MYCOTAXON

THE INTERNATIONAL JOURNAL OF FUNGAL TAXONOMY & NOMENCLATURE

VOLUME 135 (3) JULY-SEPTEMBER 2020

Guayaquilia cubensis sp. nov.
(Magdama & al. — Fia. 3, p. 509)

ISSN (PRINT) 0093-4666 https://doi.org/10.5248/135-3 ISSN (ONLINE) 2154-8889
MYXNAE 135(3): 471-718 (2020)

EDITORIAL ADVISORY BOARD

KAREN HANSEN (2014-2021), Chair
Stockholm, Sweden

P. BRANDON MATHENY (2013-2020), Past Chair

Knoxville, Tennessee, U.S.A.

ELsE C. VELLINGA (2019-2022)
Berkeley, California, U.S.A.

XINLI WEI (2019-2023)

Beijing, China

Topp W. OsMUNDSON (2019-2024)
La Crosse, Wisconsin, U.S.A.

ELAINE MALosso (2019-2025)
Recife, Brazil

ISSN 0093-4666 (PRINT)
ISSN 2154-8889 (ONLINE)

MYCOTAXON

THE INTERNATIONAL JOURNAL OF FUNGAL TAXONOMY & NOMENCLATURE

JULY-SEPTEMBER 2020

VOLUME 135 (3)

http://dx.doi.org/10.5248/135-3

EDITOR-IN-CHIEF

LORELEI L. NORVELL
editor@mycotaxon.com

Pacific Northwest Mycology Service
6720 NW Skyline Boulevard
Portland, Oregon 97229-1309 USA

NOMENCLATURE EDITOR

SHAUN R. PENNYCOOK
PennycookS@LandcareResearch.co.nz

Manaaki Whenua Landcare Research
Auckland, New Zealand

MyYcoTAxONn, LTD. © 2020

www.mycotaxon.com &
www.ingentaconnect.com/content/mtax/mt

P.O. BOX 264, ITHACA, NY 14581-0264, USA

Iv ... MYCOTAXON 135(3)

MYCOTAXON

VOLUME ONE HUNDRED THIRTY-FIVE (3) — TABLE OF CONTENTS

Nomenclatural novelties & typifications .......... 0000 c cece cece ee ees vii

ECVIEW CNS Wag ad te. Maat tA nes of Poise Sood ry rere NSS sdk yet By EN as got Bde area ix

COLigeHda cnn oan moat abet, Hie AW RR ee Ne eras id dee Ai ad x

BE POU Pde TE ILO ER Stok Path Pes OM alate te Plas ett ol Ain les alan ddahy LA xi

ZOZOSUDTTISSIOM PNOCCH UTE S.n:. weal Rasier a Rime N,. crete okie cee. ea xiii
TAXONOMY

Lepiota punaensis sp. nov. from Hawai‘i Island,
and a discussion of L. elaiophylla
JEFFERY K. STALLMAN, DON E. HEMMES,
NICOLE A. Hynson, MICHAEL H. SHINTAKU 471

Notes on rust fungi in China 8. Pucciniastrum tiliae life cycle
and new host plants inferred from phylogenetic evidence
JING-XIN JI, ZHUANG Li, Yu L1, MAKOTO KAKISHIMA 490

Guayaquilia gen. nov., typified by Idriella cubensis
FREDDY MAGDAMA, DAYNET SOSA,
FERNANDO ESPINOZA, LIZETTE SERRANO, SIMON PEREZ-MARTINEZ,
ELAINE MALOosso, MARGARITA HERNANDEZ-RESTREPO,
RAFAEL F, CASTANEDA-Ru1z 501

Distoseptispora longispora sp. nov.
from freshwater habitats in China Hal-YAN SONG,
ALY FaraG EL SHEIKHA, ZHI-JUN ZHAI, JIAN-PING ZHOU,
Mrinc-Hutr CHEN, GuANG-Hua Huo, X1-GEN Huane, D1An-MinG Hu 513

Notes on rust fungi in China 9. Puccinia miscanthi life cycle
and morphology confirmed by inoculation
JING-XIN JI, ZHUANG LI, Yu L1, MAKOTO KAKISHIMA 525
Biodiversity of heat-resistant ascomycetes
from semi-arid soils in Argentina STELLA MARIS ROMERO,
ANDREA IRENE ROMERO, ALBERTO MIGUEL STCHIGEL,
ERNESTO RODRIGUEZ ANDRADE, VIVIANA ANDREA BARRERA,
JOSE FRANCISCO CANO, RICARDO COMERIO 535

Cortinarius rapaceoides, a new record for Turkey
MERYEM SENAY SENGUL DEMIRAK & HAKAN IsIK 559

New records of Toninia from China Concconc M1Ao, MEUIE SUN,
XIAO ZHANG, ZHAOJIE REN, LING Hu 569

JULY-SEPTEMBER 2020 ... V

Serendipita sacchari sp. nov. from a sugarcane rhizosphere
in southern China LinG X1g£, YAN- YAN LONG,
YAN ZHANG, YAN-LU CHEN, WEN-LONG ZHANG 579
Five Nolanea spp. nov. from Brazil FERNANDA KARSTEDT,
SARAH E. BERGEMANN, MARINA CAPELARI 589
First record of Trappea darkeri from Turkey
YASIN UzuN, OSMAN BERBER, ABDULLAH Kaya 613
Mesocorynespora sinensis gen. & sp. nov.
from southern China ZHAO-HUuAN Xu,
KAI ZHANG, YOU-QIANG Luo, XIU-GUO ZHANG,
RAFAEL FE. CASTANEDA-RUiZ, JIAN Ma 617
Corynesporopsis hainanensis sp. nov.,
a bambusicolous fungus from southern China ZHAO-HuaNn Xu,
XuU-GEN SHI, WEI-GANG KUANG, XIU-GUO ZHANG,
RAFAEL FE. CASTANEDA-RUiZ, JIAN Ma 623
Hymenochaete longisterigmata sp. nov. from India
NAVPREET Kaur, AVNEET PAL SINGH, GURPAUL SINGH DHINGRA 631
Entoloma conferendum, Hygrocybe coccineocrenata,
and Hypholoma ericaeum new to Montenegro ILINKA CETKOVIG,
ZDENKO TKALCEC, SNEZANA DRAGICEVIC, ANTUN ALEGRO,
VEDRAN SEGOTA, MARGITA JADAN, NEVEN MATOCEC,
IvANA KuSAN, ZELJKO ZGRABLIC, ARMIN ME81¢ 637
First Pakistani report of Erysiphe betae
on the invasive weed Chenopodium ambrosioides
AYESHA ANWAR, NAJAM UL SEHAR AFSHAN,
AAMNA ISHAQ, MARIA RIAZ, ABDUL NASIR KHALID, SIRAJ UDDIN 649
Crustose lichens new to India Rupyyoti GoGo, SILJo JOSEPH,
Manas PRATIM CHOUDHURY, SANJEEVA NAYAKA, FARISHTA YASMIN 657
Chromelosporium re-evaluated,
with Chromelosporiopsis gen. nov. and Geohypha stat. nov.
GREGOIRE L. HENNEBERT 665

VI ... MYCOTAXON 135(3)

PUBLICATION DATE FOR VOLUME ONE HUNDRED THIRTY-FIVE (2)

MYCOTAXON for APRIL-JUNE 2020 (I-XIV + 235-471)
was issued on July 13, 2020

JULY-SEPTEMBER 2020 ...

NOMENCLATURAL NOVELTIES AND TYPIFICATIONS

PROPOSED IN MYCOTAXON 135(3)

Botrytis isabellina Preuss (lectotypified)
[MBT 392406], p. 671
Chromelosporium herbicola (Ellis & Dearn.) Hennebert
[MB 833990], p.673
Chromelosporiopsis Hennebert
[MB 835622], p. 688
Chromelosporiopsis carnea (Schumach.) Hennebert
[MB 835623], p. 689
Chromelosporiopsis coerulescens (Bonord.) Hennebert
[MB 835625], p. 695
Corynesporopsis hainanensis Z.H. Xu, Jian Ma, X.G. Zhang & R.F. Castaneda
[MB 836568], p. 624
Distoseptispora longispora H.Y. Song & D.M. Hu
[MB 826916], p. 516
Geohypha (Fr.) Hennebert
[MB 835628], p. 708
Geohypha terrestris (Fr.) Hennebert
[MB 835629], p. 709
Guayaquilia R.F. Castafieda, Magdama, D. Sosa & Hern.-Restr.
[MB 831849], p. 506
Guayaquilia cubensis (R.F. Castaheda & G.R.W. Arnold) R.F. Castaneda,
Magdama, D. Sosa & Hern.Restr.
[MB 831851], p. 507
Hymenochaete longisterigmata Nav. Kaur, Avn.P. Singh & Dhingra
[MB 832678], p. 632
Lepiota punaensis Stallman
[MB 832104], p. 477
Mesocorynespora Jian Ma, X.G. Zhang & R.E. Castaneda
[MB 836511], p. 618
Mesocorynespora sinensis Jian Ma, X.G. Zhang & R.E Castaneda
[MB 836512], p. 618
Nolanea albertinae Karstedt & Capelari
[MB 826784], p. 596
Nolanea atropapillata Karstedt & Capelari
[MB 805603], p. 600

Nolanea pallidosalmonea Karstedt & Capelari
[MB 805604], p. 602

VII

Vill ... MYCOTAXON 135(3)

Nolanea parvispora Karstedt & Capelari
[MB 805605], p. 603

Nolanea tricholomatoidea Karstedt & Capelari
[MB 805607], p. 606

Polyactis carnea Ehrenb. (lectotypified)
[MBT 392408], p. 689

Puccinia miscanthi Miura (neotypified)
[MBT 388544], p. 531

Serendipita sacchari L. Xie, Y.Y. Long & Y.L. Chen
[MB 836761], p. 582

Trichoderma laeve Pers. (lectotypified)
[MBT 392413], p. 709

JULY-SEPTEMBER 2020 ...

REVIEWERS — VOLUME ONE HUNDRED THIRTY-FIVE (3)

The Editors express their appreciation to the following individuals who have,

prior to acceptance for publication, reviewed one or more of the papers

prepared for this issue.

Vladimir Antonin

Flavia Rodrigues Barbosa
Timothy J. Baroni

Maria Virginia Bianchinotti
Uwe Braun

Rafael E Castafieda-Ruiz
Cvetomir M. Denchev
Edit Farkas

Patricia Oliveira Fiuza
André Fraiture

Shouyu Guo

Nils Hallenberg

David L. Hawksworth
R.G.U. Jayalal

Abdullah Kaya

Ali Keles

De-Wei Li

Xiao- Yong Liu

Jian Ma

Eric H.C. McKenzie
Andrew N. Miller
A.R. Niazi

Lorelei L. Norvell
Shaun R. Pennycook
Brian A Perry

Keith Seifert

B.M. Sharma
Silvana Santos da Silva
G.P. Sinha

Ibrahim Tirkekul
Yusuf Uzun

Alfredo Vizzini
Felipe Wartchow

Jiwen Xia

IX

X ... MYCOTAXON 135(3)

CORRIGENDA FOR MYCOTAXON 135-(3)
Cited below are mistakes present in files submitted for PDF conversion in
the current issue but not detected by the authors until after the PDF had

been processed.

p. 495, line 10 FOR: A-D READ: 5A-D
p. 496, line 13 FOR: Helongjiang READ: Heilongjiang
p. 531, line 8 FOR: Helongjiang READ: Heilongjiang

p#533,-lines3 FoR: Wuhan READ: Wuchang

JULY-SEPTEMBER 2020 ... XI

FROM THE EDITOR-IN-CHIEF

WHO ‘AUTHORS’ SCIENCE?—Fungal research is now so specialized that the single-
authored paper has become a rare beast indeed. Modern mycological systematics
now rely on contributions from masters from several different disciplines: alpha
taxonomists and collectors well versed in morphological identification, ecologists
able to link environmental requirements and taxa, physiologists and “beta”
taxonomists who craft diagnostic matrices from colonies in Petri dishes, “gene
jockeys” who reliably deliver pristine sequences from targeted DNA regions, and
evolutionary biologists wielding Bayesian analysis and Markov chain Monte Carlo
methods with morphological analytics to generate elegant and reliable phylogenies.

To these may be added those who summarize, analyze, and wrap everything up
in a research paper—the authors. In multi-authored papers, there is usually one
individual who “drives” the paper, although sometimes two authors may be said
to “contribute equally” The first-named (also called “senior”) authors should have
participated in the research since its inception so that they understand all aspects
well enough to create a clear and comprehensible presentation of their research.
Unfortunately lists begin with one name, and often the author with the best English
writing abilities ascends to first position by default, irrespective of the number of
scientific contributions made during research. Alternately, the most fluent English
speakers who are designated corresponding authors may appear anywhere in the
lists. There is also the trend toward ‘anchoring’ authorship by placing the Lab
supervisor in last place; here we devoutly hope that the lab head has read the paper
in its entirety and corrected mistakes well before journal submission.

Your editors recognize the problems encountered by contributing scientists in
deciding which contributors to include as authors and which to recognize in the
Acknowledgments. We definitely expect all authors to gather frequently to discuss
the research while in progress, when being written, and when being prepared for
submission. These discussions are true teaching moments, and authors who have
eliminated mistakes during these stringent vetting processes will have much better
success in publishing their science.

MycoTaxon ART—Your editors are unusually fortunate to be able to present on
our cover such beautiful art created by authors to illustrate their own research. The
illustrations featured on our covers are selected from papers proposing taxa new to
science. However, there are some truly spectacular plates in this issue accompanying
previously named taxa that “escaped” cover selection. Part of the pleasure of opening
a new Mycotaxon is leafing through the beautiful fungal portraits lurking inside.

MYCOTAXON 135(3) contains 18 papers by 92 authors (representing 17 countries) as
revised by 32 expert reviewers and the editors.

The 2020 July-September MycoTAxon proposes FOUR new genera (Chromelo-
sporiopsis, Geohypha, Guayaquilia, and Mesocorynespora) and TEN species new

XII ... MYCOTAXON 135(3)

to science representing Corynesporopsis, Distoseptispora, Mesocorynespora,
and Serendipita from Cuina; Hymenochaete from INp1a; Lepiota from Hawai‘i
(U.S.A.); and Nolanea from BraAziL. We also offer FIVE new combinations in
Chromelosporium, Chromelosporiopsis, Geohypha, and Guayaquilia and FouR newly
registered typifications for Botrytis, Polyactis, Puccinia, and Trichoderma.

New species range extensions are reported for [ascomycetes] five heat resistant
species in an elegant culture study from ARGENTINA; [basidiomycetes] Cortinarius
& Trappea in TuRKEY and Entoloma, Hygrocybe, and Hypholoma in MONTENEGRO;
and [lichens] Bacidia, Malmidea, Porina, and Pyrenula in Inv1a and Toninia in
CHINA. New hosts are cited for Erysiphe in PAKISTAN and Pucciniastrum in China.
We also offer keys to species of Lepiota in Hawati‘l and Toninia s.l. in CuH1Na along
with worldwide keys to Corynesporopsis, Distoseptispora, and Mesocorynespora.

The July-September issue now offers more molecularly supported taxonomic
studies: nine new species representing Distoseptispora, Guayaquilia, Lepiota,
Nolanea, and Serendipita), one Cortinarius range extension, an Erysiphe host
association, and a full life cycle of the rust Pucciniastrum tiliae are all supported by
phylogenetic analyses, while another life cycle is established for Puccinia miscanthi
via culture studies.

Alpha taxonomy is not dead, particularly when supported by a lifetime of close
microscopical scrutiny and systematic research. The issue ends with “my final
paper” by our co-founding editor, GREGOIRE HENNEBERT, who presents a masterful
synopsis of a difficult (and often overlooked) group of fungi and concluding with a
warm memorial of Agriculture Canada’s irreplaceable Stan Hughes, who died last
year at the age of 102.

Warm regards,

Lorelei L. Norvell (Editor-in-Chief)
9 October 2020

JULY-SEPTEMBER 2020... XIII

2020 MyCOTAXON SUBMISSION PROCEDURE

Prospective MycotTaxon authors should download the Mycotaxon 2020 guide,
review & submission forms, and MycoTaxon sample manuscript by clicking the ‘file
download page’ link on our INSTRUCTIONS TO AUTHORS page before preparing their
manuscript. This page briefly summarizes our “4-step’ submission process.

1—PEER REVIEW: Authors first contact peer reviewers (two for journal papers;
three for mycobiota/fungae) before sending them formatted text & illustration
files and the appropriate 2020 MycoTaxon journal or mycota reviewer comment
form. Experts return revisions & comments to BOTH the Editor-in-Chief
<editor@mycotaxon.com> and authors. ALL co-authors Must correct and proof-
read their files before submitting them to the Nomenclature Editor.

2—NOMENCLATURAL REVIEW: Authors email all ERROR-FREE text & illustration
files to the Nomenclature Editor <PennycookS@LandcareResearch.co.nz>.
Place first author surname + genus + ‘MycoTaxon’ on the subject line, and
(required) attach a completed SUBMISSION FORM. The Nomenclature Editor will
(i) immediately assign the accession number and (ii) after a few weeks return his
notes and suggested revisions to the author(s) and Editor-in-Chief.

3—FINAL SUBMISSION: All coauthors thoroughly revise and proof-read files
to prepare error-free text and images ready for immediate publication. Poorly
formatted copy will be rejected or returned for revision. E-mail the final manuscript
to the Editor-in-Chief <editor@mycotaxon.com>, adding the accession number to
the message and all files, which include a (i) revised 2020 submission form, all (ii)
text files and (iii) jpg images, and (iv) FN, IF, or MB identifier verifications for each
new name or typification. The Editor-in-Chief acknowledges submissions within
two weeks of final submission but requests authors to wait at least 14 days before
sending a follow-up query (without attachments).

4—FINAL EDITORIAL REVIEW & PUBLICATION: The Editor-in-Chief conducts a
final grammatical and scientific review and returns her editorial revisions to all
expert reviewers and coauthors for final author approval. Author-approved files
are placed in the publication queue.

The PDF proof and bibliographic & nomenclatural index entries are sent to all
coauthors for final inspection. After PDF processing, the Editor-in-Chief corrects
ONLY PDF editorial/conversion and index entry errors; corrections of all other
errors are listed in the ErratTA of a subsequent issue for no charge. Authors will pay
fees for mycobiota uploads, optional open access, and correction of major author
errors to the Business Manager <subscriptions@mycotaxon.com> at this time.

MyYcOTAXON LTD— www.mycotaxon.com

The Mycotaxon Webmaster <mycotaxon@gmail.com> posts announcements,
subscription & publication information, and author forms & templates on the official
MycorTaxon site. Our server also hosts the mycobiota web-page for free download
of Fungae (regional annotated species lists).

MYCOTAXON ONLINE— www.ingentaconnect.com/content/mtax/mt
The MycoTaxon journal publishes four quarterly issues per year. Both open access
and subscription articles are offered.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 471-489
https://doi.org/10.5248/135.471

Lepiota punaensis sp. nov. from Hawai'i Island,
and a discussion of L. elaiophylla

JEFFERY K. STALLMAN’, DON E. HEMMEs?’,
NICOLE A. HyNSON?, MICHAEL H. SHINTAKU*

™ Department of Tropical Conservation Biology & Environmental Science Graduate Program,
University of Hawai‘i Hilo, Hilo, Hawai‘i 96720 USA

? Department of Biology, University of Hawai‘i Hilo, Hilo, Hawai‘i 96720 USA

° Pacific Biosciences Research Center, University of Hawai‘i Manoa,
Honolulu, HI 96822 USA

* College of Agriculture, Forestry, and Natural Resource Management
and Department of Tropical Conservation Biology & Environmental Science Graduate Program,
University of Hawai‘i Hilo, Hilo, Hawai‘i 96720 USA

*CORRESPONDENCE TO: jstall@hawaii.edu

ABSTRACT—A new species, Lepiota punaensis, in L. subsect. Helveolinae is described from
the Puna District of Hawai‘i Island. A species closely resembling L. elaiophylla in morphology
but genetically distant from the species paratype is also discussed. Both taxa and additional
Hawaiian collections are analyzed in an nrITS phylogeny, and a key to Lepiota on Hawai‘i
Island is given.

KEY worps—Agaricaceae, Casuarina equisetifolia, cryptic species

Introduction

Lepiota (Pers.) Gray is a large genus of more than 400 species (Kirk & al.
2008) with widespread distribution that continues to see new species described
regularly from temperate (Caballero & al. 2015), subtropical (Qasim & al.
2015), and tropical (Sysouphanthong & al. 2016) environments. Exceptions
occur, but in general the genus is characterized macroscopically by white to
yellow-spored agarics with free gills, evidence of partial and universal veils,
but lacking a volva. Microscopically the lamellar trama are regular, and

472 ... Stallman & al.

basidiospores are thin-walled, without a germ pore, generally dextrinoid,
and not metachromatic in Cresyl Blue. Lepiota has historically been split into
sections based on morphology (e.g., Bon 1993), and more recently, into clades
based on molecular data (Vellinga 2003). Lepiota subsect. Helveolinae Bon &
Boiffard [in L. sect. Ovisporae (J.E. Lange) Kuhner], which contains the two
species closely examined in this manuscript, is characterized morphologically
by ellipsoid to oblong spores with a pileus covering composed of a trichoderm
of predominantly long cylindrical elements and has been consistently recovered
as monophyletic in molecular analyses of Lepiota and its infrageneric sections
(Vellinga 2003; Qasim & al. 2015, 2016; Sysouphanthong & al. 2012, 2016;
Liang & al. 2018; but see Liang & al. 2011). This clade contains species such as
Lepiota subincarnata J.E. Lange and L. brunneoincarnata Chodat & C. Martin,
which are known to contain amatoxins (Benjamin 1995).

Our project documenting the lepiotaceous fungi from Hawai‘i Island
reports a new taxon from L. subsect. Helveolinae, Lepiota punaensis, and a new
record for Hawai‘i, Lepiota cf. elaiophylla. In addition, Lepiota aspera (Pers.)
Quél., Lepiota besseyi H.V. Sm. & N.S. Weber, Lepiota pseudorubella Gubitz,
Lepiota rubrobrunnea Gubitz, and a poorly known taxon with an epithelial
pileus covering (MK412575) are confirmed as occurring on Hawai‘i Island. All
species are found in wet, lowland environments associated with alien vegetation
and are therefore presumed to be introduced.

Materials & methods

Collection and morphologic description

Basidiome collecting occurred from September 2016 to January 2019 on Hawai‘i
Island. Photographs were taken in the field with a Canon Rebel T4i camera and
have not been altered (PLATES 2a; 3a). Morphological details were recorded at the
time of collection. Descriptions of Hawaiian habitats and vegetation zones are from
Gagné & Cuddihy (1999). Macroscopic descriptions are based on terminology from
Vellinga (2001) and color descriptions are from Kornerup & Wanscher (1978).
After collection, specimens were desiccated before microscopic and molecular
analysis, and are deposited at the Joseph F. Rock Herbarium, University of Hawaii
at Manoa, Honolulu, HI, USA (HAW).

Measurement of microscopic structures was performed on material rehydrated
in 10% ammonia (pileus and stipe covering, spores), or 10% ammonia with
1% Congo Red (all other structures). Melzer’s reagent, distilled water, and 1%
Cresyl Blue in distilled water were also used to observe natural colors and color-
changing reactions. Mature spores were measured in side view (excluding the
hilar appendage) using the program Piximétre version 5.9 (http://ach.log.free.
fr/Piximetre/). Measurements represent values falling within a 95% confidence

Lepiota punaensis sp. nov. (Hawai'i USA) ... 473

interval; the annotation [30, 4, 3] indicates that thirty spores from four specimens
in three collections were measured. Micrographs for import to Piximétre were
captured using an Olympus XM10 microscope camera attachment on an Olympus
BX53 microscope with the software cell-sens Dimension version 1.5.

Molecular analysis

The primers ITSIF and ITS4 were used to amplify the nuclear ribosomal
internal transcribed spacer region (nrITS; Schoch & al. 2012) via the polymerase
chain reaction from dried fungal tissue of eleven specimens from Hawai‘i Island.
Amplicons were Sanger sequenced in both forward and reverse directions using
the primers ITSIF and ITS4, and sequences were trimmed, edited, and forward
and reverse reads aligned into consensus sequences in Geneious v. 9.1.8 (Kearse &
al. 2012). Sequences generated were further investigated using the BLAST tool in
GenBank (NCBI 2015), and the top sequences by similarity to Hawaiian taxa, as well

TABLE 1. Sequences newly generated and downloaded from GenBank for phylogenetic

analysis.

TAXON (COLLECTION #) GENBANK # TAXON (COLLECTION #) GENBANK #
C. hetieri AY176459 L. luteophylla AY176475
C. pulverulenta AF391035 L. magnispora AF391005
C. seminuda JF907983 L. pilodes AY 176476
C. sp. (Hawai‘i) (JKS 143) MK412600 L. punaensis (JKS 64) MK412572
C. sp. (Hawai‘i) (JKS 140) MK412604 L. punaensis (JKS 86) MK412577
Ch. molybdites (JKS 96) MK412591 L. punaensis (JKS 87) MK412578
L. andegavensis KP004931 L. rubrobrunnea (JKS 118) MK412583
L. apatelia AY176462 L. rhodophylla AY176480
L. aspera KP843884 L. sp. (O‘ahu) (SS 1) MK412617
L. aspera MK412598 L. sp. (Australia) KP012693
L. brunneoincarnata FJ998395 L. sp. (Australia) KP012854
L. castanea AY176463 L. sp. (Hawai‘i) (JKS 74) MK412575
L. castaneidisca AF391061 L. sp. (Kaua‘i) AY176402
L. cristata U85327 L. sp. (Thailand) HQ647293
L. cf. elaiophylla MK412581 L. sp. (Thailand) JN224825
L. cf. elaiophylla (JKS 71) MK412589 L. sp. (Thailand) JN224826
L. cf. elaiophylla (JKS 77) MK412588 L. sp. (Thailand) JN224828
L. elaiophylla MH979467 L. subincarnata AY176491
L. elaiophylla AF391024 L. thiersii AY176492
L. erminea AY176470 L. tomentella EF080868
L. farinolens AY176368 L. vellingana HE974764
L. felina U85330 L. xanthophylla AY176405
L. helveola MH979466 M. haematospermum KF953545
L. himalayensis HE614898 Uncultured fungus (Australia) FJ528742

Sequences with collection numbers were newly generated; Hawaiian sequences are in bold.
C. = Cystolepiota, Ch. = Chlorophyllum, L. = Lepiota, and M. = Melanophyllum.

474. ... Stallman & al.

as representatives from each of the clades of Lepiota identified in Vellinga (2003)
were included in our phylogenetic analyses (TaBLE 1). Pairwise genetic distances
(TABLE 2) were calculated in Geneious by comparing aligned, overlapping regions,
excluding gaps and ambiguous positions. Lepiota besseyi was excluded from our
phylogenetic analysis and key to Lepiota because it falls outside of Lepiota in the
Leucocoprinus Pat. and Leucoagaricus Locq. ex Singer clade in Agaricaceae Chevall.,
although a formal transfer has not been made (Vellinga & al. 2011).

TABLE 2. Pairwise genetic distance comparison between Lepiota cf. elaiophylla and
closest Lepiota relatives in GenBank.

elaiophylla elaiophylla cf. elaiophylla cf. elaiophylla | cf. elaiophylla
(Canada) (Netherlands) (Hawai‘i) (Hawai‘i) (Hawai‘i)
MH979467 AF391024 MK412581 MK412581 MK412588
elaiophylla
(Netherlands) 92.9%
AF391024
cf. elaiophylla
(Hawai‘i) 99.9% 92.9%
MK412581

cf. elaiophylla
(Hawai ‘i) 99.9% 92.9% 99.9%
MK412589
cf. elaiophylla
(Hawai ‘i) 99.9% 92.9% 99.9% 99.9%
MK412581
L. sp.
(Australia) 98.3% 93.2% 98.3% 98.3% 98.3%
KP012854

Sequences were aligned in Geneious with the default settings of the MAFFT
(Katoh & Standley 2013) plugin, then imported to Molecular Evolutionary Genetics
Analysis (MEGA) version X (Kumar & al. 2018). Based on the “Find Best DNA
Model” tool in MEGA, Maximum Likelihood (ML) phylogenetic trees were created
with all sites with gaps and/or missing data eliminated resulting in 465 total
positions in the final dataset using the following settings: General Time Reversible
(GTR) model (Nei & Kumar 2000) including gamma distributed (G) and invariant
sites (I), moderate branch swap filter, and Subtree-Pruning-Regrafting (Extensive,
level 5) for the ML heuristic method. The initial tree was built using the default
neighbor-joining/bioneighbor-joining method, and the phylogeny was tested with
1000 bootstrap replicates.

The alignment was further analyzed using the Geneious plugin MrBayes
(Huelsenbeck & Ronquist 2001). The tree was constructed with a GTR model
including G and I sites with default settings (four chains for 1,100,000 generations,
sampled every 200 generations with the first 100,000 generations discarded as burn-
in). Tree images were edited in Inkscape version 3 (https://inkscape.org/).

Lepiota punaensis sp. nov. (Hawai'i USA) ... 475

Results & discussion

Our Bayesian and ML phylogenetic analyses generated identical tree
topologies when considering our ML tree with the highest log likelihood
(-4599.22) shown in Fic. 1. The topology of our Lepiota phylogeny is similar to
prior analyses from the last 16 years and does not differ greatly from Vellinga’s
(2003) work using nrITS and nrLSU sequences, Qasim & al’s (2015; 2016)
works using nrITS sequences, Sysouphanthong & al’s (2012; 2016) works using
nrITS sequences, and Liang & al’s (2018) work using nrITS, nrLSU, IGS, and
mtSSU sequences (but see Liang & al. 2011 using nrITS, nrLSU, IGS, and
mtSSU sequences where species with a trichoderm of long elements in clade
2 were dispersed).

Bootstrap support values for clades 2 and 4 (as defined by Vellinga 2003)
are too low to draw general conclusions about the deeper relationships of our
Hawaiian taxa within the genus, but our species clusters do reveal interesting
information about close relatives of Hawaiian Lepiota s.l. species.

Lepiota punaensis is always on a long branch by itself with the closest
nrITS match in GenBank an 87% similar Australian sequence (KP012854).
Lepiota punaensis is sister to the cluster of species from Hawai‘i, Canada,
Australia, and Europe, all of which (except the Australian collection) are
morphologically identified as L. elaiophylla. The Hawaiian L. cf. elaiophylla
is genetically identical (99.9% similar, TABLE 2) to a collection identified as
L. elaiophylla from a greenhouse in Canada, close to (98.3% similar, TABLE
2) a collection from a native Eucalyptus and Acacia swamp in Australia (M.
Barrett, pers. comm.); these three geographically separated collections form a
clade sister to the paratype of L. elaiophylla from the Netherlands, where the
species was originally described. The collection from the Netherlands is 92.9%
similar to the Hawaiian collections based on our alignment (TABLE 2).

Regarding other Hawaiian collections with a trichoderm of predominantly
long elements, L. rubrobrunnea is on a long branch in a poorly supported
group and its closest relatives are unclear. A Lepiota sp. collected on the UH
Manoa Campus on O‘ahu clusters in a well-supported clade with L. vellingana
Nawaz & Khalid, currently known from Pakistan (Nawaz & al. 2013), and
L. farinolens Bon & G. Riousset, from France (Bon 1992). A species collected
on the Island of Kaua‘i clusters in a well-supported clade with three taxa
from Thailand and L. subincarnata, a species known from Europe, North
America, and South Asia (Razaq & al. 2014). It may be conspecific with
sequence JN224826, a species collected in Chiang Mai Province in 2008 that,
according to notes in GenBank, is “close to L. subincarnata?

476 ... Stallman & al.

. Cf. mg a A MK412589
. cf. elaiophylla MK412588
. cf. elalophy lla MK412581
ees a {Canada MH979467
oat (Australlia) KP012854
‘elaiopnytia (Netherlands) AF391024
L. punaensis MK412577
99/10] [ punaensis MK412578
L. punaensis MK412572
99/1.0 rae sp. (Kaua‘i) AY176402
L. sp. AM ) JN224826
subincarnata AE. 76491
sp. (Thailand) JN224825
73/1.0 © sp. (Thailand) JN224828
L. brunneoincarnata FJ998395
1.0 L. farinolens AY 176368
oa vellingana HE974764
6/0.97 98/1.0 (0

op O‘ahu) MK412617
L. helveola mriosba

L. himalayensis HE614898
rubrobrunnea MK412583
86/0.99-— | . [reaopril. AY 176480

©
Q
oO
oO
oO

clade 2
trichoderm of long elements

o6it10 Thailand) HQ647293 Bo
L. andegavensis KP004931 + 2

89/1.0 L. castanea AY176463 Sie,
eu L. pilodes AY 176476 oa

L. tomentella EF080868
ods L. castaneidisca AF391061
L. cristata U85327
95/1.0 L. apatelia AY176462
L. thiersti AY176492
99/1.0 L. erminea AY176470
aanof— L. magnispora AF391005
*4 L. felina U85330
L. xanthophylla AY176405
L. sp. (Hawai‘i) MK412575
99/1.0; C. sp. (Hawai‘i) MK412604
ano C. sp. (Hawai‘i) MK412600
99/10 Uncultured Fungus (Australia) FJ F 1528742
sp. (Australia) KP012693
C. pulverulenta AF391035
M. haematospermum KF953545
zo C. seminuda JF907983
C. hetieri AY176459
99/1.0, L. aspera MK412598
L. aspera KP843884
L. cf. luteophylla AY176475
Ch. molybdites MK412591 | outgroup

0.03

s
&
e)

clade 1

clade 4

Fic. 1. Phylogenetic analysis of selected sequences and species of Lepiota based on nrITS
sequences. The phylogeny was inferred using the Maximum Likelihood method and is drawn to
scale, with branch lengths measured in the number of substitutions per site. Maximum Likelihood
bootstrap support values >70% are shown in bold, and Bayesian posterior probabilities 20.95 are
shown in normal type. Hawaiian taxa are in bold, and islands are indicated for taxa not identified
to species. C. = Cystolepiota, Ch. = Chlorophyllum, L. = Lepiota, and M. = Melanophyllum.

The Hawaiian Cystolepiota species clusters in a well-supported clade
with two unknown taxa from Australia, and these are sister to Cystolepiota
pulverulenta (Huijsman) Vellinga [= C. petasiformis (Murrill) Vellinga], a
purportedly widespread species found in Europe (Vellinga 2001), western
North America (Vellinga 2006), and India (Kumar & Manimohan 2009).
The closest Australian sequence (FJ528742) is 96% similar to the Hawaiian

Lepiota punaensis sp. nov. (Hawai'i USA) ... 477

Cystolepiota species, and its lack of any closer matches in GenBank and
association with native vegetation supports the inference that it is a Hawaiian
endemic (Hemmes & Desjardin 2002). A poorly known Lepiota (MK412575)
that was only collected once in this study is on its own long branch in clade 1
(with only 74% support), and its closest relatives are unclear.

There are few data at this time to support broader conclusions about the
origins and full ranges of Hawaiian Lepiota s.l. taxa. Lepiota pseudorubella
lacks molecular data, L. rubrobrunnea and L. sp. (MK412575) have uncertain
placement in our tree due to low support values, and L. sp. (MK412617) is
on a relatively long branch in a clade with dispersed taxa. Lepiota aspera and
Melanophyllum haematospermum (Bull.) Kreisel (for which no Hawaiian
sequences are available) have widespread distributions, and L. pseudorubella,
L. rubrobrunnea, and L. cf. elaiophylla have all been collected in artificially
warm environments in temperate areas such as Canada and Germany (Gubitz
2008). The only putatively native Hawaiian taxon, Cystolepiota sp., is likely of
Australian origin, while a collection from Kaua‘i (AY176402) clusters with
several species from Thailand. Lepiota punaensis and L. cf. elaiophylla have
a close relative found in native Australian vegetation, but this is far from
conclusive in establishing a location of origin or theory of dispersal.

Taxonomy

Lepiota punaensis Stallman, sp. nov. PLATE 2
MB 832104

Differs from Lepiota elaiophylla by its white lamellae and from L. subincarnata by its
pileus covering containing short and narrowly clavate cells.

Type: USA, Hawai‘i, Hawai‘i Island, Puna District, MacKenzie State Recreation Area,
19°26’11”N 154°51’57”W, in duff under Casuarina equisetifolia L. and Cocos nucifera L.,
9 Dec 2016, coll. JKS 86 (Holotype, HAW-F-00256, GenBank: MK412577).

ETYMOLOGY: from the Puna District of Hawai‘i Island, the only known locality of this

species.
PrLEus 8-24 mm broad, at first hemispherical, becoming obtusely conical to
obtusely broadly conical, then convex to plano-convex in age; pileus covered
in a dense mat of warm brown (6E6 to 7E4-5; occasionally 7F6) fibrils when
young, quickly breaking into minute to small scales, composed of generally
appressed aggregated fibrils, over a white to off-white (6B2) background as
pileus expands, fibrils denser towards the cracked, or remaining intact disc
surface, lessening towards margin, margin aspect straight, shape entire to
eroded in age, often with remnants of the pileus covering adhering when
young, dry, non-hygrophanous; CONTEXT thin (<3 mm), white, unchanging;

478 ... Stallman & al.

LAMELLAE, L = 36,1 = 1-3, free, close, subventricose to ventricose, <3 mm broad,
white to off-white, edge even to eroded in age; stiPE 14-35 x 1-3 (-4 at base)
mm, cylindrical, equal to tapering upwards, off-white to light brown (6B2, 8C2),
covered with aggregated fibrils of similar appearance to pileus covering on
lower 1/2 to 1/3 of stipe that are easily removed and become less conspicuous in
age, appearing glabrous above this zone, but usually with thin covering of white
hyphal strands oriented parallel to the stipe (lens), also easy to remove; stipe
darkening over time to brown (6F5) where handled; ConTExT thin, concolorous
with exterior of stipe, stuffed with white hyphae when young, hollow in age,
base equal to slightly enlarged; BASAL TOMENTUM absent to inconspicuous;
RHIZOMORPHS absent or present, white; ANNULUS present only as annular zone;
SPORE DEPOSIT white; EDIBILITY toxic, likely contains amatoxins; ODOR none
to fungal; TASTE none to mildly fungal.

BasIDIOSPORES [94, 6, 4] (5.4-)6.3-6.6(-7.5) x (3.2-)3.7-3.8(-4.4) um
[x= 6.4 x 3.8 um], Q=(1.4—)1.6-1.8(-2.0) [Qm = 1.7], ellipsoid to subcylindrical
(generally oblong) in side view, usually with a straight adaxial (suprahilar
depression absent) and convex abaxial side; oblong to rarely obovoid in
frontal view, hyaline in H,O and NH,OH, dextrinoid, congophilous, weakly
cyanophilous, non-metachromatic in Cresyl Blue, germ pore absent, mono to
less commonly biguttulate; BAsIp1A [63, 6, 4] (21.2-)25.6-33.3(-34.7) x (5.9-)
6.5-8(-8.3) um [x = 28.9 x 7.2 um], hyaline, thin-walled, narrowly clavate to
subclavate, sometimes with flexuous wall, with 4 sterigmata; LAMELLAR-EDGE
sterile; CHEILOCYSTIDIA [44, 6, 4] (15.6—)22.3-24.6(-31.3) x (5.1-)8.9-10.2
(-14.0) um [x = 23.5 x 9.5 um], narrowly clavate to more commonly clavate or
broadly clavate, hyaline, thin-walled; PILEUS COVERING an intricate trichoderm
of long and shorter inflated cylindrical, sometimes flexuous, golden-colored
hyphae with parietal pigment, thin to slightly thick-walled, shorter elements are
present and common, but not in a distinctive layer, terminal elements narrowly
clavate, cylindrical, inflated cylindrical, or less commonly irregular/flexuose
narrowly clavate, or with a mucronate tip, <160 um long and 12 um diam,
clamp connections common; STIPITIPELLIS a cutis of tightly packed hyaline,
narrowly cylindrical hyphae <5 um diam, scales below annular zone similar
to those on pileus but generally composed of shorter elements, above annular
zone irregularly present and mostly composed of long, narrowly cylindrical,
hyaline, clamped hyphae; ANNULUS as zone only; CLAMP CONNECTIONS present
in all tissues.

ADDITIONAL SPECIMENS EXAMINED—USA, Hawai‘i, Hawai‘i Island, Puna District,
MacKenzie State Recreation Area, 19°26’11”N 154°51’57”W, 17 Sep 2016, coll. JKS

Lepiota punaensis sp. nov. (Hawai'i USA) ... 479

20 um

PLATE. 2. Lepiota punaensis (holotype, HAW-F-00256). a. Basidiomata; b. Basidiospores; c. Basidia
(with four sterigmata; only two shown in this basidial view); d. Cheilocystidia; e. Stipe covering;
f. Pileus covering.

64 (HAW-F-00257; GenBank MK412572); 5 Jan 2017, coll. JKS 87 (HAW-F-00258;
GenBank: MK412578); 1 February 2018, coll. JKS 186 (HAW-F-00255); 2 January 2019,
coll. JKS 204 (HAW-F-00259).

480 ... Stallman & al.

ECOLOGY & DISTRIBUTION — Solitary to scattered on needles and seed pods of
Casuarina equisetifolia in wet, lowland, alien environments. January, February,
September, and December. Currently known only from the Puna District of
Hawai'i Island.

CoMMENTS—Lepiota punaensis is known only from Casuarina equisetifolia
duff in the Puna District of Hawai‘i Island. The species is recognized by its
small size, lack of an annulus, and small, appressed brown fibrils over an
off-white cap context. Its oblong spores and pileus covering of long elements
without a layer of shorter clavate elements (although shorter elements are
present) place this species in L. subsect. Helveolinae with other species that
contain amatoxins.

Although L. punaensis is a small, relatively nondescript species, few
described species provide similar morphological matches, and its nrITS
sequence is unique. Recent studies from around the world such as Thailand
(Sysouphanthong & al. 2012), China (e.g., Liang & al. 2018), Pakistan (Qasim
& al. 2016), and the Dominican Republic (Justo & al. 2015) have described
new Lepiota species from the (neo)tropics, and have included DNA
sequence data that excludes any species from these studies, or other studies
incorporating nrITS sequence data, from providing a match to L. punaensis.
Older literature can be more difficult to interpret, but a review of species
sharing similarities, and newly described species without molecular data also
do not reveal a close match.

Lepiota zalkavritha T.K.A. Kumar & Manim. is a species of small size in
L. sect. Ovisporae described from India with no nrITS sequence (Kumar &
Manimohan 2009). Lepiota zalkavritha differs from L. punaensis in having
occasional apical outgrowths on its cheilocystidia, being more robust, having
darker brown coloration on pileus and stipe, and growth in soil (compared
to Casuarina equisetifolia duff). Lepiota brevipes Murrill is a small species
described from Florida in L. sect. Ovisporae with similar coloration to
L. punaensis, but the stipe is often much wider, and the spores are smaller
at 4.1-5 x 2.5-3.1 um (Akers 1997). Lepiota cinnamomea Cleland is a
small species from Australia in L. sect. Ovisporae (Aberdeen 1992), but the
pinkish-brown and dark-brown color descriptions of the scales and disc, and
shorter elements in the pileus covering (only <68 um long) rule it out. Other
small species described from Australia and stated to be in L. sect. Ovisporae
(Grgurinovic 1998) have annuli (e.g., L. rimosa Murrill) or color-changing
reactions not present in L. punaensis.

Lepiota punaensis sp. nov. (Hawai'i USA) ... 481

Pegler’s work from Ceylon (1972) reveals species in L. sect. Ovisporae that
are much larger, have unique red or yellow colors, or have annuli that do not
match L. punaensis, and his works from Africa (1977) and the Caribbean
(1983) do not reveal close matches. Rick’s (1905, 1907, 1920, 1926, 1930,
1937, 1938, 1961) works from South America present few good matches
for L. punaensis and Pereira’ (1998, 2000, 2001) present none. Rick does
describe a variety of Lepiota species with arachnoid veils (e.g., L. flavipes Rick
and L. hypholoma Rick), but other features such as the coloration or spore
sizes are different.

The closest morphological match appears to be Lepiota subincarnata,
a well-known species described from Europe that is also found in North
America and Asia (Razaq & al. 2014). Lepiota punaensis differs in having a
typically smaller pileus and containing pileus covering elements that can have
flexuose walls, be narrowly clavate, and contain shorter elements (although
not in a distinctive layer), all of which L. subincarnata lacks.

Lepiota cf. elaiophylla Vellinga & Huijser PLATE 3

Piteus (15-)25-40(-50) mm broad, at first paraboloid to narrowly
hemispherical, then convex, expanding to plano-convex or applanate in age,
completely covered in warm brown to dark brown (7F5, 8F4, 8F6, 8F8, 9F5)
fibrils when young, quickly breaking up as the pileus expands into small to
medium, generally appressed scales of aggregated fibrils over a dull yellow (3A4,
3B5, 4A3, 4A2) background; fibrils concentrated at disc (sometimes remaining
unbroken) and gradually lessening towards margin to reveal more of surface;
margin aspect straight, shape entire to eroded in age, sometimes with medium
to large remnants of pileus covering adhering to margin, non-hygrophanous,
dry; CONTEXT <5 mm thick, yellow (3A3, 3A4, 4B4, 4A3) fading to brown or
reddish brown over time; LAMELLAE L = 32,1 = 3 (usually), free, ventricose, up
to 9 mm broad, dull yellow to sulphur yellow (3B6, 3B4), sometimes darkening
in age (3A4, 4B4, 4C5); stripe 20-40 x 3-7 mm, cylindrical (although sometimes
flattening near the pileus) and equal (rarely tapering downwards), yellow (3A3,
3B4, 3A4, 4B3, 4A2, 3B4), with a clear annular zone beginning *% to % from the
bottom of the stipe, above which the stipe appears glabrous, but remnants of
the white, cortina-like partial veil generally remain, uncommonly aggregating
into larger visible structures, below covered in medium to large, horizontally-
oriented brown scales, generally appressed, but more uplifted than those on
the pileus, concolorous with those on the pileus; CONTEXT fleshy-fibrous, color
as in pileus or slightly lighter; when young solid to stuffed with translucent to

482 ... Stallman & al.

white hyphae, hollow in age; RHIZOMORPHS present, white; BASAL TOMENTUM
generally present; SPORE DEPOSIT white; EDIBILITY toxic, likely contains
amatoxins; ODOR none to mildly fungal; TAsTE none to mild.

BASIDIOSPORES [150, 7, 5] (5.8-)7.0-7.2(-8.4) x (3.3-)3.7-3.8(-4.2)
um [x = 7.1-3.8 um], Q = (1.5-)1.9(-2.3) [Qm = 1.9], narrowly ellipsoid to
subcylindrical (usually oblong) in side view with a convex abaxial side and
straighter adaxial side (mild suprahilar depression rarely present), oblong
to subcylindrical in face view, hyaline in H,O and NH,OH, dextrinoid,
congophilous, weakly cyanophilic to cyanophilic and non-metachromatic in
Cresyl Blue, germ pore absent, mono- or (less commonly) bi-guttulate; BAsIDIA
[57,7,5] (20.6-)23.1-28.7(-34.6) x (5.7-)7.2-8.8(-9.2) um [x = 26 x 8 um],
narrowly clavate to clavate, hyaline, thin-walled, 4-spored, rarely 2-spored;
LAMELLAR-EDGE Sterile; CHEILOCYSTIDIA [39, 5, 4] (15.5-)20.1-30.1(-39.3)
x (5.2-)6.1-9.8(-10.3) um [x = 24.5 x 7.9 um], generally narrowly clavate to
clavate, but also cylindrical and somewhat flexuous, sometimes with an apical
extension, narrowly utriform, or less commonly subconical, often septate with
one to two short, cylindrical basal cells, with or without clamp connections,
hyaline, thin-walled; PLEUROCYSTIDIA absent; PILEUS COVERING an intricate
trichoderm of mostly long erect and repent, generally cylindrical hyphae with
brown intracellular and parietal pigments, lacking a layer of short clavate
elements, terminal cells 25-240 x 4-15 um, most commonly 60-100 um in
length, inflated cylindrical to narrowly clavate, often flexuous; STIPITIPELLIS
a cutis of narrowly cylindrical hyaline hyphae 3-7 um diam with stipe scales
below annular zone similar to scales on pileus, above this zone a covering of
thin, hyaline, cylindrical, often flexuous hyphae up to 4 um diam and 100 um
long; ANNULUS as a cortinoid zone only; rarely with stipe covering elements
aggregating to create a medial to superior raised region resembling an
adhering “ring”; CLAMP CONNECTIONS present in all tissues; may be absent in
cheilocystidia.

SPECIMENS EXAMINED—USA, Hawai‘i, Hawai‘i Island, Hilo District, University of
Hawai‘i Hilo Botanical Garden, 19°42’10”N 155°04’56”W, 28 September 2016, coll.
JKS 69 (HAW-F-00244); Hilo, ‘Imiloa Astronomy Center, 19°42’07”N 155°05’16’W,
5 October 2016, coll. JkKS 71 (HAW-F-00245; GenBank MK412589); 6 November
2016, coll. JKS 77 (HAW-F-00246; GenBank MK412588); Puna District, MacKenzie
State Recreation Area, 19°26’22”N 154°51’4”W, 15 November 2017, coll. JKS 174
(HAW-F-00247).

ECOLOGY & DISTRIBUTION—Scattered to gregarious, sometimes cespitose,
in wood chips, on nutrient-rich soil in disturbed settings, or on Casuarina
equisetifolia duff in wet, lowland, alien environments. January, May, and July

Lepiota punaensis sp. nov. (Hawai'i USA) ... 483

Pirate. 3. Lepiota cf. elaiophylla (HAW-F-00246). a. Basidiomata; b. Basidiospores; c. Basidia
(generally with four sterigmata; only two shown in these basidial views); d. Cheilocystidia; e. Pileus
covering.

to December. Currently only known from the Puna and South Hilo Districts
on Hawai‘i Island; L. elaiophylla in the broad sense (see discussion) is reported

484 ... Stallman & al.

from Australia, Europe, North America, South America, India, and possibly
Africa (as L. xanthophylla P.D. Orton).

ComMMENTS—Lepiota cf. elaiophylla occurs on wood chips, nutrient-rich soil
in disturbed environments such as gardens, and under coastal Casuarina
equisetifolia where it can fruit singly, or in large groups and cespitose clusters.
Although many yellow lepiotaceous fungi occur in Hawai‘i, L. cf. elaiophylla
is easily distinguishable by its overall sulphur yellow coloration (including the
gills) with brown scales on the pileus, robust stature (differentiating it from
delicate yellow species in Leucocoprinus), and clear annular zone on the stipe
with cortina-like partial veil remnants above a base covered in brown scales. Its
oblong spores and pileus covering of primarily long elements place this species
in L. subsect. Helveolinae with other species containing amatoxins.

A BLAST search reveals the top match by identity in GenBank to represent
a collection identified as Lepiota elaiophylla by Else Vellinga, the co-describer
of this species, from a greenhouse in Canada at 99.9% sequence similarity
(KP012854). The next closest match (at 98.3% similarity) is MH979467 from a
specimen collected near Darwin Australia growing in a native Eucalyptus and
Acacia swamp habitat (M. Barrett, pers. comm.). Micrographs of the Australian
collection (T. Lebel, pers. comm.) reveal spores that are more ellipsoid than
in most collections of L. cf. elaiophylla, so it is unclear without additional
Australian specimens whether these two taxa are morphologically identical.

Our phylogeny of Lepiota (Fic. 1) shows the Hawaiian L. cf. elaiophylla
and the Canadian collection identified as L. elaiophylla as identical, with the
Australian collection close on its own short branch. The Dutch paratype of
L. elaiophylla is sister to the clade containing the Hawaiian, Canadian, and
Australian collections, and a well-supported (84% bootstrap support, 1.0
Bayesian posterior probability) clade is formed when considering all taxa,
including the paratype collection. See TABLE 2 for a comparison of pairwise
genetic distances between the species discussed.

Lepiota elaiophylla was described from the Netherlands and is reported
throughout Europe (e.g., Holec & Halek 2008), Brazil (Wartchow & al. 2008,
Ferreira & Cortez 2012), India (Kumar & Manimohan 2009), and possibly
Africa (as L. xanthophylla; Pegler 1977). The Hawaiian L. cf. elaiophylla is
clearly closely related to L. elaiophylla, from which it is macroscopically
indistinguishable. The only differences are (morphologically) a more variable
cheilocystidia shape in L. cf. elaiophylla and (molecularly) a different nrITS
sequence, although some European collections outside the Netherlands and
Brazilian collections show variation in cheilocystidia shape.

Lepiota punaensis sp. nov. (Hawai'i USA) ... 485

For a discussion of other Lepiota spp. with yellow lamellae (including the
macroscopic lookalike L. xanthophylla, which is differentiated by containing
a layer of short, clavate elements in the pileus covering and which has not
been recorded from Hawai‘i), see Vellinga & Huijser (1997). Collections of
the European L. xanthophylla and L. elaiophylla are described with differently
colored dried lamellae (yellow in xanthophylla and dirty olive-brown for
elaiophylla). Collections of L. cf. elaiophylla generally have dark yellow lamellae
when dried, although older, poorly dried, or damaged specimens may exhibit
brown colors; so this does not appear to be a useful taxonomic feature at this
time.

More information is needed to distinguish species concepts among L. cf.
elaiophylla, the Australian collection, and L. elaiophylla from the Netherlands
and throughout its reported range. One option is to argue that L. cf. elaiophylla
falls within normal morphological variation (minor cystidia differences) of
L. elaiophylla, a widespread species with high molecular variation and some
morphological variation as evidenced by its presence in India (Kumar &
Manimohan 2009), Brazil (Wartchow & al. 2008, Ferreira & Cortez 2012),
and Australia. This option cannot be proven but falls on the conservative side
of not describing a new taxon without first examining molecular data from
other regions that might reveal whether there is a range of variation in the
nrITS or two distinct taxa. The other option is to argue that L. cf. elaiophylla is
clearly molecularly different from the Dutch L. elaiophylla (over 7% pairwise
distance) and supported by a morphological difference (cheilocystidia
shape). This argument is supported by pointing out that the related species
L. brunneoincarnata and L. subincarnata initially showed little to no molecular
variation across their respective geographic ranges (Europe and Central Asia;
Europe, South Asia, and North America) when examined by Razaq & al.
(2014).

At this time, more molecular data from Europe, South America, India (and
possibly Africa) and morphological data from India and Africa are needed to
clarify the species concept. The Indian collection was not given a full species
description, but collections from South America reportedly have smaller
spores as well as lageniform (Ferreira & Cortez 2012) or subfusoid (Wartchow
& al. 2008) cheilocystidia, while collections from greenhouses in Europe
primarily have narrowly clavate to clavate cheilocystidia (with the exception
of the subglobose, and oval to pyriform cheilocystidia noted by Breitenbach &
Kranzlin 1995). At this time, habitat does not seem to be a useful taxonomic
feature as both Hawaiian and Dutch collections have been found in greenhouse

486 ... Stallman & al.

environments, although only the Hawaiian L. cf. elaiophylla is currently

confirmed from non-artificial habitats in (sub)tropical environments.

Key to the Lepiota of Hawai'i Island

if

—

Oo OW

on

a

Pileus brownish with covering of acute pyramidal scales composed of
elobase on inflated, Clements t..:, 3.) ft os 2h 2 Se Se, sgce th eget Ser arp sca 2

. Pileus color variable (including brownish) with covering lacking

acute pyramidal scales, at least some long (2100 ttm) cylindrical

ClEMIENtS: PRESEHIS. fat. oo eee vate ten Un Mee cet MhrY cag stains Ovid ip ey « 3
. Basidiome with large membranous annulus,

spores oblong to cylindrical, averaging 6.4 x 2.7 um ................ L. aspera
. Basidiome annulus and other features poorly known,

spores ellipsoid to oblong, averaging 4.4 x 2.7m .............. 0.0. eee L. sp.

(MK412575; poorly known; see text)
. Basidiome with ellipsoid spores averaging 5X 3UM..... eee eee eee 4
. Basidiome with ellipsoid to oblong spores averaging 7 x 3-4um _............... 5

. Basidiome with prominent basal stipe ornamentation concolorous

with pileus scales; farinaceous odor when crushed; pileus and stipe
covering of long flexuose hyphae lacking abundant shorter clavate
Clemence s.r hen ween. Mer ety atten Sea eee ent ete eee, L. rubrobrunnea

. Basidiome generally lacking prominent basal stipe ornamentation,

stipe scales present usually lighter than pileus scales; lacking a
farinaceous odor when crushed; pileus and particularly stipe
covering with abundant short clavate elements ............... L. pseudorubella

. Basidiome with brown scales over a dull yellow pileus background,

lamellae and stipe also yellow; arachnoid partial veil usually leaving
only zone on stipe; pileus covering a trichoderm of long (<240 um)
elements lacking shorter cells..................0..000- Lepiota cf. elaiophylla

. Basidiome with warm brown scales over an off-white pileus background

lacking yellow coloration in all tissues; annulus a zone only;

pileus covering a trichoderm of long (<160 um) elements with

shorter, sometimes clavate hyphae interspersed but not in a distinct layer;
shorter hyphae more common in stipe covering, currently known only

from Casuarina equisetifolia duff in the Puna District of Hawai‘i

1S ha (6 hee pes A De nt ye prea, UM Rec Slay. pe Saas Ch ear L. punaensis

Acknowledgments

We would like to acknowledge the National Geographic Society, Puget Sound

Mycological Society, and Sonoma County Mycological Society for funding. Thank
you to Dr. Teresa Lebel and Dr. Matthew Barrett for sharing information on the
Australian collection (GenBank KP012854), to Sean Swift for a collection made on
O‘ahu (GenBank MK412617), and to Dr. Else Vellinga on a variety of topics related

Lepiota punaensis sp. nov. (Hawai'i USA) ... 487

to Lepiota taxonomy in general and L. elaiophylla in particular. We also thank
Dr. Brian A. Perry (Department of Biological Sciences, California State University
East Bay, USA) and Dr. Alfredo Vizzini (Department of Life Sciences & Systems
Biology, University of Torino, Italy) for presubmission review.

Literature cited

Aberdeen JEC. 1992. Lepiotoid genera (Agaricales) in south-eastern Queensland. Gailes,
Queensland: Aberdeen Publications.

Akers B. 1997. The family Lepiotaceae (Agaricales, Basidiomycetes) in Florida. PhD dissertation.
Southern Illinois University, Carbondale, IL.

Benjamin DR. 1995. Amatoxin syndrome poisoning by the amanitins. 198-241, in: Mushrooms
poisons and panaceas. New York: W.H. Freeman and Company.

Bon M. 1992. Clé analytique des cortinaires alpins (avec quelques incursions dans la rhodoraie
et laulnaie verte). Documents Mycologiques 22: 43-67.

Bon M. 1993 Flore mycologique d’Europe, 3. Les Lépiotes. Lepiotaceae Roze. Documents
Mycologiques Mémoire hors série no. 3: 1-153. Lille, France: LAssociation d’Ecologie et
Mycologie.

Breitenbach J, Kranzlin F. 1995. Fungi of Switzerland. volume 4. Agarics 2nd part. Switzerland:
Edition Mycologia Lucerne.

Caballero A, Vizzini A, Munoz G, Marco C, Ercole E. 2015. Lepiota elseae (Agaricales,
Agaricaceae), a new species of section Lepiota from Spain. Phytotaxa 201: 188-196.
https://doi.org/10.11646/phytotaxa.201.3.2

Ferreira AJ, Cortez VG. 2012. Lepiotoid Agaricaceae (Basidiomycota) from Sao Camilo State Park,
Parana State, Brazil. Mycosphere 3: 962-976. https://doi.org/10.5943/mycosphere/3/6/11

Gagné WC, Cuddihy LW. 1999. Vegetation. 45-114, in: WL Wagner & al. (eds). Manual of the
flowering plants of Hawai‘i. Honolulu, HI: Bishop Museum Press.

Grgurinovic CA. 1998. Larger fungi of South Australia. Botanic Gardens of Adelaide and State
Herbarium, Adelaide, Australia.

Gubitz C. 2008. Zwei neue Lepiota-Arten aus den Tropenhausern des Okologisch-Botanischen
Gartens der Universitat Bayreuth. Zeitschrift fiir Mykologie 74: 135-146.

Hemmes DE, Desjardin DE. 2002. Mushrooms of Hawai‘i. Berkeley, California: Ten Speed
Press.

Holec J, Halek V. 2008. Record of the rare greenhouse fungus Lepiota elaiophylla (Agaricales,
Agaricaceae) in Prague, Czech Republic, with notes on its taxonomy and distribution.
Mycotaxon 105: 433-439.

Huelsenbeck JP, Ronquist F. 2001. MRBAYES: Bayesian inference of phylogenetic trees.
Bioinformatics 17: 754-755. https://doi.org/10.1093/bioinformatics/17.8.754

Justo A, Angelini C, Bizzi A. 2015. Two new species anda new record of Lepiota (Basidiomycota,
Agaricales) from the Dominican Republic. Mycological Progress 14(56): [9 p.].
https://doi.org/10.1007/s11557-015-1080-9

Katoh K, Standley DM. 2013. MAFFT Multiple sequence alignment software version 7:
Improvements in performance and usability. Molecular Biology and Evolution 30:
772-780. https://doi.org/10.1093/molbev/mst010

Kirk PM, Cannon PF, Minter DW, Stalpers JA. 2008. Ainsworth & Bisby’s dictionary of the
fungi. 10th edition. CAB International, Wallingford, UK.
https://doi.org/10.1079/9780851998268.0000

488 ... Stallman & al.

Kearse M, Moir R, Wilson A, Stones-Havas S, Cheung M, Sturrock S, Buxton S & al.
2012. Geneious Basic: an integrated and extendable desktop software platform for the
organization and analysis of sequence data. Bioinformatics 28: 1647-1649.

Kornerup A, Wanscher JH. 1978. Methuen handbook of colour. Copenhagen, Denmark:
Politikens Forlag. https://doi.org/10.1093/bioinformatics/bts199

Kumar TK, Manimohan P. 2009. The genus Lepiota (Agaricales, Basidiomycota) in Kerala State,
India. Mycotaxon 107: 105-138. https://doi.org/10.5248/107.105

Kumar S, Stecher G, Li M, Knyaz C, Tamura K. 2018. MEGA X: Molecular evolutionary
genetics analysis across computing platforms. Molecular Biology and Evolution 35:
1547-1549. https://doi.org/10.1093/molbev/msy096

Liang JE, Yang ZL, Xu DP. 2011. A new species of Lepiota from China. Mycologia 103:
820-830. 10.3852/10-216. https://doi.org/10.3852/10-216

Liang JF, Yu F, Lu JK, Wang SK, Song J. 2018. Morphological and molecular evidence for two
new species in Lepiota from China. Mycologia 110: 494-501.
https://doi.org/10.1080/00275514.2018.1464333

Nawaz R, Khalid AN, Hanif M, Razaq A. 2013. Lepiota vellingana sp. nov. (Basidiomycota,
Agaricales) a new species from Lahore, Pakistan. Mycological Progress 12: 727-732.
https://doi.org/10.1007/s11557-012-0884-0

NCBI RC. 2015. Database resources of the National Center for Biotechnology Information.
Nucleic Acids Research 44: D7-D19. https://doi.org/10.1093/nar/gkv 1290

Nei M. Kumar S. 2000. Molecular evolution and phylogenetics. Oxford University Press, New
York.

Pegler DN. 1972. A revision of the genus Lepiota from Ceylon. Kew Bulletin 27: 155-202.
https://doi.org/10.2307/4117880

Pegler DN. 1977. A preliminary agaric flora of East Africa. Kew Bulletin Additional Series 6:
15-571.

Pegler DN. 1983. Agaric flora of the Lesser Antilles. Kew Bulletin Additional Series 9: 1-668.

Pereira AB. 1998. Espécies novas do género Lepiota (Agaricaceae) do sul do Brasil. Iheringia,
Série Botanica. 51: 227-247.

Pereira AB. 2000. Contribuicao ao conhecimento do género Lepiota no Brasil. I. Pesquisas,
Série Botanica 50: 27-77.

Pereira AB. 2001. Contribui¢gao ao conhecimento do género Lepiota no Brasil. II. Pesquisas,
Série Botanica 51: 7-30.

Qasim T, Khalid AN, Vellinga EC, Razaq A. 2015. Lepiota albogranulosa sp.nov. (Agaricales,
Agaricaceae) from Lahore, Pakistan. Mycological Progress 14(24): [6 p.].
https://doi.org/10.1007/s11557-015-1037-z

Qasim T, Khalid AN, Vellinga EC. 2016. A new species of Lepiota, Lepiota lahorensis, from
Lahore, Pakistan. Turkish Journal of Botany 40: 419-426.
https://doi.org/10.3906/bot-1507-31

Razaq A, Vellinga EC, Ilyas S, Khalid AN. 2014. Lepiota brunneoincarnata and L. subincarnata:
distribution and phylogeny. Mycotaxon 126: 133-141. https://doi.org/10.5248/126.133

Rick J. 1905. Pilze aus Rio Grande do Sul. Annales Mycologici 3: 235-240.

Rick J. 1907. Contributio ad monographiam Agaricacearum et Polyporacearum Brasiliensium.
Brotéria, Série Botanica 6: 65-92.

Rick J. 1920. Contributio ad monographiam Agaricacearum Brasiliensium. Brotéria, Série
Botanica 18: 48-63.

Rick J. 1926. Descripcao de algumas especies novas da mycoflora Riograndense. Egatea 11: 16-17.

Lepiota punaensis sp. nov. (Hawai'i USA) ... 489

Rick J. 1930. Contributio IV ad monographiam Agaricacearum Brasiliensium. Brotéria, Série
Botanica 24: 97-118.

Rick J. 1937. Agarici riograndenses. Lilloa 1: 307-346.

Rick J. 1938. Agarici riograndensis. II. Lilloa 2: 251-316.

Rick J. 1961. Basidiomycetes eubasidii in Rio Grande do Sul, Brasilia, 5. Iheringia, Série
Botanica 8: 296-449.

Schoch, CL, Seifert KA, Huhndorf S, Robert V, Spouge JL, Levesque CA & al. 2012. Nuclear
ribosomal internal transcribed spacer (ITS) region as a universal DNA barcode marker
for Fungi. Proceedings of the National Academy of Sciences USA 109: 6241-6246.
https://doi.org/10.1073/pnas.1117018109

Sysouphanthong P, Hyde KD, Chukeatirote E, Bahkali AH, Vellinga EC. 2012. Lepiota
(Agaricales) in Northern Thailand — 2. Lepiota section Lepiota. Cryptogamie, Mycologie
33: 25-42. https://doi.org/10.7872/crym.v33.iss1.2012.025

Sysouphanthong P, Guo J, Hyde K, Xu J, Mortimer P. 2016. Lepiota thailandica (Agaricaceae),
a new species from Thailand. Phytotaxa 245: 262-270.
https://doi.org/10.11646/phytotaxa.245.4.3

Vellinga EC. 2001. 4. Macrolepiota. 5. Leucocoprinus. 6. Leucoagaricus. 7. Lepiota. 8.
Chamaemyces. 9. Cystolepiota. 64-162, in: ME Noordeloos & al. (eds). Flora Agaricina
Neerlandica 5. Rotterdam, Netherlands: A. A. Balkema Publishers.

Vellinga, EC. 2003. Phylogeny of Lepiota (Agaricaceae)--Evidence from nrITS and nrLSU
sequences. Mycological Progress 2: 305-322. https://doi.org/10.1007/s11557-006-0068-x

Vellinga EC. 2006. Lepiotaceous fungi in California, U.S.A. - 4. Type studies of Lepiota
fumosifolia and L. petasiformis. Mycotaxon 98: 225-232.

Vellinga EC, Huijser HA. 1997. Lepiota xanthophylla and its greenhouse counterpart.
Bollettino Gruppo Micologico G. Bresadola, n.s. 40: 457-464.

Vellinga EC, Sysouphanthong P, Hyde KD. 2011. The family Agaricaceae: phylogenies and two
new white-spored genera. Mycologia 103(3): 494-509. https://doi.org/10.3852/10-204
Wartchow EF, Putzke J, Cavalcanti MAdQ. 2008. Agaricaceae Fr. (Agaricales, Basidiomycota)
from areas of Atlantic Forest in Pernambuco, Brazil. Acta Botanica Brasilica 22: 287-299.

https://doi.org/10.1590/S0102-33062008000100026

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 491-500
https://doi.org/10.5248/135.491

Notes on rust fungi in China 8.
Pucciniastrum tiliae life cycle and
new host plants inferred from phylogenetic evidence

JING-XIN Jr, ZHUANG L?’, Yu Lr’, MAKOTO KAKISHIMA®?®

‘Engineering Research Center of Chinese Ministry of Education for Edible and Medicinal Fungi,
Jilin Agricultural University, Changchun, Jilin 130118, China

College of Plant Protection, Shandong Agricultural University, Taian 271000, China

>University of Tsukuba, Tsukuba, Ibaraki 305-8572, Japan

* CORRESPONDENCE TO: * 1096314395@qq.com * kakishima.makoto.ga@u.tsukuba.ac.jp

ABSTRACT—The life cycle connection between spermogonial and aecial stages of a rust
fungus found on Abies holophylla and uredinial and telial stages on Tilia mongolica and
T. mandshurica collected in northeast China were confirmed by phylogenetic analyses.
The rust, identified as Pucciniastrum tiliae, was confirmed by morphological observations.
The life cycle of this rust fungus is reported for the first time in China, and A. holophylla
and T: mongolica represent new host plants for the species.

Key worps—phylogeny, Pinaceae, Pucciniastreae, Tiliaceae, tree disease

Introduction

Pucciniastrum tiliae was first described with uredinial and telial stages on
Tilia cordata var. japonica [= T: japonica; Tiliaceae| collected in Hokkaido,
Japan (Hiratsuka 1897). This species has been since reported on T: amurensis
in Korea, China, and Russian Far East; T: americana and T. kiusiana in Japan;
T. mandshurica in China and Russian Far East; T. maximowicziana
[= T. miyabei] in China and Japan; T: platyphyllos in Japan; and T! tuan in
China (Hiratsuka 1936, 1958; Ito 1938; Cummins 1950; Cummins & Ling
1950; Wang 1951; Kim 1963; Tai 1979; Hiratsuka & al. 1992; Azbukina 2005,

492 ... Ji &al.

2015). The life cycle of this fungus was revealed by Kamei in Japan in 1934
through inoculations of basidiospores from teliospores on T: japonica and
T. maximowicziana into needles of Abies sachalinensis var. mayriana (Pinaceae)
(Hiratsuka & al. 1992). Although P tiliae is distributed in northeast China (Tai
1979), there are no reports of a spermogonial and aecial host in the country.

During field investigation of rust fungi in northeast China, we collected
uredinial and telial stages of Pucciniastrum on T. mandshurica and T: mongolica
in the mountains of Jilin and Heilongjiang Provinces. We also observed
occurrences of aecia producing long peridia on Abies holophylla near infected
trees of Tilia. Therefore, we suspected life cycle connections between the rust
on Abies and Tilia. Inoculation of plants by spores are an appropriate method
to clarify rust life cycles (Ji & al. 2017a, b). However, collection and propagation
of plants from the mountains of Maple Valley (Jilin) and Fenix National Park
(Heilongjiang) where we collected specimens are strictly prohibited as they
are nature conservation areas. Therefore, we applied molecular analyses to
resolve these problems and to clarify the life cycle (Liu & Hambleton 2013,
Ji & al. 2016, Padamsee & McKenzie 2017, Scholler & al. 2019). We report
here the results of phylogenetic analyses and morphological observations of
the specimens.

Materials & methods

Molecular analyses

Uredinial and telial stages on Tilia mandshurica and T: mongolica collected in
mountains in Jilin and Heilongjiang Provinces, China, were used for molecular
analyses. The spermogonial and aecial stages on Abies holophylla collected in Jiaohe,
Jilin Province, China, were also used for analyses.

The total genomic DNA was directly extracted from c. 200 spores obtained from
single sori on the leaf of each specimen using similar methods reported by Ji & al.
(2016, 2019). Specimens used in the experiments were deposited in the Herbarium
of Mycology, Engineering Research Center of Chinese Ministry of Education for
Edible and Medicinal Fungi, Jilin Agricultural University, China (HMJAU); all data
sequenced in this experiment were deposited in GenBank as shown in specimens
examined.

The sequences obtained from specimens were aligned following Ji & al. (2019).
ITS and 28S sequences related to P tiliae were retrieved from GenBank and added
to phylogenetic analyses (Ji & al. 2019). The accession numbers of these data are
shown in the phylogenetic trees (Fics 1, 2). Phylogenetic trees were constructed
using Melampsora laricis-populina Kleb. as outgroup according to Ji & al. (2019).
The alignment and trees were deposited in TreeBASE under http://purl.org/phylo/
treebase/phylows/study/TB2:S24909 (Fics 1, 2).

Pucciniastrum tiliae in China ... 493

Pucciniastrum tiliae HMJAU8581 [Tilia mandshurica|UT
Pucciniastrum tiliae HMSJAU8582 [Tilia mongolica|UT
satepii.nd Pucciniastrum tiliae HMJAU8583 [Tilia mongolica|UT
=< Pucciniastrum tiliaeg HMJAU8584 [Tilia mongolica|UT

65\68\0,94| [Pucciniastrum tiliae (AB 221412) [Tilia mandshurica]
Pucciniastrum tiliae (AB 221415) [Tilia japonica]
Pucciniastrum tiliae HMJAU8641 [Abies holophylla|SA
Thekopsora triangula (KF551204) [Cornus macrophylla]
Thekopsora ostryae (KC416004) [Ostrya japonica]
Thekopsora ostryae (KC415993) [Ostrya japonica]
Pucciniastrum agrimoniae (MG787142) [Agrimonia pilosa]
Pucciniastrum agrimoniae (MG787143) [Agrimonia pilosa]
Pucciniastrum agrimoniae (MG787145) [Agrimonia pilosa]
Pucciniastrum agrimoniae (KJ725375)
Thekopsora lanpingensis (KF551208) [Cornus schindleri]
100\100\1;7ekopsora lanpingensis (KF551211) [Cornus walteri]
Thekopsora lanpingensis (KF551213) [Cornus schindleri]
Thekopsora lanpingensis (KF551214) [Cornus officinalis |
Pucciniastrum coronispora (MH780998) [Galium trifidum]
Pucciniastrum coronispora (MG787127) [Galium davuricum]
Pucciniastrum coronispora (MG787128) [Galium boreale]
Pucciniastrum coronispora (MG787132) [Galium bungei|
Thekopsora nipponica (KC416003) [Galium aparine]

L00\100\I-7hekopsora nipponica (KC415995) [Galium aparine]
Pucciniastrum rubiae (MG787136) [Rubia cordifolia]
#1*\0.56| [Pucciniastrum rubiae (MG787139) [Rubia chinensis]
Pucciniastrum rubiae (MG787140) [Rubia chinensis]
Pucciniastrum guttata (KC415999) [Galium odoratum]
Pucciniastrum rubiae (KC616007) [Rubia cordifolia]
Pucciniastrum annulospora (MH781004) [Kalimeris integrifolia]
97 | Pucciniastrum annulospora (MH781003) [Aster tataricus]

Pucciniastrum annulospora (MG787133) [Kalimeris lautureana]

‘Melampsora laricis-populina (MG787151) [Populus sp.]

70\*\0.75

98\97\0,89
79\82\0.86

99\L00\0.

0.04

Fic. 1. Phylogenetic tree constructed by Bayesian method based 28S rDNA sequences. MP/ML
bootstrap values precede Bayesian posterior probabilities (Bpp) on the nodes. Asterisks (*) indicate
bootstrap values <50% or Bpp <0.5. Sample data include species name, (voucher specimen or
GenBank accession number), and [host plant]. Sequences generated in this study are shown in
bold face. SA= Spermogonial and aecial stages; UT = Uredinial and telial stages.

Morphological observations

Light (LM) and scanning electron (SEM) microscopy were used to examine
morphological characters of rust specimens, including the size and shape of sori and
spores following Ji & al. (2019).

Phylogenetic results

The 28S dataset comprised 33 sequences with 496 total characters, of which 394
were constant, 30 parsimony-uninformative variable, and 72 parsimony-informative.
Parsimony analysis yielded one parsimonious tree with TL = 156, CI = 0.7692,
RI = 0.9231, and RC = 0.7101. Bayesian analysis resulted in average standard
deviation of split frequencies of 0.008983. The ITS dataset comprised 39 sequences
of 745 total characters, of which 228 were parsimony-informative. Parsimony

A494 ... Ji & al.

Pucciniastrum coronispora (MH780990) [Galium trifidum]
98\97\1] Pucciniastrum coronispora (MG787102) [Galium davuricum]
Pucciniastrum coronispora (MG787103) [Galium boreale]
1OO\OO Pr cciniastrum coronispora (MG787107) [Galium bungei|
Pucciniastrum nipponica (KC415792) [Galium davuricum]
16\9 1O0\1 00} Mcciniastrum nipponica (KC415794) [Galium aparine]
Pucciniastrum nipponica (KC415793) [Galium aparine]
Pucciniastrum annulospora (MG787108) [Kalimeris lautureana]
00\TOO q Pucciniastrum annulospora (MH780995) [Aster tataricus]
Pucciniastrum annulospora (MH780996) [Kalimeris integrifolia]
Pucciniastrum guttatum (KC415789) [Galium odoratum]
Pucciniastrum guttatum (KC415790) [Galium odoratum]
Pucciniastrum guttatum (KC415791) [Galium odoratum]
Pucciniastrum rubiae (MG787114) [Rubia chinensis]
Pucciniastrum rubiae (MG787115) [Rubia chinensis]
Pucciniastrum rubiae (KC415799) [Rubia cordifolia]
100\9 Pucciniastrum rubiae (KC415802) [Rubia cordifolia]
Pucciniastrum rubiae (KC415801) [Rubia cordifolia]
83\59\0.67 Pucciniastrum rubiae (MG787111) [Rubia cordifolia]
Pucciniastrum tiliae HMJAU8581 [Tilia mandshurica}UT
Pucciniastrum tiliae HMJAU8583 [Tilia mongolica}UT
Pucciniastrum tiliae HMJAU8641 [Abies holophylla]SA
65\*\0.8] Pucciniastrum tiliae HMJAU8582 [Tilia mongolica|UT
Pucciniastrum tiliae HMJAU8584 [Tilia mongolica}UT
9ON\9G\1I| Pucciniastrum tiliae (AB 221453) [Tilia japonica]
SOM Pucciniastrum tiliae (AB 221455) [Tilia mandshurica]
INIG\I Pucciniastrum kusanoi (AB221426) [Clethra barbinervis]
9NIN\I" Pucciniastrum boehmeriae (AB221449) [Boehmeria tricuspis]
Thekopsora triangula (KF551219) [Cornus macrophylla]
Pucciniastrum agrimoniae (MG787117) [Agrimonia pilosa]
100\100\1|Pucciniastrum agrimoniae (MG787118) [Agrimonia pilosa]
99\100 Pucciniastrum agrimoniae (MG787120) [Agrimonia pilosa]
‘Pucciniastrum agrimoniae (KJ486537)
Thekopsora ostryae (KC415796) [Ostrya japonica]
71\85\0.81 Thekopsora lanpingensis (KF551220) [Cornus walteri]
100\100\1| 7hekopsora lanpingensis (KF551222) [Cornus schindleri]
Thekopsora lanpingensis (KF551225) [Cornus schindleri]

Thekopsora lanpingensis (KF551224) [Cornus officinalis |
Melampsora laricis-populina (MG787126) [Populus sp.]

9ON\I\I

Fic. 2. Phylogenetic tree constructed by Bayesian method based on ITS rDNA sequences. MP/
ML bootstrap values precede Bayesian posterior probabilities (Bpp) on the nodes. Asterisks (*)
indicate bootstrap values <50% or Bpp <0.5. Sample data include species name, (voucher specimen
or GenBank accession number), and [host plant]. Sequences generated in this study are shown in
bold face. SA= Spermogonial and aecial stages; UT = Uredinial and telial stages.

analysis yielded one parsimonious tree with TL = 543, CI = 0.8066, RI = 0.9417, and
RC = 0.7596. Bayesian analysis resulted in average standard deviation of split
frequencies of 0.003112. Tree topologies formed by MP, ML, and MCMC methods
were identical among trees. The Bayesian phylogenetic trees are shown in Fic. 1
(28S) and Fie. 2 (ITS).

Both 28S and ITS phylogenetic trees included the uredinial and telial stages on
T. mandshurica (HMJAU 8581) and T: mongolica (HMJAU 8582, 8583, 8584) and the
spermogonial and aecial stages on A. holophylla (HMJAU 8641) in a monophyletic
clade (Fics 1, 2). Genetically identical to one another, they can be considered
the same species. The life connection between spermogonial and aecial stages on
A. holophylla and uredinial and telial stages on T: mandshurica and T: mongolica is
therefore strongly supported by the phylogenetic analyses.

Pucciniastrum tiliae in China ... 495

Taxonomy

The phylogenetic analyses reveal that this rust fungus has a
heteromacrocyclic life cycle, producing spermogonia and aecia on Abies
holophylla (Fic. 3p) and uredinia and telia on Tilia mandshurica and
T. mongolica (Figs 3a-c). LM and SEM observations showed that the
morphological characteristics of spermogonial and aecial specimens on
A. holophylla collected from the field were identical with the descriptions
of Pucciniastrum tiliae reported by Hiratsuka (1936) and Hiratsuka & al.
(1992), except for outer wall surface structure of the peridial cells (Fics 3p,
4A-C, A-D). Under SEM, these walls are minutely verrucose, in contrast to
the smooth surface described by Hiratsuka & al. (1992). Previously, P. tiliae
spermogonial and aecial stages have been reported on Abies species only
from Japan, so this represents the first report of the P. tiliae life cycle from
China. Abies holophylla is a new spermogonial and aecial host plant and
occurs in northeastern China, Korea, and Russian Far East.

After clarifying the life cycle connection of P tiliae with phylogenetic
analyses, we described its morphology based on specimens collected in the
field.

The morphological characters of uredinial and telial specimens on
T. mandshurica and T: mongolica were similar to one another (Fics 34-c,
4D-F, 5E,F) and identical to the descriptions of P. tiliae by Hiratsuka (1936),
Hiratsuka & al. (1992) and Azbukina (2005, 2015). No researcher has
previously reported P. tiliae on T. mongolica (Hiratsuka 1936, 1958; Kim
1963; Tai 1979; Hiratsuka & al. 1992; Azbukina 2005, 2015), so we add
T: mongolica (known from Mongolia, northern China, and eastern Russia)
as a new host for the rust.

Pucciniastrum tiliae Miyabe, Bot. Mag. Tokyo 11: 47, 1897. Figs 3-5

Spermogonia amphigenous, pale yellow to yellowish, subcuticular, type 3
(Cummins & Hiratsuka 2003). Aecia with long peridia, Peridermium-type,
hypophyllous, cylindrical, orange-yellow. Peridia colorless, rupturing at the
sides and apex; peridial cells ovate to ellipsoid, slightly overlapping, inner and
outer walls thin, minutely verrucose. Aeciospores globose to ellipsoid, 15.0-22.0
x 13.0-16.5 um (av. = 18.5 x 15.0 um), walls hyaline, 1.0-2.0 um (av. = 1.5 um)
thick, densely verrucose with annulate verrucae.

Uredinia hypophyllous, scattered to gregarious, subepidermal, small,
round, covered by the epidermis, rupturing with pores, pulverulent. Peridia
hemispherical, delicate, firm, rupturing at the apex, peridial cells small,

496 ... Ji & al.

Fic. 3. Pucciniastrum tiliae. A. Uredinia and telia on lower leaf surface of Tilia mongolica. B. Telia
produced on lower leaf surface of T: mongolica. C. Uredinia produced on lower leaf surface of
T. mongolica. D. Aecia with long peridia produced on needles of Abies holophylla.

irregularly polygonal, walls smooth, thin, ostiolar cells rounded, walls
smooth. Urediniospores subglobose, ellipsoid, obovate, or oblong, 16.5-25.5
x 8.0-15.5 um (av. = 20.5 x 12.5 um), walls echinulate, 0.5-2.0 um (av. = 1 um)
thick. Telia hypophyllous, subepidermal, scattered or in small groups, at
first orange-yellow, then brown to reddish in color. Teliospores forming
under the epidermis, attached laterally, subglobose, oblong, or somewhat
angular, divided into 2-6 cells by vertical or oblique septa, 21.0-37.0 x
5.5-14.0 um (av. = 30.5 x 9.5 um), walls thin, 0.5-1.0 um (av. = 0.7 um)
thick, smooth.

SPECIMENS EXAMINED—CHINA, Jilin Province, Jiaohe, stages 0 & I, on Abies
holophylla Maxim., 16 June 2019 (HMJAU8641, GenBank MN294706, MG787116);
stages II & IH, on Tilia mongolica Maxim., 11 September 2017 (HMJAU8583, GenBank
MG787149, MG787124; HMJAU8584, GenBank MG787150, MG787125); Helongjiang

Pucciniastrum tiliae in China ... 497

Fic. 4. Pucciniastrum tiliae observed with LM. A. Vertical section of spermogonium (type 3).
B. Aeciospores with verrucose surface. C. Vertical section of aecium surround by peridium (P).
D. Urediniospores with echinulate surface. E. Vertical section of uredinium with peridium (P),
opening by central pore. F. Vertical section of telia with laterally attached teliospores, covered by
host epidermis. Scale bars: A, C = 20 um; B = 30 um; D, E= 10 um; F = 15 um.

Province, Wuchang, stages II & III, on T: mongolica, 9 September 2017 (HMJAU8582,
GenBank MG787148, MG787123); stages Il & II, on T: mandshurica Rupr. & Maxim.,
9 September 2017 (HMJAU8581, GenBank MG787147, MG787122).

498 ... Ji & al.

Fic. 5. Pucciniastrum tiliae observed with SEM. A. Aeciospores with densely verrucose surface.
B. Aecium with long peridium. C. Outer walls of peridial cells. D. Inner walls of peridial cells.
E. Urediniospores with echinulate surface. F. Uredinium with peridium (P) and ostiolar cells (O),
opening by central pore. Scale bars: A, E = 5 um; B = 100 um; C, D = 20 um; F = 10 um.

Pucciniastrum tiliae in China ... 499

Hosts & DISTRIBUTION WITHIN CHINA—Abies holophylla, Jilin (new host;
this paper). Tilia amurensis Rupr., Jilin (Ito 1938, Tai 1979). Tilia mandshurica,
Heilongjiang (Ito 1938, Hiratsuka 1958, Tai 1979). Tilia mongolica, Heilongjiang,
Jilin (new host; this paper). Tilia tuan Szyszyt., Guizhou (Hiratsuka 1958, Tai 1979).

Acknowledgments

This work was financed by the Fungal Flora in Jilin Province (20130206073NY).
We thank Dr. E.H.C. McKenzie (Manaaki Whenua Landcare Research, Auckland,
New Zealand) and Prof. C.M. Denchev (Bulgarian Academy of Sciences, Sofia,
Bulgaria) for critical reading of the manuscript and suggestions.

Literature cited

Azbukina ZM. 2005. Rust fungi. Cryptogamic plants, fungi and mosses of the Russian Far East,
vol. 5. Dalnauka, Vladivostok. (In Russian)

Azbukina ZM. 2015. Definitorium fungorum Rossiae, Ordo Pucciniales 1. Dalnauka,
Vladivostok.

Cummins GB. 1950. Urediniales of continental China collected by S.Y. Cheo. I. Mycologia 42:
779-797. https://doi.org/10.1080/00275514.1950.12017881

Cummins GB, Hiratsuka Y. 2003. Illustrated genera of rust fungi, 3% ed. American
Phytopathological Society, St. Paul, Minnesota.

Cummins GB, Ling L. 1950. An index of the plant rusts recorded for continental China and
Manchuria. Plant Disease Reporter (Supplement) 196: 520-556.

Hiratsuka N. 1897. Notes on some Melampsorae of Japan. Botanical Magazine Tokyo 11: 45-49.

Hiratsuka N. 1936. A monograph of the Pucciniastreae. Memoirs of Tottori Agricultural College
4. 374 p.

Hiratsuka N. 1958. Revision of taxonomy of the Pucciniastreae. Memoirs of the Faculty of
Agriculture, Tokyo University of Education 5. 167 p.

Hiratsuka N, Sato S, Katsuya K, Kakishima M, Hiratsuka Y, Kaneko S, Ono Y, Sato T, Harada
Y, Hiratsuka T, Nakayama K. 1992. The rust flora of Japan. Tsukuba-shuppankai, Tsukuba.

Ito S. 1938. Mycological flora of Japan, vol. 2, no. 2, Urediniales-Melampsoraceae. Yokendo,
Tokyo.

Ji JX, Li Z, Wan Q, Li Y, Kakishima M. 2016. Notes on rust fungi in China 1. Autoecious life
cycle of Puccinia tatarinovii on Prenanthes. Mycotaxon 131: 653-661.
http://dx.doi.org/10.5248/131.653

Ji JX, Li Z, Wan Q, Li Y, Kakishima M. 2017a. Life cycle of Aecidium klugkistianum on Ligstrum
and its new combination, Puccinia klugkistiana. Mycoscience 58: 307-311.
https://doi.org/10.1016/j.myc.2017.01.004

Ji JX, Li Z, Wan Q, Li Y, Kakishima M. 2017b. Notes on rust fungi in China 3. Puccinia
adenocauli comb. nov. and its life cycle and new host. Mycotaxon 132: 141-148.
http://dx.doi.org/10.5248/132.141

Ji JX, Li Z, Li Y, Kakishima M. 2019. Two new species of Pucciniastrum producing dimorphic
sori and spores from northeast of China. Mycological Progress 18: 529-540.
https://doi.org/10.1007/s11557-018-1460-z

Kim CJ. 1963. A provisional list of Uredinales of Korea. Korean Journal of Microbiology 1: 51-64.

500 ... Ji & al.

Liu M, Hambleton S. 2013 Laying the formation for a taxonomic review of Puccinia coronata s.l.
in a phylogenetic context. Mycological Progress 12: 63-89.
https://doi.org/10.1007/s11557-012-0814-1

Padamsee M, McKenzie EHC. 2017. The intriguing and convoluted life of a heteroecious rust
fungus in New Zealand. Plant Pathology 66: 1248-1257. https://doi.org/10.1111/ppa.12672

Scholler M, Lutz M, Aime MC. 2019. Repeated formation of correlated species in Tranzschelia
(Pucciniales). Mycological Progress 18: 295-303. https://doi.org/10.1007/s11557-018-1417-2

Tai FL. 1979. Sylloge fungorum sinicorum. Science Press, Beijing.

Wang YZ. 1951. Index Uredinearum sinensium. Academia Sinica, Beijing.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 501-512
https://doi.org/10.5248/135.501

Guayaquilia gen. nov., typified by /driella cubensis

FREDDY MAGDAMA’, DAYNET SOSA’, FERNANDO ESPINOZA’,
LIZETTE SERRANO’, SIMON PEREZ-MARTINEZ’, ELAINE MALOSSO},
MARGARITA HERNANDEZ-RESTREPO*, RAFAEL F. CASTANEDA-RUIZ>

' Escuela Superior Politécnica del Litoral, ESPOL,
Centro de Investigaciones Biotecnologicas del Ecuador, Campus Gustavo Galindo,
Km. 30.5 Via Perimetral, RO. Box 09-01-5863, Guayaquil, Ecuador
? Universidad Estatal de Milagro (UNEM1I), Facultad de Ingenieria,
Cdla. Universitaria Km. 1.5 via Milagro-Km26. Milagro 091706, Guayas, Ecuador
> Centro de Biociencias, Departamento de Micologia, Universidade Federal de Pernambuco,
Avenida da Engenharia, s/n Cidade Universitaria, Recife, PE, 50.740-600, Brazil
* Westerdijk Fungal Biodiversity Institute, 3508 AD Utrecht, The Netherlands
° Instituto de Investigaciones Fundamentales en Agricultura (INIFAT),
Tropical Alejandro de Humboldt, OSDE, Grupo Agricola,
Calle 1 Esq. 2, Santiago de Las Vegas, C. Habana, Cuba, C.P. 17200

* CORRESPONDENCE TO: dasosa@espol.edu.ec

ABSTRACT—A new genus Guayaquilia is established to accommodate Idriella cubensis based
on morphology and phylogenetic analysis. DNA sequence data place these specimens as
incertae sedis separate from Microdochiaceae (Xylariales), forming a monophyletic lineage
separated from Neoidriella desertorum and phylogenetically distant from Idriella. The novel
genus is characterized by macronematous, tree-like, fasciculate, profuse dichotomously,
alternately, or irregularly branched, brown conidiophores with polyblastic, denticulate,
sympodial extended, intercalary and terminal conidiogenous cells that produce solitary,
sublunate, subnavicular, lunate, inequilateral, (0-)1-septate, hyaline conidia.

KEY worps—asexual fungi, hyphomycetes, Microdochiaceae, taxonomy, tropics

Introduction
Idriella, introduced by Nelson & Wilhelm (1956) with I. lunata as type species,
is distinguished by macronematous, mononematous, unbranched, and basally

502 ... Magdama & al.

inflated and apically slightly geniculate brown conidiophores, mostly reduced
to polyblastic, denticulate, sympodial extended conidiogenous cells. Conidia
are typically lunate or falcate, unicellular, hyaline, and acuminate towards the
apex (Nelson & Wilhelm 1956). Morgan-Jones (1979) updated and provided
brief nomenclatural commentaries on Idriella australiensis, I. couratarii,
I. desertorum, I. lunata, I. mycogonoidea, I. ramosa, I. vandalurensis, and
I. variabilis and proposed two new species, I. angustispora and I. bambusae.
Von Arx (1981), who presented a combined key for Idriella and Microdochium
species, proposed the conidial shape and the habitat as the main characters to
separate the genera; he included the Idriella species treated by Morgan-Jones
(1979), excluded I. tropicalis as similar to I. variabilis, and added five new
combinations (J. bolleyi, I. caespitosa, I. falcata, I. grisea, and I. tainanensis).
Subsequently, 16 new species have been described I. acerosa, I. amazonica,
I. angamosensis, I. asaicola, I. cagnizarii, I. campnospermae, I. cubensis,
I. euterpes, I. jambosae, I. licualae, I. mycophila, I. rara, I. rhododendri,
I. setiformis, I. stilboidea, and I. uncinospora (Castaheda-Ruiz 1985, 1986;
Castaneda-Ruiz & Arnold 1985; Castafteda-Ruiz & Kendrick 1991; Castafieda-
Ruiz & al. 1997; Matsushima 1985, 1995; Rodrigues & Samuels 1990, 1992;
Subramanian & Bhat 1987; Wu & al. 1997).

When the generic concept of Idriella was expanded, it becamea heterogeneous
genus (Seifert & al 2011). In the generic type, I. lunata, conidiophores are
unbranched and mostly reduced to conidiogenous cells producing unicellular
conidia on tiny denticles arranged along the apical and subapical surface of
each conidiogenous cell after several sympodial holoblastic extensions (Nelson
& Wilhelm 1956), but many other Idriella species produce conidiophores
branched in various patterns, sympodial extensions of the conidiogenous
cells confined to a small, nodose area at the apex, and conidiogenous loci as
inconspicuous denticles that produce unicellular or septate conidia. DNA
sequences of several Idriella species revealed the polyphyletic nature of this
genus, showing phylogenetic separation between I. lunata (type species) and
four other Idriella species, which consequently were transferred to four new
genera: Castanediella Hern.-Restr. & al., Idriellopsis Hern.-Restr. & Crous,
Neoidriella Hern.-Restr. & Crous, and Paraidriella Hern.-Restr. & Crous (Crous
& al. 2015, Hernandez-Restrepo & al. 2016).

During a workshop on fungal diversity conservation in Cacao forest areas,
two surveys of microfungi were conducted in Theobroma cacao plantations in
Guayaquil, Guayas Province, Ecuador, and several Idriella-like specimens were
found. LSU and ITS sequence analyses place these specimens as incertae sedis

Guayaquilia cubensis gen. & sp. nov. (Cuba, Ecuador) ... 503

and separate from Microdochiaceae (Xylariales). They are not congeneric with
Idriella lunata (the generic type), and we propose a new genus Guayaquilia to
accommodate them.

Materials & methods

Sampling and fungal strains studied

Samples of decaying plants were placed in plastic bags, transported to the
laboratory, placed in moist chambers, and treated according to Castafeda-Ruiz & al.
(2016). Individual conidia were separated from the plant material under a stereoscope
using an entomological needle and cultured in two different media: V8 (V8: 125 ml
V8 juice, 18 g agar, 1000 ml distilled water, pH 6.3) and Cornmeal agar (CMA: 20
g cornmeal, 18 g agar, 1000 ml distilled water, pH 6.3). Morphological observations
were made from cultures grown on CMA after five days, incubated at 25 + 1°C under
12 h alternating near-UV light and darkness (using Vica, FLB-20W T10 near-UV
lamp in an irradiation box). Colony colors were coded according to Rayner (1970).
Mounts were prepared in lactic acid (90%) or in polyvinyl alcohol-glycerol (8 g PVA
in 100 mL of water + 5 mL of glycerol) and lactofuchsin (0.1 g acid fuchsin, 100 mL
85% lactic acid) (Carmichael 1955). Microscopic characters were measured at x1000
using a Nikon Eclipse Ni-U microscope with DIC optics and a Nikon DS-Fi2 camera.

Pure cultures were deposited at the Microbial Culture Collection of the
Biotechnology Research Center, Guayaquil, Ecuador (CCM-CIBE), and the voucher
specimens and slide preparations were deposited in the Herbarium, Departamento
de Micologia, Universidade Federal de Pernambuco, Recife, Brazil (URM). Also
examined were the holotype and another specimen deposited as Idriella cubensis in
the INIFAT Fungus Collection.

DNA extraction, sequencing, and phylogenetic analysis

Genomic DNA was extracted from fresh mycelia grown on V8 Agar at 25°C using
a modified rapid extraction method for filamentous fungi according to Cenis (1992).
The primer pairs ITS1/ITS4 (White & al. 1990) and LROR/LRS (Vilgalys & Hester
1990) were used for the amplification of the internal transcribed spacers (ITS), and
part of the large subunit of the nuclear ribosomal RNA gene (LSU). PCR cycling
conditions followed Korabecna (2007; ITS) and Yang & al. (2017; LSU). PCR products
were sent to Macrogen Korea for purification and sequencing with the same primers.

Sequences were aligned and edited using MEGA v.6.0. Phylogenetic relationships
among taxa were addressed through Maximum Likelihood (ML) analysis using
MEGA v.6.0 and Bayesian analysis using Beast v1.10.4 (Drummond & al. 2012). Data
for each gene or region was analyzed both individually and together as a combined data
set. jModeltest v.2.1.10 (Darriba & al. 2012) was used to determine the best nucleotide
substitution model for both studies. Congruence between individual gene data sets
was tested using the partition homogeneity test (Farris & al. 1995) implemented in
PAUP v4.0b10 (Swofford, 2001), using a heuristic search option with random taxon
addition and TBR branch swapping with 1000 replicates. Tree topologies from ML

504 ... Magdama & al.

analysis of individual genes were also compared visually for congruence. For the
combined ML study, GTR was specified as the evolutionary model with estimated
proportion of invariables sites and gamma distribution as default parameters.
Number of substitution rates was set to four and topology search changed to SPR
for tree improvement. Nodal support was assessed by bootstrap analysis from 1000
replicates. Bootstrap values equal or higher than 70% were considered significant.
Bayesian inference was run with four Monte Carlo Markov (MCM) chains over 1
million generations with a sampling frequency of 1000 trees using the GTR+I+G
as the best model (Drummond & al. 2012). To detect if the sample distribution has
reached stationarity, convergence and the effective sample size (ESS) were checked
for each run. Posterior probabilities (PP) for the Bayesian analysis were determined
by calculating 50% majority rule consensus tree and added onto congruent nodes of
the ML tree topology. PP equal or above 0.95 were considered significant. Relevant
sequences of ITS and LSU from Hernandez-Restrepo & al. (2016) obtained from
GenBank, were included in the phylogenetic inference for comparison purposes
(TABLE 1).

TABLE I. Sequences of Guayaquilia cubensis and related species used in the
phylogenetic analysis. New sequences are indicated in bold.

SPECIES STRAIN # ITS LSU REFERENCE
Astrocystis IT1612 KP297404 KP340545 Daranagama & al. 2015
concavispora
Castanediella acaciae CBS 139896 KR476728 KR476763 Crous & al. 2015
C. cagnizarii CBS 542.96 KP859054 KP858991 Hernandez-Restrepo &
al. 2016
CBS 101043 KP859051 KP858988 Hernandez-Restrepo &
al. 2016
C. couratarii CBS 579.71 KP859050 KP858987 Hernandez-Restrepo &
al. 2016
Guayaquilia cubensis MUCL 39017 KC775733 KC775708 Becerra-Hernandez &
al. 2016
CCMCIBE-H312 MH777025 MH777024 This Study
CCMCIBE-H320 MH777026 MH777023 This Study
Idriella lunata CBS 177.57 KP859043 KP858980 Hernandez-Restrepo &
al. 2016
CBS 204.56 KP859044 KP858981 Hernandez-Restrepo &
al. 2016
CBS 209.60 KP859045 KP858982 Hernandez-Restrepo &
al. 2016
CBS 736.74 KP859046 KP858983 Hernandez-Restrepo &
al. 2016
Idriellopsis CBS 575.92 KP859052 KP858989 Hernandez-Restrepo &
uncinospora al. 2016

Kretzschmaria deusta CBS 163.93 KC477237 KY610458 Wendt & al. 2018

Guayaquilia cubensis gen. & sp. nov. (Cuba, Ecuador) ... 505

Microdochium CBS 243.83 KP858994 KP858930 Hernandez-Restrepo &
albescens al. 2016
M. citrinidiscum CBS 109067 KP859003 KP858939 Hernandez-Restrepo &
al. 2016
M. lycopodinum CBS 109398 KP859005 KP858941 Hernandez-Restrepo &
al. 2016
M. majus CBS 741.79 KP859001 KP858937 Hernandez-Restrepo &
al. 2016
M. CBS 445.95 KP858997 KP858933 Hernandez-Restrepo &
neoqueenslandicum al. 2016
M. nivale CBS 116205 KP859008 KP858944 Hernandez-Restrepo &
al. 2016
M. seminicola CBS 122707 KP859007 KP858943 Hernandez-Restrepo &
al. 2016
Microdochium sorghi CBS 691.96 KP859000 KP858936 Hernandez-Restrepo &
al. 2016
M. tainanense CBS 269.76 KP859009 KP858945 Hernandez-Restrepo &
al. 2016
M. trichocladiopsis CBS 623 77 KP858998 KP858934 Hernandez-Restrepo &
al. 2016
Neoidriella CBS 985.72 KP859048 KP858985 Hernandez-Restrepo &
desertorum al. 2016
Paraidriella jambosae CBS 374.90 KP859049 KP858986 Hernandez-Restrepo &
al. 2016
Poronia punctata CBS:656.78 KT281904 KY610496 Wendt & al. 2018
Rosellinia aquila MUCL 51703 KY610392 KY610460 Wendt & al. 2018
R. corticium MUCL 51693 KY610393 KY610461 Wendt & al. 2018
R. necatrix CBS 349.36 AY909001 KF7 19204 Pelaez & al. 2008
Sarcoxylon CBS 359.61 KT281903 KY610462 Wendt & al. 2018
compunctum
Selenodriella cubensis CBS 683.96 KP859053 KP858990 Hernandez-Restrepo &
al. 2016
S. fertilis CBS 772.83 KP859055 KP858992 Hernandez-Restrepo &
al. 2016
Xylaria arbuscula CBS:126415 KY610394 KY610463 Fournier & al. 2011;
Wendt & al. 2018
X. hypoxylon CBS 122620 KY610407 KY610495 Wendt & al. 2018
X.polymorpha MUCL 49884 KY610408 KY610464 Wendt & al. 2018
Phylogeny

The LSU-ITS dataset comprised 36 aligned sequences with 1482 positions.
Fic. 1 presents the ML tree including BS and PP values. The partition
homogeneity test showed no significant incongruence between the combined
data sets (p >0.05). Trees obtained from ML and Bayesian analysis of the
individual loci and the combined analysis produced congruent topologies.

Phylogenetic inferences grouped the three strains identified as Idriella
cubensis (MUCL 39017, CCMCIBE-H312, CCMCIBE-H320) together in a

506 ... Magdama & al.

92/1 - Microdochium citrinidiscum CBS 109067
Microdochium sorghi CBS 691 96
100/17 Microdochium seminicola CBS 122707
Microdochium albescens CBS 243 83
76/1 Wl Microdochium tainanense CBS 269 76
Microdochium trichocladiopsis CBS 623 77

89/1] |400/17 Microdochium majus CBS 741 79

Microdochium nivale CBS 116205

Microdochium neoqueenslandicum CBS 445 95
Microdochium lycopodinum CBS 109398
100/1 | Selenodriella fertilis CBS 772 83
Selenodriella cubensis CBS 683 96
-/0.96 Idriella lunata CBS 736 74
100/1 |- !driella lunata CBS 209 60
Idriella lunata CBS 204 56
100/1! Idriella lunata CBS 177 57
Neoidriella desertorum CBS 985 72
“j0.96| Uayaquilia cubensis sp. nov. CCMCIBE-H312_
_ | Guayaquilia cubensis sp. nov. CCMCIBE-H320
Paraidriella jambosae CBS 374 90
Idriellopsis uncinospora CBS 575 92
Castanediella acaciae CBS 139896
Castanediella couratarii CBS 579 71
Castanediella cagnizarii CBS 542 96
99/1 Castanediella cagnizarii CBS 101043
“ft Sarcoxylon compunctum CBS 359 61
Poronia punctata CBS 656 78

86/1

-/t

-/t

100/1 Rosellinia corticium MUCL 51693
fi
J 96/0.98 Rosellinia aquila MUCL 51703
oe il Astrocystis concavispora IT1612
78/1 Rosellinia necatrix CBS 349 36
|i Xylaria polymorpha MUCL 49884
86/0.99 Xylaria hypoxylon CBS 122620
-/0.99 Kretzschmaria deusta CBS 163 93

Xylaria arbuscula KY610463

0.050

Fic. 1. Maximum Likelihood (ML) non-rooted tree inferred from the combined LSU and ITS
sequences of Guayaquilia cubensis and related species. Numbers on the branches are support values
>75% from BS and >0.95 from PP. The scale bar shows the expected changes per site.

supported clade and sister to Neoidriella desertorum, both clades separate from,
and basal to, the Microdochiaceae Hern.-Restr. & al. clade containing Idriella
lunata, Microdochium spp., and Selenodriella spp. We therefore propose a new
genus Guayaquilia typified by Idriella cubensis.

Taxonomy

Guayaquilia R.F. Castafieda, Magdama, D. Sosa & Hern.-Restr., gen. nov.
MB 831849

Differs from Neodriella and Paraidriella by its macronematous, tree-like, irregularly
multibranched conidiophores and its intercalary, discrete conidiogenous cells.

Guayaquilia cubensis gen. & sp. nov. (Cuba, Ecuador) ... 507

Type Species: Idriella cubensis R.F. Castahteda & G.R.W. Arnold [= Guayaquilia cubensis
(R.E Castafieda & G.R.W. Arnold) R.F. Castafeda & al.].

EryMo.Loey: Guayaquilia (Latin), referring to Guayaquil city, Ecuador.

ASEXUAL. COLONIES on natural substrate effuse, pulvinate-velutinous,
golden brown to brown. CONIDIOPHORES macronematous, mononematous,
fasciculate, erect, cylindrical, irregularly branched, septate, smooth, brown.
CONIDIOGENOUS CELLS polyblastic, denticulate, sympodial extended,
terminal or intercalary, cylindrical or slightly inflated, pale brown to
brown. Conidial secession schizolytic. Conip1a solitary, acropleurogenous,
sublunate, subnavicular, inequilateral, unicellular or septate, hyaline, smooth.
CHLAMYDOSPORES solitary, bicellular, brown and the apical cell globose, thick
walled, smooth.

Guayaquilia cubensis (R.F. Castafieda & G.R.W. Arnold) R.F. Castafieda, Magdama,

D. Sosa & Hern.-Restr., comb. nov. FIGS 2, 3

MB 831851
= Idriella cubensis R. F. Castaheda & G.R.W. Arnold, Rev.
Jard. Bot. Nac., Univ. Habana 6(1): 50 (1985).

COLONIES on V8 agar at 25°C attaining 60 mm diam after five days, floccose,
pale lavender grey to buff, sporulation poor, sparse. On CMA reaching
50 mm diam, felted, dark brick at the center, whitish toward the periphery.
CONIDIOPHORES macronematous, mononematous, tree-like, fasciculate,
profuse, dichotomously, alternately or irregularly branched toward the apex,
slightly inflated or bulbous at the base, smooth, brown below, pale brown to
subhyaline at the tip of branches, <500 um long, 4-7.5 um wide at the base,
branches 2-3.5 um wide. CONIDIOGENOUS CELLS polyblastic, denticulate,
intercalary and terminal, in branches integrated, cylindrical, or slightly
curved, brown to pale brown or subhyaline, 8-25 x 2-3 um. CONIDIA
solitary, acropleurogenous, sublunate, subnavicular, lunate, inequilateral, (0-)
l-septate, 14-17 x 2.5-3 um. CHLAMyDospoRESs bicellular, the basal cells
subcampanulate, subcuneiform to hemispherical, 5-8 um wide, and the apical
cells globose, 18-22 um diam, brown, thick walled; both cells with lumina
granulose, brown; terminal, smooth, arising from assimilative hyphae.

SPECIMENS EXAMINED: ECUADOR, Guayas PROVINCE, Naranjal, 2°48’S 79°40’W,
on decaying leaves of Theobroma cacao L. (Malvaceae), 8 July 2017, F. Espinoza & S.
Pérez-Martinez (URM 91815 = CCMCIBE-H312; GenBank MH777025, MH777024);
2°41’S 79°36’W, on decaying leaves of Theobroma cacao, 8 July 2017, F. Espinoza & S.
Pérez-Martinez (URM 91815a = CCMCIBE-H320; GenBank MH777026, MH777023).
CUBA, La HABANA PROVINCE, Santiago de Las Vegas, 22°58’N 82°22’W, on decaying
leaves of Calophyllum calaba L. (Clusiaceae), 29 Jun 1983, RF Castaneda Ruiz (holotype,

508 ... Magdama & al.

50pm

50 um

Fic. 2. Guayaquilia cubensis (holotype, INIFAT C83/57-1).
Conidiophores, conidiogenous cells, and conidia.

Guayaquilia cubensis gen. & sp. nov. (Cuba, Ecuador) ... 509

C, D. Conidiophores; E-G. Conidiogenous cells; H-L. Conidia; M, N, Chlamydospores. Scale
bars = 10 um.

INIFAT C83/57-1); PINAR DEL R10 PROVINCE, Los Portales, 22°40’N 83°28’W, on

decaying leaves of Cupania sp. (Sapindaceae), 5 Feb. 1994, RF Castafieda Ruiz, (INIFAT
C94/27 = MUCL 39017).

510 ... Magdama & al.

Note: Guayaquilia shares some morphological characters with the genera
Castanediella, Idriella, Idriellopsis, Neoidriella, and Paraidriella, such as blastic
conidial ontogeny and denticulate conidiogenous loci, but the tree-like,
dichotomously, alternately or irregularly profuse branched conidiophores with
intercalary and terminal conidiogenous cells are present only in Guayaquilia.
Also, the bicellular, globose, brown chlamydospores that arise from assimilative
hyphae in Guayaquilia are another distinctive character. The conidiophore
morphology in Guayaquilia resembles that of some Phaeodactylium species
(P. biseptatum, P. curvularioides, and P. stadleri) described by Castafeda-
Ruiz & al. (2009, 2013) and Matsushima (1980), but these taxa have clavate,
ellipsoidal, to obovoid, brown to subhyaline conidia.

Acknowledgments

We are indebted to Dr. Flavia Rodrigues Barbosa (Instituto de Ciéncias Naturais,
Humanas e Sociais, Universidade Federal de Mato Grosso, Brazil) and Dr. De-Wei Li
(The Connecticut Agricultural Experiment Station Valley Laboratory, USA) for their
critical reviews. The authors are grateful to Escuela Superior del Litoral (ESPOL),
CIBE for financial support and the International Society for Fungal Conservation for
facilities. RFCR is grateful to the Cuban Ministry of Agriculture. We acknowledge the
websites provided by Dr. P.M. Kirk (Index Fungorum) and Dr. K. Bensch (MycoBank).
Dr. Lorelei Norvell’s editorial review and Dr. Shaun Pennycook’s nomenclature review
are greatly appreciated.

Literature cited

Arx JA von. 1981. Notes on Microdochium and Idriella. Sydowia 34: 30-38.

Becerra-Hernandez CI, Gonzalez D, Luna ED, Mena-Portales J. 2016. First report of
pleoanamorphy in Gyrothrix verticiclada with an Idriella like synanamorph. Cryptogamie
Mycologie 37: 241-252 https://doi.org/10.7872/crym/v37.iss2.2016.241

Carmichael JW. 1955. Lacto-fuschsin: a new medium for mounting fungi. Mycologia 47: 611.

Castaneda-Ruiz RE 1985. Deuteromycotina de Cuba. Hyphomycetes, II. La Habana, 23 p.

Castafeda-Ruiz RE 1986. Fungi Cubenses. La Habana, 20 p

Castafeda-Ruiz RF, Arnold GRW. 1985. Deuteromycotina de Cuba. I. Hyphomycetes. Revista
del Jardin Botanico Nacional 6:47-67.

Castaneda RF, Kendrick B. 1991. Ninety-nine conidial fungi from Cuba and three from Canada.
University of Waterloo Biology Series 35: 1-132.

Castafieda RF, Guarro J, Cano J. 1997. Notes on conidial fungi. XII. New or interesting
hyphomycetes from Cuba. Mycotaxon 63: 169-181.

Castaneda Ruiz RE, Iturriaga T, Minter DW Heredia Abarca G, Stadler M, Saikawa M.;
Fernandez R. 2009. Two new anamorphic fungi and some microfungi recorded from
‘El Avila, Venezuela. Mycotaxon 107: 225-237. https://doi.org/10.5248/107.225

Castafeda-Ruiz RF, Hernandez-Restrepo M, Gené J, Guarro J, Minter DW, Saikawa M.
2012. Two new microfungi from Portugal: Magnohelicospora iberica gen. & sp. nov. and
Phaeodactylium stadleri sp. nov. Mycotaxon 121: 171-179. https://doi.org/10.5248/121.171

Guayaquilia cubensis gen. & sp. nov. (Cuba, Ecuador) ... 511

Castafieda-Ruiz RE, Heredia G, Gusmao LFP, Li DW. 2016. Fungal diversity of Central and
South America. 197-217, in: DW Li (ed.). Biology of Microfungi. Springer International
Publishing. https://doi.org/10.1007/978-3-319-29137-6_9

Cenis JL. 1992. Rapid extraction of fungal DNA for PCR amplification. Nucleic Acids Research
20: 2380. https://doi.org/10.1093/nar/20.9.2380

Crous PW, Wingfield MJ, Guarro J & al. 2015. Fungal Planet description sheets: 320-370.
Persoonia 34: 167-266. https://doi.org/10.3767/003158515X688433

Daranagama DA, Camporesi E, Liu X, Chamyuang S, Stadler M, Hyde KD. 2015. Anthostomella
is polyphyletic comprising several genera in Xylariaceae. Fungal Diversity 73: 203-238.
https://doi.org/10.1007/s13225-015-0329-6

Darriba D, Taboada GL, Doallo R, Posada D. 2012. jModelTest 2: more models, new heuristics
and parallel computing. Nature Methods 9: 772.

Drummond AJ, Suchard MA, Xie D, Rambaut A. 2012. Bayesian phylogenetics with
BEAUti and the BEAST 1.7. Molecular Biology and Evolution 29: 1969-1973.
http://doi.org/10.1093/molbev/mss075

Farris JS, Kallersjo M., Kluge AG, Bult C. 1995. Testing significance of incongruence. Cladistics
10: 315-319.

Fournier J, Flessa FE, Persoh D, Stadler M. 2011. Three new Xylaria species from southwestern
Europe. Mycological Progress 10:33-52. https://doi.org/10.1007/s11557-010-0671-8

Hernandez-Restrepo M, Groenewald JZ, Crous PW. 2016. Taxonomic and phylogenetic
re-evaluation of Microdochium, Monographella and Idriella. Persoonia 36: 57-82.
http://doi.org/10.3767/003158516X688676

Korabecna M. 2007. The variability in the fungal ribosomal DNA (ITS1, ITS2, and 5.8 S RRNA
Gene): Its biological meaning and application in medical mycology. Communicating
Current Research and Educational Topics and Trends in Applied Microbiology 108: 783-787.
https://doi.org/10.1128/JCM.39.10.3617

Matsushima T 1980. Saprophytic microfungi from Taiwan, part 1. Hyphomycetes. Matsushima
Mycological Memoirs.1. Matsushima Fungus Collection, Kobe

Matsushima, T. 1985. Matsushima Mycological Memoirs No. 4. Matsushima Fungus Collection
Kobe.

Matsushima, T. 1995. Matsushima Mycological Memoirs No. 8. Matsushima Fungus Collection,
Kobe.

Morgan-Jones G. 1979. Notes on hyphomycetes XXX. On three species of Idriella.
Mycotaxon 8(2): 402-410.

Nelson PE, Wilhelm S. 1956. An undescribed fungus causing a root rot of strawberry.
Mycologia 48: 547-551. https://doi.org/10.1080/00275514.1956.12024564

Pelaez FE, Gonzalez V, Platas G, Sanchez-Ballesteros J, Rubio V. 2008. Molecular phylogenetic
studies within the family Xylariaceae based on ribosomal DNA sequences. Fungal Diversity,
31: 111-134.

Rayner RW. 1970. A mycological colour chart. Kew, Surrey, UK.

Rodrigues KF, Samuels GJ. 1990. Preliminary study of endophytic fungi in tropical palm.
Mycological Research 94: 827-830. https://doi.org/10.1016/S0953-7562(09)81386-5

Rodrigues KF, Samuels GJ. 1992. Idriella species endophytic in palms. Mycotaxon 43: 271-276

Seifert K, Morgan-Jones G, Gams W, Kendrick B. 2011. The genera of hyphomycetes.
CBS Biodiversity Series 9. 997 p.

Subramanian CV, Bhat DJ. 1989 [1987]. Hyphomycetes from South India I. Some new taxa.
Kavaka 15: 41-74.

512 ... Magdama & al.

Swofford DL. 2001. PAUP*. Phylogenetic Analysis Using Parsimony (*and Other Methods).
Version 4 Ed. Sinauer Associates, Sunderland, MA, USA.

Vilgalys R, Hester M. 1990. Rapid genetic identification and mapping of enzymatically amplified
ribosomal DNA from several Cryptococcus species. Journal of Bacteriology 172: 4238-4246.
https://doi.org/10.1128/jb.172.8.4238-4246.1990

Wendt L, Sir EB, Kuhnert E, Heitkamper S, & al. 2018. Resurrection and emendation of the
Hypoxylaceae, recognized from a multigene phylogeny of the Xylariales. Mycological
Progress 17: 115-154 https://doi.org/ 10.1007/s11557-017-1311-3

White TJ, Bruns T, Lee S, Taylor J. 1990. Amplification and direct sequencing of fungal ribosomal
RNA genes for phylogenetics. In PCR Protocols, 315-322.
https://doi.org/10.1016/B978-0-12-372180-8.50042-1

Wu WB, Sutton BC, Gange AC. 1997. Notes on three fungicolous fungi: Anastomyces microsporus
gen. et sp. nov., Idriella rhododendri sp. nov. and Infundibura adhaerens. Mycological
Research 101: 1318-1322. https://doi-org/10.1017/S0953756297004097

Yang J, Liu JK, Hyde KD, Jones EBG, Liu ZY. 2017. Two new species in Fuscosporellaceae from
freshwater habitats in Thailand. Mycosphere 8: 1893-1903 Doi 10.5943/mycosphere/8/10/12.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 513-523
https://doi.org/10.5248/135.513

Distoseptispora longispora sp. nov.
from freshwater habitats in China

Hal-YAN SONG’, ALY FARAG EL SHEIKHA”?*>*, ZHI-JUN ZHADL,
JIAN-PING ZHOU’, MING-HuI CHEN’, GUANG-Hua Huo},
X1-GEN HuANG?®, Dian-MInG Hu”?

' Key Laboratory of Crop Physiology, Ecology and Genetic Breeding,
Ministry of Education of the P. R. China,
? Bioengineering and Technological Research Centre for Edible and Medicinal Fungi,
’ Jiangxi Key Laboratory for Conservation and Utilization of Fungal Resources, and
* College of Bioscience and Bioengineering,
™4 Jiangxi Agricultural University, 1101 Zhimin Road, Nanchang, Jiangxi 330045, China
° Department of Food Science and Technology, Minufiya University,
Shibin El Kom, Minufiya Government, Egypt

“ CORRESPONDENCE TO: * elsheikha_aly@yahoo.com
®=hxg208@163.com “hudianming1@163.com

ABSTRACT—A novel species, Distoseptispora longispora, from submerged wood in Yunnan
Province, China, is described and illustrated. The fungus is characterized by macronematous,
mononematous, septate conidiophores with monoblastic, integrated, determinate, terminal
conidiogenous cells that produce acrogenous, solitary, obclavate, elongated, distoseptate
conidia. SSU-ITS-LSU sequence analyses were used to infer the phylogenetic relationship
between D. longispora and related species. Both molecular analyses and morphological
data well support D. longispora as an independent taxon. A key to Distoseptispora species is
provided.

KEY worDs—Ascomycota, asexual fungi, Distoseptisporaceae, hyphomycetes

Introduction
Distoseptispora K.D. Hyde & al. was introduced by Su & al. (2016) to
accommodate two species, D. fluminicola McKenzie & al., the type species,

514 ... Song & al.

and D. aquatica Z.L. Luo & al. The genus is characterized by hairy colonies,
macronematous conidiophores, monoblastic conidiogenous cells, and
distoseptate acrogenous cylindrical conidia., Distoseptispora represents
a phylogenetically distinct lineage in Sordariomycetes for which Su & al.
(2016) proposed a new family, Distoseptisporaceae K.D. Hyde & McKenzie.
Subsequently, 13 more species have been added: D. cangshanensis Z.L. Luo
& al., D. dehongensis W. Dong & al., D. guttulata Jing Yang & K.D. Hyde,
D. martinii (J.L. Crane & Dumont) J.W. Xia & X.G. Zhang, D. obpyriformis
Z.L. Luo & H.Y. Su, D. palmarum S.N. Zhang & al., D. phangngaensis Jing Yang
& al., D. rostrata Z.L. Luo & al., D. submersa Z.L. Luo & al., D. suoluoensis Jing
Yang & al., D. thailandica Tibpromma & K.D. Hyde, D. thysanolaenae Goonas.
& al., and D. xishuangbannaensis Tibpromma & K.D. Hyde (Hyde & al. 2019,
Luo & al. 2018, Phookamsak & al. 2019, Tibpromma & al 2018, Xia & al. 2017,
Yang & al. 2018).

Many aquatic fungi have been discovered in China’s freshwater habitats,
which are rich in lignicolous fungi (Hu & al. 2007, 2012a,b; Huang & al. 2016;
Song & al. 2018). Our ongoing survey of aquatic fungi in Yunnan Province
revealed an interesting Distoseptispora species that we describe as new based on
morphological characters and molecular analyses (SSU-ITS-LSU).

Materials & methods

Sample collection & morphological studies

Debarked wood samples from different freshwater habitats in Yunnan Province,
China, were taken to the lab for detection of fungi using dissecting and compound
microscopes. The dried specimens were deposited in the Herbarium of Fungi, Jiangxi
Agricultural University, Nanchang, China (HFJAU).

DNA extraction, sequencing, and phylogenetic analyses
Genomic DNA was extracted from fresh fungal materials found on the natural
substrate following Hu & al. (2012c). We amplified three rDNA regions: internal

TABLE 1. Isolates included in the phylogenetic analyses.

GENBANK ACCESSION NUMBERS
SPECIES STRAIN

ITS LSU SSU
Distoseptispora “adscendens” HKUCC 10820 — DQ408561 —
D. aquatica MFLUCC 15-0374" NR_ 154040 KU376268 —
SNJ14 MH555360 — a
D. fluminicola MFLUCC 15-0417 =NR_154041 KU376270 —

D. guttulata MFLUCC 16-0183 MF077543 MF077554 MF077532

D. “leonensis”
D. longispora
D. martinii

D. multiseptata

D. phangngaensis

D. suoluoensis

D. tectonae

D. tectonigena
Distoseptispora sp.

Dothidea sambuci

Ellisembia bambusicola

E. calyptrata
E. minigelatinosa

Ellisembia sp.

Sporidesmium aquaticivaginatum

S. aquaticum

S. australiense

S. fluminicola

S. macrurum

S. obclavatulum

S. olivaceoconidium
S. pachyanthicola
S. parvum

S. pyriformatum

S. submersum
S. tengii
S. thailandense

S. tropicale

Sporidesmium sp.
Sporidesmium sp.

Sporidesmium sp.

Distoseptispora longispora sp. nov. (China) ... 515

HKUCC 10822
HFJAU 0705"
HSAUP myr4280
MFLUCC 15-0609"
MFLUCC 16-1044
MFLUCC 16-0857
MFLUCC 17-1305
MFLUCC 17-0224
MFLUCC 12-0291
GZ25
MFLUCC 12-0292

HLXM 15-1
AFTOL-ID 274
HKUCC 3578
HKUCC 10821
NN47497

HKUCC 10558
MFLUCC 15-0624
MFLUCC 15-0420
HKUCC 10833
MFLUCC 15-0346
HKUCC 2740
HKUCC 10834
MFLUCC 15-0380
HKUCC 10835
HKUCC 10836
MFLUCC 15-06207
MFLUCC 15-0627
MFLUCC 15-0421
HKUCC 10837
MFLUCC 15-0964"

MFLUCC 16-0185
HKUCC 10838
KUFA 0043

MFLUCC 15-0617

MFLUCC 16-0186

MH555359
KU999975

NR_154017
MF077544
MF077545

MF077547
MF077546
KX751711
MH555361
NR_154018

DQ491505

KX710147

KX710144

KX710146

KX710148

MF374361

MF077551

KT824799
MF077550

MF077549

DQ408566
MH555431
KX033566

KX710140
MF077555
MF077556

MF077558
MF077557
KX751713

KX751714
KU376269
AY544681

DQ408562
DQ408564
DQ408567
DQ408565
KX710142
KU376273
DQ408554
KU376271
DQ408555
DQ408556
KX710139

DQ408557
DQ408558
KX710141

KU376272
DQ408559
MF374370

MF077562
DQ408560

MF077561

MF077560

MH555357
KX033537

MF077540
MF077533
MF077534

MF077536
MF077535

MH555358

AY544722

MF077541

MF077542

KX710143

MF077539

MF077538

516 ... Song & al.

transcribed spacer (ITS) with the primer pair ITS1 & ITS4 (White & al. 1990),
partial small subunit (SSU) with NS1 & NS4 (White & al. 1990), and large subunit
(LSU) with LROR & LR6 (Vilgalys & Hester 1990, Rehner & Samuels 1995). PCR
protocols followed the conditions set by Hu & al. (2012b). The PCR products were
purified and sequenced by the same primers used for PCR at Sangon Biotech
(Shanghai) Co. Ltd.

In this study, we generated six novel sequences (MH555360, MH555359,
MH555431, MH555357, MH555361 & MH555358) and retrieved 36 reference
sequences from GenBank (TABLE 1) that were aligned using MAFFT v7.

The ML analyses were produced with RAxML v7.2.6 (Stamatakis & Alachiotis
2010) using a GTRGAMMA substitution model with 1000 bootstrap replicates and
evaluated by bootstrap support (MLBS).

The best-fit evolutionary models were estimated using MrModeltest V2.2.
Posterior probabilities (PP) (Zhaxybayeva & Gogarten 2002) were determined by
Markov chain Monte Carlo sampling (BMCMC) in MrBayes 3.0b4 (Huelsenbeck &
Ronquist 2001). Six simultaneous Markov chains were run 1,500,000 generations,
with trees sampled every 100 generations and the first 25% deleted as burn-
in. Posterior probabilities were calculated based on the remaining trees. The
novel taxonomic descriptions and nomenclature were deposited in MycoBank
(http://www.mycobank.org/).

Phylogenetic results

The six new sequences generated in our study included one LSU, two SSU,
and three ITS sequences. The phylogenetic tree based on the three-locus
analysis (Fic. 1) shows the relationship between the new taxon and other
related species. The concatenated aligned dataset comprised 17 isolates from
13 Distoseptispora spp., 23 isolates from 21 Sporidesmium (or “Ellisembia”)
spp., and one isolate of Dothidea sambuci (Pers.) Fr. (Dothideomycetes) as an
outgroup. The dataset including alignment gaps comprised 2817 characters:
1348 for SSU, 629 for ITS, and 840 for LSU. The combined dataset ML tree
(Fic. 1) with bootstrap support values (MLBS) and Bayesian posterior
probabilities (BPP) indicates several well-supported clades, with the
Distoseptispora longispora strain forming a well-supported clade (MLBS = 94%,
BPP = 0.68) with other Distoseptispora species.

Taxonomy
Distoseptispora longispora H.Y. Song & D.M. Hu sp. nov. Fic. 2
MB 826916

Differs from Distoseptispora aquatica by its larger and more septate conidia; and from
D. tectonae and D. tectonigena by its smooth and brown to yellowish brown conidia.

Distoseptispora longispora sp. nov. (China) ... 517

66/0.99 Distoseptispora tectonae MFLUCC 12-0291
60/0.98|! nistoseptispora tectonae GZ25

Distoseptispora tectonigena MFLUCC 12-0292?
Distoseptispora “adscendens” HKUCC 10820
79/0.96: Distoseptispora fluminicola MFLUCC 15-0417?
Distoseptispora aquatica SNJ14
abet Li Dinseviees basis MFLUCC 15-0374?
73/0.76| | Distoseptispora longispora HFJAU 0705t
v1 Distoseptispora sp. HLXM 15-1
65/0.68 Distoseptispora multiseptata MFLUCC 15-0609T
Distoseptispora multiseptata MFLUCC 16-1044
98/0.67 Distoseptispora phangngaensis MFLUCC 16-0857
Distoseptispora martinii HSAUP myr4280
Distoseptispora guttulataMFLUCC 16-0183
94/0.68] | 100/1)Distoseptispora suoluoensis MFLUCC 17-0224
Distoseptispora suoluoensis MFLUCC 17-1305

63/-

PONS Distoseptispora “leonensis” HKUCC 10822
100/1 >- Sporidesmium olivaceoconidium MFLU! oC
Sporidesmium aquaticivaginatum MI FLUCC
99/0.94 Sporidesmium pyrif
100/1 iE 1! 'Sporidesmium pyriformat,
100/1
93/0.73 ‘Sporidesmiine a c
100/0.85 96/1 =
Sl Sporidesmium sp. MFLUCC 15-0
100/1 Sporidesmium thailandense MFLU
87/0.94, Sporidesmium submersum MFLU u

/0. Ellisembia minigelatinosa NN47497
7
100/0.93 99/0. Br ON zitisembia bambusicola HKUCC 3578
Ellisembia sp. HKUCC 10558
S Sporidesmium aquaticum MFLUCC 15-0420
100/1/ Sporidesmium tropicale HKUCC 10838

100/0.99 Sporidesmium tropicale MFLUCC 16-0185
64/0.8. Sporidesmium macrurum HKUCC 2740
100/1 Sporidesmium sp. MFLUCC 16-0186
-/67 Ellisembia calyptrata HKUCC 10821

Sporidesmium sp. KUFA 0043
99/1 Sporidesmium tengii HKUCC 10837
100/1 Sporidesmium australiense HKUCC 10833
Sporidesmium obclavatulum HKUCC 10834
Sporidesmium pachyanthicola HKUCC 10835
Dothidea sambuci AFTOL-ID 274
0.1

Fic. 1. Maximum Likelihood (ML) phylogenetic tree of Distoseptispora longispora and allied
species based on concatenated SSU-ITS-LSU data. The RAxML bootstrap support values
(MLBS) and Bayesian posterior probabilities (BPP) are given at the nodes (MLBS/BPP).

Type: China, Yunnan Province: Mengla, a small stream, on submerged wood, 13 Apr
2017, H.Y. Song (Holotype, HFJAU 0705).

EtyMo.oey: longispora, referring to the long conidia of the fungus.

COLONIES on submerged wood superficial, effuse, scattered, hairy, brown to
dark brown. Mycelium mostly immersed, composed of branched, septate,
smooth, subhyaline to pale brown hyphae. CONIDIOPHORES macronematous,
mononematous, 2-4-septate, unbranched, single, straight or slightly
flexuous, erect, cylindrical, smooth, brown to dark brown, 17-37 x 6-10 um.
CONIDIOGENOUS CELLS monoblastic, integrated, determinate, terminal, light
brown to dark brown, cylindrical. Conidial secession schizolytic. CoNIDIA
acrogenous, solitary, dry, obclavate, elongated, straight or slightly curved,
rounded at the apex, truncate at the base, 31—56-distoseptate, smooth, brown

518 ... Song & al.

to yellowish brown, slightly paler towards the apex, 189-297 x 16-23 um
(mean = 204 x 21 um, n= 50).

ADDITIONAL SPECIMEN EXAMINED: CHINA, YUNNAN PROVINCE, Mengla, a small

stream, on submerged wood, 13 Apr 2017, H.Y. Song (HFJAU 0706).
Notes: Distoseptispora longispora is characterized by its macronematous,
mononematous, septate conidiophores, monoblastic, integrated, determinate,
terminal conidiogenous cells, and acrogenous, solitary, dry, obclavate,
elongated, distoseptate conidia, which fit well with the generic concepts of
Distoseptispora (Su & al. 2016). The molecular phylogeny (Fic. 1) clusters the
D. longispora strain well within the Distoseptispora clade and closely related
to D. aquatica but with an ITS six base pair (bp) difference separating it
from D. aquatica (MFLUCC 15-0374). Distoseptispora longispora resembles
D. aquatica, D. tectonae, and D. tectonigena in conidial shape. However, its
larger and more septate conidia separate D. longispora from D. aquatica
(189-297 x 16-23 um; 15-28 septa). In addition, D. tectonae has verruculose,
dark reddish conidia, and D. tectonigena has dark reddish-brown conidia
(Hyde & al. 2016).

The multilocus molecular phylogeny and morphological data fully support
separation of our new species, D. longispora. Morphologically, Distoseptispora
resembles Ellisembia Subram., first established to accommodate the species
with distoseptate conidia in Sporidesmium Link (Subramanian 1992).
However, a molecular phylogeny by Shenoy & al. (2006) showed that Ellisembia
and Sporidesmium were polyphyletic. Su & al. (2016) later clarified differences
between Ellisembia and Sporidesmium, noting that euseptate/distoseptate
characters were not supported by molecular evidence and treating Ellisembia
as a synonym of Sporidesmium. Distoseptispora species differ from Ellisembia
(Sporidesmium) species in having relatively short conidiophores and darker
conidia with slightly paler, but not hyaline, rounded apices, basal cells cut off
by cross walls, and of indeterminate length (Su & al. 2016).

There are various hyphomycetes in freshwater habitats, and several studies
have reported Distoseptispora species, e.g., D. aquatica, D. fluminicola,
D. guttulata, D. multiseptata, D. phangngaensis, and D. suoluoensis (Hu &
al. 2007, 2010a,b; Huang & al. 2018; Hyde & al. 2016; Su & al. 2016; Yang
& al. 2018). Most of these species were identified based on morphology,
which proved to be insufficient for accurate identification (Hu & al. 2017).
Numerous other studies (Réblova & al. 2016, Su & al. 2016, Zhang & al. 2017)
have revealed many different freshwater lineages using molecular analyses.

Distoseptispora longispora sp. nov. (China) ... 519

d b

Fic. 2. Distoseptispora longispora (holotype, HFJAU 0705). a. Colonies on submerged wood;
b, c. Conidia; d. Conidiophore. Scale bars: a = 100 um, b-d = 5 um.

520 ... Song & al.

Key to Distoseptispora species

1. Conidia muriform, having both longitudinal and transverse septa ...... D. martinii
b-@oniciawathy Only transverse septa: 4) ef aia n he Seed ert bs ae natok Sue hes 2
PAC OMIA CUSe Plate .cA Ars Hs AMS sR tee ode gt AE Tee ppc i oan: ood aPag ET NR OVS CP 3
2 COniatacdistosep tate. 7. Reed oe AR ER Ne He see hy wasn aeale pS Ree ea 4
3. Conidia 75-130 x 7-11 um, 11-14(-20)-euseptate, smooth ........... D. guttulata
3. Conidia 80-125 x 8-13 um, 8-10-euseptate, verrucose............. D. suoluoensis
4, Conidiogenous cells polyblastic, conidia 35-180 x 7-ll um ......... D. palmarum
4. Conidiogenous:cellsimonoblastic «5, ose ages axis sean nied omens Panaee ken 5
5. Conidiophores having percurrently proliferating conidiogenous

cellsatthe apex Or comidiophoress:,. <. eactcmtics aha sate Ke sent teen sede oP Seek 6
5 Conidiophores Ot AG ADOVE Bi sts remiaginw Hits te aca hbo aaitess ertticen peta Sabghomem ae 7
6; Conidial PaaS 5 8 Orr pas An. Se, Scene ae tl Rd, Bre mle AN al D. rostrata
Gs ConidianAs 22 51 az ties sea tetiaeale Sat wants. eee D. tectonigena
7 @onidiaverruculoses7..5=9:5-X SiS SYM 25s eens eke aod ete alae os D. tectonae
Fe LOT Cia NOt eTTUCULOSE Pic etn)... Aas 5) ARN oe Sng. cats stata tar Ate so IRB. 8
8. Conidia 3-5-distoseptate, 17-30 x 7.5-10 um................004. D. dehongensis
8. Gonidia with more-than-6. distosepta: «oe. .5 da.04 wedeae vee ee ae cea 9
9. Saprobic on submerged wood in freshwater habitats ...................0000-% 12
9. Not saprobic on submerged wood in freshwater habitats...................-. 10
10. Saprobic on dead culms of Thysanolaena maxima,

conidia 8-14-distoseptate, 21.5-80 x 6.5-12.8 um ........... D. thysanolaenae
10Saprobic-on-deadsleaves*ot Pandanussp. bchie aiuto ag ths to ethuseen nore hoh wht ie 11
11. Conidia reddish brown to brown, 130-230 x 13.5-17 um ......... D. thailandica
11. Conidia green-brown to brown, 160-305 x 8-15 um...... D. xishuangbannaensis
12. Conidia 9-11-distoseptate, 53-71 x 12-16um .................. D. obpyriformis
12. Comidia with-morediant 12 aistos ep ta gets ssi cists sis ae todays aloe fel tte tess 13
13. Conidiogenous cells yellow, conidia 125-250 x 13-15 um ......... D. fluminicola
13¥Gonidiogenous cells: brownish: 22.0202 42-02-50u nessa ee Qo ueeee ee ou eeeeeees 14
14. Conidia brown to yellowish brown, 31-56-distoseptate,

1B oe Pde eo Ad CePA on Ae Roa ee a ai D. longispora
14. Conidia greenish brown or dark olivaceous green ............. 0.0 c cece eee 15
15. Conidiogenous cells subhyaline to pale brown,

conidia 58=1665¢ 10-14 yiml e255 toe tsa pee, Pee ed ee D. cangshanensis
15. Conidiogenous cells brown to dark brown ............ 0.00. eee eee eee eee 16

16. Conidiogenous cells dark brown to olivaceous,
conidia 110-157" 13:5.51:625 im" * 4 254 ak. 7 5 eis ef eal D. aquatica
16.-Gonidiogenious cells brown oo... 4h oi. gee eee ete a ede te deen ce dae 17

Distoseptispora longispora sp. nov. (China) ... 521

17. Conidia dark olivaceous green, multi-distoseptate,
99 = 29096 TP ONE em ae ERS Sin Ss ike ced eS ad D. multiseptata
17. Conidia dark or mid olivaceous to mid or dark brown ...................04- 18

18. Conidia dark olivaceous to mid or dark brown,
16553507% 14 S19 spirrn Vaan ae VR Brn tae eNe Bote Ee, ese ae D. phangngaensis
18. Conidia mid-olivaceous to brown, 95-123 x15-19 um .............. D. submersa

Acknowledgments

The authors express their sincere gratitude to Dr. Rafael EF Castafieda-Ruiz
(Alejandro de Humboldt—INIFAT, Havana, Cuba) and Dr. Jian Ma (College of
Agronomy, Jiangxi Agricultural University, Nanchang, China) for their critical
review of the manuscript, to Dr. Shaun Pennycook for nomenclatural review, and
to Dr. Lorelei L. Norvell for editorial review. Funds for research were provided
by the National Natural Science Foundation of China (NSFC 32070023), the Key
Projects of Youth Fund of Jiangxi Science and Technology Department of China
(20192ACBL21017), Natural Science Foundation of Education Department of
Jiangxi Province of China (GJJ190168).

Literature cited

Huang J-E, Song H-Y, Huang X-G, Ma J, Hu D-M. 2018. Phaeomonilia aquatica sp. nov., an
aquatic hyphomycete from China. Mycotaxon 132:919-923. https://doi.org/10.5248/132.919

Huelsenbeck JP, Ronquist FR. 2001. MrBayes: Bayesian inference of phylogenetic trees.
Biometrics 17: 754-755. https://doi.org/10.109

Hu DM, Zhu H, Cai L, Hyde KD, Zhang KQ. 2007. Sirothecium triseriale, a new chirosporous
anamorphic species from China. Cryptogamie, Mycologie 28: 311-314.

Hu DM, Cai L Chen H, Bahkali AH, Hyde KD. 2010a. Four new freshwater fungi associated
with submerged wood from Southwest Asia. Sydowia 62: 191-203.

Hu DM, Cai L Chen H, Bahkali AH, Hyde KD. 2010b. Fungal diversity on submerged wood
in a tropical stream and an artificial lake. Biodiversity and Conservation 19: 3799-3808.
https://doi.org/10.1007/s10531-010-9927-5

Hu DM, Cai L, Bahkali AH, Hyde KD. 2012a. Two new freshwater species of Annulatascaceae
from China. Mycotaxon 120: 81-88. https://doi.org/10.5248/120.81

Hu DM, Cai L, Hyde KD. 2012b. Three new ascomycetes from freshwater in China. Mycologia
104: 1478-1489. https://doi.org/10.3852/11-430

Hu DM, Chen H, Cai L, Bahkali AH, Hyde KD. 2012c. Aquapeziza: a new genus from
freshwater, and its morphological and phylogenetic relationships to Pezizaceae. Mycologia
104: 540-546. https://doi.org/10.3852/11-123

Hu DM, Wang M, Cai L. 2017. Phylogenetic assessment and taxonomic revision of Mariannaea.
Mycological Progress 16: 271-283. https://doi.org/10.1007/s11557-016-1252-2

Huang J-E, Song H-Y, Ma J, Guan G-X, Hu D-M. 2016. Xylohyphopsis aquatica sp. nov., a new
aquatic hyphomycete from China. Mycotaxon 131: 391-394.
https://doi.org/10.5248/131.3913/bioinformatics/17.8.754

Hyde KD, Hongsanan S, Jeewon R & al. 2016. Fungal diversity notes 367-490: taxonomic
and phylogenetic contributions to fungal taxa. Fungal Diversity 80: 1-270.
https://doi.org/10.1007/s13225-016-0373-x

522 ... Song &al.

Hyde KD, Tennakoon DS, Jeewon R & al. 2019. Fungal diversity notes 1036-1150: taxonomic
and phylogenetic contributions on genera and species of fungal taxa. Fungal Diversity, 96:
1-242. https://doi.org/10.1007/s13225-019-00429-2

Katoh K, Standley DM. 2013. MAFFT multiple sequence alignment software version 7:
improvements in performance and usability. Molecular Biology and Evolution 30: 772-780.
https://doi.org/10.1093/molbev/mst010

Luo Z-L, Hyde KD, Bhat DJ, Jeewon R, Maharachchikumbura SSN, Bao D-F & al. 2018.
Morphological and molecular taxonomy of novel species Pleurotheciaceae from freshwater
habitats in Yunnan, China. Mycological Progress 17(5): 511-530.
https://doi.org/10.1007/s11557-018-1377-6

Phookamsak R, Hyde KD, Jeewon R & al. 2019. Fungal diversity notes 929-1035: taxonomic
and phylogenetic contributions on genera and species of fungi. Fungal Diversity 95:
1-273. https://doi.org/10.1007/s13225-019-00421-w

Réblova M, Fournier J, Stépdnek V. 2016. Two new lineages of aquatic ascomycetes:
Atractospora gen. nov. and Rubellisphaeria gen. et sp. nov. and a_ sexual
morph of Myrmecridium montsegurinum sp. nov. Mycological Progress 15: 21.
https://doi-org/10.1007/s11557-016-1166-z

Rehner SA, Samuels GJ. 1995. Molecular systematics of the Hypocreales: a teleomorph gene
phylogeny and the status of their anamorphs. Canadian Journal of Botany 73: 816-823.
https://doi.org/10.1139/b95-327

Shenoy BD, Jeewon R, Wu WP, Bhat DJ, Hyde KD. 2006. Ribosomal and RPB2 DNA sequence
analyses suggest that Sporidesmium and morphologically similar genera are polyphyletic.
Mycological Research 110: 916-928. https://doi.org/10.1016/j.mycres.2006.06.004

Song HY, Zhong PA, Liao JL, Wang ZH, Hu DM, Huang YJ. 2018. Junewangia aquatica
(Junewangiaceae), a new species from freshwater habitats in China. Phytotaxa 336:
272-278. https://doi.org/10.11646/phytotaxa.336.3.5

Stamatakis A, Alachiotis N. 2010. Time and memory efficient likelihood-based tree
searches on phylogenomic alignments with missing data. Bioinformatics 26: i132-i139.
https://doi.org/10.1093/bioinformatics/btq205

Su H, Hyde KD, Maharachchikumbura SSN, Ariyawansa HA, Luo Z & al. 2016. The families
Distoseptisporaceae fam. nov., Kirschsteiniotheliaceae, Sporormiaceae and Torulaceae, with
new species from freshwater in Yunnan Province, China. Fungal Diversity 80: 375-409.
https://doi.org/10.1007/s13225-016-0362-0

Subramanian C. 1992. A reassessment of Sporidesmium (Hyphomycetes) and some related taxa.
Proceedings of the National Academy of Sciences, India, Section B: Biological Sciences 58:
179-190.

Tibpromma S, Hyde KD, McKenzie EHC & al. 2018. Fungal diversity notes 840-928: micro-
fungi associated with Pandanaceae. Fungal Diversity 93: 1-160.
https://doi.org/10.1007/s13225-018-0408-6

Vilgalys R, Hester M. 1990. Rapid genetic identification and mapping of enzymatically amplified
ribosomal DNA from several Cryptococcus species. Journal of Bacteriology 172: 4238-4246.
https://doi.org/10.1128/jb.172.8.4238-4246.1990

White TJ, Bruns T, Lee S, Taylor JW. 1990. Amplification and direct sequencing of
fungal ribosomal RNA genes for phylogenetics. 315-322, in: MA Innis & al. (eds).
PCR Protocols: a Guide to Methods and Applications. San Diego, Academic Press.
https://doi.org/10.1016/B978-0-12-372180-8.50042-1

Distoseptispora longispora sp. nov. (China) ... 523

Xia JW, Ma YR, Li Z, Zhang XG. 2017. Acrodictys-like wood decay fungi from southern China,
with two new families Acrodictyaceae and Junewangiaceae. Scientific Reports 7: 7888.
https://doi.org/10.1038/s41598-017-08318-x

Yang J, Maharachchikumbura SSN, Liu J-K, Hyde KD, Jones EBG, Al-Sadi AM, Liu Z-Y.
2018. Pseudostanjehughesia aquitropica gen. et sp. nov. and Sporidesmium sensu lato
species from freshwater habitats. Mycological Progress 17: 591-616.
https://doi.org/10.1007/s11557-017-1339-4

Zhang H, Dong W, Hyde KD, Maharachchikumbura SS, Hongsanan S, Bhat DJ, Al-Sadi
AM, Zhang D. 2017. Towards a natural classification of Annulatascaceae-like taxa:
introducing Atractosporales ord. nov. and six new families. Fungal Diversity 85: 75-110.
https://doi.org/10.1007/s13225-017-0387-z

Zhaxybayeva O, Gogarten JP. 2002. Bootstrap, Bayesian probability and maximum likelihood
mapping: exploring new tools for comparative genome analyses. BMC Genomics 3: 4.
https://doi.org/10.1186/1471-2164-3-4

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 525-534
https://doi.org/10.5248/135.525

Notes on rust fungi in China 9. Puccinia miscanthi
life cycle and morphology confirmed by inoculation

JING-XIN J’*, ZHUANG LY’, Yu Lt, MAKOTO KAKISHIMA??®

‘Engineering Research Center of Chinese Ministry of Education for Edible & Medicinal Fungi,
Jilin Agricultural University, Changchun, Jilin 130118, China

College of Plant Protection, Shandong Agricultural University, Taian 271000, China

>University of Tsukuba, Tsukuba, Ibaraki 305-8572, Japan

* CORRESPONDENCE TO: * 1096314395@qq.com * kakishima.makoto.ga@u.tsukuba.ac.jp

ABSTRACT— The Heteroecious and macrocyclic life cycle of Puccinia miscanthi is confirmed
for the first time with inoculation experiments in China. The rust produces spermogonial and
aecial stages on Plantago asiatica and uredinial and telial stages on Miscanthus sacchariflorus.
Morphological characters of these stages are described based on field collections and
specimens that confirmed their life cycle connections. The neotype of P miscanthi is
designated.

Key worps—Plantaginaceae, plant disease, Poaceae, Pucciniales, Uredinales

Introduction

Puccinia miscanthi was first described with uredinial and telial stages on
Miscanthus sacchariflorus (Poaceae) collected in northeastern China (Miura
1928). The life cycle of P. miscanthi was reported in Japan by Hiratsuka (1933),
Ito (1934), and Asuyama (1936) under the name of P. eulaliae Barclay. These
authors demonstrated life cycle connection between spermogonial and aecial
stages on Plantago asiatica (Plantaginaceae) and uredinial and telial stages on
M. sinensis Andersson through inoculations. Ito (1950) considered the rust
fungus as producing spermogonial and aecial stages on Plantago and uredinial
and telial stages on Miscanthus and Imperata (as P. eulaliae) and treated
P. miscanthi as a synonym of this species. Later, however, this rust fungus

526 ... Ji & al.

was considered to represent a species different from P. eulaliae because of
morphology and host relations, and it was treated as P. miscanthi (Cummins
1971, Hiratsuka & al. 1992). Sato & Kakishima (1982) reported Lysimachia
clethroides Duby (Primulaceae) as an additional host of the rust’s spermogonial
and aecial stages. This rust fungus has been reported on wide range of host
plants from northeastern Asia (TABLE 1, p. 532).

During investigation of rust fungi in northeastern China, a Puccinia species
producing uredinial and telial stages on M. sacchariflorus was collected in
Heilongjiang Province. Spermogonial and aecial stages of a rust fungus on
Plantago asiatica were also found near infected M. sacchariflorus plants. The
spermogonial and aecial stages were suspected to represent different stages
of Puccinia miscanthi. However, life cycle connection of P miscanthi between
different host plants has not been clarified in China, although PI. asiatica,
Pl. depressa Willd., and Pl. major L. have all been listed as spermogonial
and aecial host plants, and M. floridulus (Labill.) K. Schum. & Lauterb.,
M. sacchariflorus, M. sinensis, Saccharum spontaneum L., and Thysanolaena
maxima (Roxb.) Kuntze as uredinial and telial hosts (Wang & Zhuang 1998,
Cao & Li 1999). Furthermore, Puccinia cynodontis Lacroix ex Desm. also
has been reported to produce spermogonia and aecia on Plantago species
including Pl. asiatica (Cummins 1971, Wang & Zhuang 1998). Worldwide,
uredinial and telial stages of six morphologically similar Puccinia species
have been recorded on Miscanthus (TABLE 1; Cummins 1971, Hiratsuka &
al. 1992, Wang & Zhuang 1998). Among them, P. miscanthi, P. miscanthicola
EL. Tai & C.C. Cheo, P. melanocephala Syd. & P. Syd., and P. erythropus Dietel
have been recorded in China (Tai 1979, Wang & Zhuang 1998). Therefore,
we carried out inoculation experiments to clarify the life cycle connection
between spermogonia and aecia on PI. asiatica and uredinia and telia on
M. sacchariflorus collected in Heilongjiang Province on 2 July 2018. We also
observed morphology of these specimens for identification of species.

Materials & methods

Inoculation experiments

On 2 July 2018 uredinia and telia on Miscanthus sacchariflorus were found at
Wuchang, Heilongjiang Province, China (44°12’22”N 128°03’33”E). Infected plants
were transplanted in plastic pots and placed on the ground at the campus of Jilin
Agricultural University, Changchun, Jilin Province. In late summer, abundant telia
appeared on the plants, and these telia were overwintered on dead leaves. Teliospores
obtained from the telia were observed to germinate and basidiospores produced in
the spring of 2019 were used for inoculations. On 17 June 2019 small pieces of leaves

Puccinia miscanthi life cycle (China) ... 527

- P
XG)

Le
=

te!

Fic. 1. Puccinia miscanthi on Plantago asiatica (A, C, E) and Miscanthus sacchariflorus (B, D, F).
A. The plants in plastic pots, producing spermogonia and aecia by basidiospore inoculation.
B. Plant transplanted from Heilongjiang Province and cultured at campus of Jilin Agricultural
University. C. Spermogonia produced on leaf surface by basidiospore inoculation. D. Brown
uredinia produced on leaf surface by aeciospore inoculation. E. Aecia on lower leaf surface
produced by basidiospore inoculation. F. Dark brown telia on leaf.

with teliospores were attached to the surfaces of young healthy leaves of Pl. asiatica
for inoculation, using a similar method previously reported by Ji & al. (2017a,b).
The inoculated plants were collected at campus of Jilin Agricultural University and
had been maintained in plastic pots. No natural infection of the field plants had

528 ... Ji&al.

been confirmed prior to inoculation. The inoculated plants were kept in a humid
environment in a plastic box in darkness at 20-23 °C for 3 days and then transferred
to a place near windows at 20-23 °C for observation.

Aeciospores obtained from aecia on the basidiospore-inoculated Plantago asiatica
leaves were dusted onto small pieces of wet filter paper (about 3 mm?’) in a Petri dish.
These papers were then placed on young healthy leaves of M. sacchariflorus, which
had been transplanted from Wuchang, Heilongjiang Province in 2018 and maintained
in plastic pots at campus of Jilin Agricultural University. Plants with new leaves were
used for the inoculation. The inoculated plants were kept in a humid environment in
a plastic box under the same conditions as the basidiospore inoculations, and later
transferred to the place near windows.

Morphological observations

Specimens collected at Wuchang, and specimens obtained by inoculations were
morphologically examined. The spores and size and shape of sori were microscopically
examined using Light (LM) and scanning electron (SEM) microscopes according
to Ji & al. (2019). The specimens are deposited in the Herbarium of Mycology,
Engineering Research Center of Chinese Ministry of Education for Edible and
Medicinal Fungi, Jilin Agricultural University, Changchun, China (HMJAU).

Results & discussion

Life cycle

About 10 days after inoculation of Plantago asiatica with basidiospores from
germinating teliospores, small yellow spots of spermogonia appeared on both
surfaces of the inoculated leaves (Fics 1A, C). These spots were frequently
observed on the leaf, and the leaf tissue around infected veins was sometimes
malformed when many spots were produced. About 10 to 12 days later, orange-
yellow aecia were produced around the spots on lower surfaces of the leaves
(Fic. 1E).

About 5 days after aeciospore inoculation, pale yellow spots appeared on
the leaves of Miscanthus. sacchariflorus, after which then brown uredinia were
produced (Fic. 1D). One to two months after that, blackish telia appeared on
M. sacchariflorus (Fic. 1F). The inoculation results confirmed that the rust
fungus producing spermogonial and aecial stages on PI. asiatica was conspecific
with the rust fungus producing uredinial and telial stages on M. sacchariflorus.

Morphology & identification

Theinoculations show that this rust fungus has an heteromacrocycliclife cycle,
producing spermogonia and aecia on Plantago asiatica and uredinia and telia
on Micanthus sacchariflorus. The uredinial and telial stages of our Heilongjiang
Province rust on M. sacchariflorus are morphologically similar to those of

Puccinia miscanthi life cycle (China) ... 529

ore

seed fl
—-

Fic. 2. Puccinia miscanthi on Plantago asiatica (HMJAU8642: A, B, D) and Miscanthus sacchariflorus
(neotype, HMJAU8643: C, E, FE, G) observed by LM. A. Vertical section of spermogonium (type 4).
B. Aeciospores with verrucose surface. C. Urediniospores with equatorial germ pores. D. Vertical
section of aecium with catenulate aeciospores surrounded by peridium. E. Vertical section of
uredinium mixed with paraphyses. F. Teliospores. G. Vertical section of telia, surrounded by host
epidermis. Scale bars: A, C = 30 um; B, E = 20 um; D = 100 um; F G = 25 um.

Puccinia erythropus, P. melanocephala, and P. miscanthi in urediniospore and
teliospore shapes. However, teliospores of P. erythropus and P. melanocephala

530 ... Ji&al.

are shorter, and their apical walls thinner, than those of our M. sacchariflorus
rust fungus (TABLE 1). Furthermore, although Ito (1950) described paraphyses
(TABLE 1), P. erythropus has been reported to have no paraphysis in uredinia,
whereas, our M. sacchariflorus rust fungus produces abundant paraphyses (Fics
2E, 3D). The morphological characters of our M. sacchariflorus rust fungus are
very close to those previously reported for P miscanthi, but as its teliospores are
only slightly shorter than these descriptions (TABLE 1), we identified our rust
fungus as P. miscanthi. Host range and morphological features of P. miscanthi
reported by different authors as shown in TABLE 1; the differences may be
considered variations within species caused by host plants and geographical
distribution. Puccinia miscanthi has been reported to be genetically very close
to P melanocephala although they are morphologically different (Virtudazo
& al. 2001, Dixon & al. 2010). Phylogenetic analyses with specimens from
different regions and host plants may clarify their relationships.

Spermogonial and aecial stages of Puccinia miscanthi have been reported to
be produced on Plantago and Lysimachia species (Cummins 1971, Hiratsuka
& al. 1992, Wang & Zhuang 1998). However, no confirmation of these stages
of P. miscanthi has been reported in China, although its life cycle connection
was reported in Japan with inoculations. Therefore, Pl. asiatica is the first
host plant confirmed by inoculations of its spermogonial and aecial stages in
China. The morphology of these stages is almost identical with the descriptions
reported from Japan by Ito (1950), Sato & Kakishima (1982), and Hiratsuka &
al. (1992), except for the slightly smaller aeciospores. Wang & Zhuang (1998)
described the rust’s spermogonial and aecial stages on Pl. depressa in China;
however, a connection to its uredinial and telial stages was not confirmed.
Two Plantago species, Pl. asiatica and Pl. lanceolata L., were also reported as
spermogonial and aecial host plants of P. cynodontis without confirmation of
their life cycle connections in China (Wang & Zhuang 1998). Therefore, rust
species identifications of spermogonial and aecial stages on species of Plantago
should be reconsidered. Ono & Azbukina (1997) reported that P. erythropus,
morphologically similar to P miscanthi, produced spermogonia and aecia
on Cynanchum sublanceolatum var. obtusum (Franch. & Sav.) Matsum.
(Apocynaceae), suggesting that this species differs from P miscanthi in its
spermogonial and aecial hosts.

Miura (1928) described Puccinia miscanthi based on a specimen on
Miscanthus sacchariflorus collected in Teikaton, Manchuria (northeast China)
on 22 September in 1919. However, this specimen has not been found in any
herbarium, we therefore designate a neotype. We collected specimens on the

Puccinia miscanthi life cycle (China) ... 531

Fic. 3. Puccinia miscanthi on Plantago asiatica (HMJAU8642: A, B) and Miscanthus sacchariflorus
(neotype, HMJAU8643: C, D) observed by SEM. A. Aeciospores with densely verrucose surface.
B. Aecium with peridium. C. Urediniospore with echinulate surface. D. Uredinium mixed with
paraphyses. Scale bars: A, C = 5 um; B = 40 um; D = 30 um.

same host plant from the same area of China, as reported by Miura (1928) and
used for inoculations. We believe that specimens collected and obtained from
inoculations are morphologically close to the original specimen and describe
its morphology based on these specimens.

Puccinia miscanthi Miura,
Fl. Manch. E. Mong., III Cryptogams, Fungi: 302, 1928. Figs 1-3

Type: Uredinia and telia on Miscanthus sacchariflorus (Maxim.) Franch. (Poaceae),
China, Helongjiang Province, Wuchang, 9 September 2017, leg. M. Kakishima & J-X. Ji
(neotype designated here, HMJAU8643; MBT388544).

Spermogonia amphigenous, surrounded by greenish yellow lesions,
densely grouped, yellow, subepidermal, flask-shaped, type 4 of Cummins
& Hiratsuka (2003). Aecia hypophyllous, densely grouped, yellow, cupulate
with peridia, Aecidium-type. Aeciospores catenulate, globose to subglobose,

Ji & al.

2h.

uoT}dIIOsap [RUIBTIO :, (€ ‘UdAT3 JON :

8661 SueNYZ 2» SUM
C66T ‘TR 28 eNS EIT
TZ6T suture)

OS6I OI

xSO6T [PIC

Z66T ‘Te 29 eYNsyeITH
IZ61 suru

OS6T OY

8661 SueNYZ 2» Sue
Z66T ‘Te 29 eYNsIeITY
LZ6T sururuns

«L061 Mopds 29 MopdS
LZ6T sururuns

8661 SueNYZ 2» Sue
LZ6T suru

so0c eURIngzZy

8661 SueNYyZ 2» Sue
Z66T ‘Te 29 eyNsIeITY
TZ6T surtuuine)

OS6I OI

x8C6I PANIY]
jaded yuasoid ayy,

TONAU AAA Y

S-€ SC-ST I@-LI X SP-CE
S-€ SC-ST OC-9I X SP-EE
c-€ SC-ST OC-9I X SP-EE
E56 CC-VL X CS-CE
v 2 I@-9L X SP-8T
€I-Z c-ST CC-ST X 9S-SE
€I-Z c-S'T CC-ST X 9S-GE
ScI-6 é I@-ST X 09-CP
v-€ C-S'T CC-LI XEV—-OE
v-€ c-S'T I@-LI X €h-O€
v-€ c-ST I@-LI X €P-0€
9-9 é OC-VI X SP-SE
6-S £-¢ LC-OC X 9P-€E
v-T f° VC-SI X SS-CE
€-¢ E-G VC-SI X SS-CE
9-9 c-ST VC-9L X 09-CE
8-T C-S'T VC-9L X OL-TE
9-9 C-SI €C-9L X 09-O0F
9-9 CSA. €C-9L X 09-0F
LE. é VC-9T X OL-TE
S8-Z é SC-ITC X 19-€P
9-9°C I-S'0 CC-VLI X G'9S-S'6E
xody apts (ur)
STAOASOITAY,

b-€

p-€

b-€
v

S-)
OI
V

‘ou
210g

€T-8I X TE-HT
€T-8I X €€-F7
€T-8I X €€-F7
ST-O7 X PE-8Z
€T-8I X 8Z-€Z
€T-6I X €€-97
€T-6I X €£-97
87-17 X PE-87
PT-8I X PE-LZ
€T-8I X €£-8Z
€T-8I X €£-8Z
SZ-8I X OF-77
€Z-61 X O€-F7

uUMOUYUN eIUTpar—,

CE-OC X BE-LT

LE-OC X 8E-ST

9C-61 X SE-6T

9T-61 X SE-6T

T¢e-07 X 8e-ST
GC X €€

SECT-G'6T X GSE-LT

(um)

9215

SHUOdSOINIGHY)

+ + + + + + +

+ + + + +

-uInTuUIpein
ul
SaSAHAVUVg

PISsSny
‘sautddrryg
‘uede( ‘WeMIey,
“euryD)

vissny ‘uede(

2PIMPHOM

BLY YINOS

euryo

BISsny
‘soutddrryg
‘uede( ‘ueMIey,
“eury)

NOLLOGISLSIG,

W'S

=
= ai

a
Sess

n
Bown

;VWuUANAD
LSOP

3 ‘Sgouasqy :— ‘souasarg :+ (7 ‘snAnjaovYyg :q ‘vuavjouvsdy], :], SWinsvyrIvG :S ‘snyguvosIPy 7 ‘vJosadwy :] ssnyguvLag vy (1

sndosyjasa g

sisuauaswp J

vjvydasouvjau

upiguvssiu g

DIOINYJUDISIM J

[Aepieg uou
‘oy *S avyyjna q =|
iyjuvostur J

SaIOadS

‘dds snyjuvosip uo payiodas saisads viuioong Jo ela} pue erurpein jo A8ojoydiow saneseduroy “| ATAVI,

Puccinia miscanthi life cycle (China) ... 533

angular, 17.5-23.5 x 14.5-19.0 um (av. = 20.5 x 17. 0 um); walls hyaline,
0.6-1.2 um (av.= 0.9 um) thick, densely verrucose.

Uredinia mostly on abaxial surface, scattered or gregarious, yellow-
brown, subepidermal, erumpent, with abundant paraphyses. Paraphyses
capitate; walls hyaline, thicker at the apical parts. Urediniospores pedicellate,
obovoid to ellipsoid, 27.0-35.5 x 19.5-23.5 um (av. = 30.0 x 21.5 um); walls
brown, echinulate, 0.7-1.5 um (av. = 1.0 um) thick; germ pores mostly 4,
equatorial. Telia mostly on abaxial surface, blackish brown, erumpent,
pulvinate. Teliospores pedicellate, oblong-clavate, 39.5-56.5 x 14.0-22.0 um
(av. = 47.0 x 19.0 um); walls chestnut-brown, 0.5-1.5 um (av. = 1.0 um) thick
at sides, 2.5-6.0 um (av. 4.0 um) thick at apices, smooth; pedicels persistent,
brown, thick-walled, short.

ADDITIONAL SPECIMENS EXAMINED — CHINA, HEILONGJIANG PROVINCE, Wuhan:
Spermogonia and aecia on Plantago asiatica, 2 July 2018, (HMJAU8644); cultured at
Jilin Agricultural University, Changchun, 5 July 2019 (HMJAU8642). Uredinia and telia
on Miscanthus sacchariflorus, 2 July 2018 (HMJAU8645); cultured at Jilin Agricultural
University, Changchun, 5 July 2019 (HMJAU8646).

Acknowledgments

This work was financed by the Fungal Flora in Jilin Province (20130206073NY).
We wish to thank Dr E.H.C. McKenzie (Manaaki Whenua Landcare Research,
Auckland, New Zealand) and Prof. C.M. Denchev (Bulgarian Academy of Sciences,
Sofia, Bulgaria) for critical reading of the manuscript and suggestions.

Literature cited

Asuyama H. 1936. A telial host of an Aecidium on Plantago asiatica L. Journal of Plant Protection
(Japan) 23: 206-207. (In Japanese)

Azbukina ZM. 2005. Rust fungi. Cryptogamic plants, fungi and mosses of the Russian Far East,
vol. 5. Dalnauka, Vladivostok. (In Russian)

Cao ZM, Li ZQ. 1999. Rust fungi of Qinling Mountains. China Forest Publishing House. Beijing.

Cummins GB. 1971. The rust fungi of cereals, grasses and bamboos. Springer-Verlag, New York.
https://doi.org/10.1007/978-3-642-88451-1

Cummins GB, Hiratsuka Y. 2003. Illustrated genera of rust fungi, 3" ed. American
Phytopathological Society, St. Paul, Minnesota.

Dietel P. 1905. Uredineae Japonicae. VI. Botanische Jahrbiicher fiir Systematik Pflanzengeschichte
und Pflanzengeographie 37: 97-109.

Dixon LJ, Castlebury LA, Aime MC, Glynn NC, Comstock JC. 2010. Phylogenetic relationships
of sugarcane rust fungi. Mycological Progress 9:
459-468. https://doi.org/10.1007/s11557-009-0649-6

Hiratsuka, N. 1933. Inoculation experiments with heteroecious species of Japanese rust fungi.
Botanical Magazine Tokyo 47: 710-714. https://doi-org/10.15281/jplantres1887.47.710

Hiratsuka N, Sato S, Katsuya K, Kakishima M, Hiratsuka Y, Kaneko S, Ono Y, Sato T, Harada
Y, Hiratsuka T, Nakayama K. 1992. The rust flora of Japan. Tsukuba-shuppankai, Tsukuba.

534 ... Ji &al.

Ito, S. 1934. Cultures of Japanese Uredinales I. Botanical Magazine Tokyo 48: 531-539.
https://doi.org/10.15281/jplantres 1887.48.531

Ito S. 1950. Mycological flora of Japan, vol. 2, no. 3, Urediniales-Pucciniaceae, Uredinales
Imperfecti. Yokendo, Tokyo.

Ji JX, Li Z, Wan Q, Li Y, Kakishima M. 2017a. Life cycle of Aecidium klugkistianum on
Ligstrum and its new combination, Puccinia klugkistiana. Mycoscience 58: 307-311.
https://doi.org/10.1016/j.myc.2017.01.004

Ji JX, Li Z, Wan Q, Li Y, Kakishima M. 2017b. Notes on rust fungi in China 3. Puccinia
adenocauli comb. nov. and its life cycle and new host. Mycotaxon 132: 141-148.
https://dx.doi.org/10.5248/132.141

Ji JX, Li Z, Li Y, Kakishima M. 2019. Two new species of Pucciniastrum producing
dimorphic sori and spores from northeast of China. Mycological Progress 18: 529-540.
https://doi.org/10.1007/s11557-018-1460-z

Miura M. 1928. Flora of Manchuria and east Mongolia III. Cryptogams, Fungi.
Minamimanshutetsudo, Dalian.

Ono Y, Azbukina ZM. 1997. Heteroecious life cycle of two graminicolous Puccinia
(Urediniales). Mycoscience 38: 281-286. https://doi.org/10.1007/BF02464085

Sato T, Kakishima M. 1982. Life cycles and morphology of two Puccinia species that produce
aecidioid sori on Lysimachia clethroides. Transactions of Mycological Society of Japan 23:
293-300.

Sydow H, Sydow P. 1907. Fungi Indiae orientalis pars II. Annales Mycologici 5: 485-515.

Tai FL. 1979. Sylloge fungorum Sinicorum. Science Press, Beijing.

Virtudazo EV, Nakamura H, Kakishima M. 2001. Phylogenetic analysis of sugarcane rusts
based on sequences of ITS, 5.88 rDNA and D1/D2 regions of LSU rDNA. Journal of
General Plant Pathology 67: 28-36. https://doi.org/10.1007/PL00012983

Wang YZ, Zhuang JY. 1998. Flora Fungorum Sinicorum vol. 10, Uredinales (I). Science Press,
Beijing.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 535-558
https://doi.org/10.5248/135.535

Biodiversity of heat-resistant ascomycetes
from semi-arid soils in Argentina

STELLA MARIS ROMERO??*, ANDREA IRENE ROMERO’”,
ALBERTO MIGUEL STCHIGEL?, ERNESTO RODRIGUEZ ANDRADE?,
VIVIANA ANDREA BARRERA‘, JOSE FRANCISCO CANO}, RICARDO COMERIO®

' Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales, DBBE,

Intendente Giiiraldes 2160, Pab. II Ciudad Universitaria, C1428EGA, Buenos Aires, Argentina
? CONICET-Universidad de Buenos Aires, Instituto de Micologia y Botanica (InMiBo),

Intendente Giiiraldes 2160, Pab. II Ciudad Universitaria, C1428EGA, Buenos Aires, Argentina
* Mycology Unit, Medical School and IISPV, Universitat Rovira i Virgili (URV),

Sant Lloreng 21, 43201 Reus, Tarragona, Spain
* Instituto Nacional de Tecnologia Agropecuaria (INTA), IMyZA-CICVyA,

N. Repetto y De los Reseros, CC25 1712, Castelar, Pcia. Buenos Aires, Argentina
° Instituto Nacional de Tecnologia Agropecuaria (INTA), EEA Anguil Ing. Agr. G. Covas,

Ruta Nacional N° 5, km 580, CC 11 6326 Anguil, Pcia. La Pampa, Argentina

* CORRESPONDENCE TO— smromero@conicet.gov.ar

ABSTRACT—Artificial thermal shock conducted on 50 soil samples from a semi-arid
geographic region (Catamarca and La Rioja provinces) in northern Argentina yielded 34
heat-resistant fungal strains. These strains were assigned to seventeen taxa in ten ascomycete
genera: Arthrinium (1), Aspergillus (3), Epicoccum (1), Gilmaniella (1), Hamigera (2),
Leiothecium (1), Penicillium (2), Talaromyces (4), Trichocladium (1), and Trichoderma (1). All
strains were identified by phenotypic features, with molecular data additionally obtained for
eleven strains. Five species are reported for the first time in Argentina.

Key worps —Ascomycota, Eurotiales, South America, Monte, Chaco.

Introduction

Temperature is an environmental parameter that plays a key role in the
survival, growth, distribution, and speciation of microorganisms on earth
(Mouchacca 1993). Fungi growing at high temperatures are generally classified

536 ... Romero &al.

in two groups: thermophilic and thermotolerant. Thermophilic fungi are
those able to grow in a temperature range of 20-50 °C or above; while the
maximum temperature for growth of thermotolerant fungi is near 50 °C with
a minimum of below 20 °C (Cooney & Emerson 1964, Mouchacca 2007).

Alternatively, heat-resistant fungi are defined as those capable of surviving
to a thermal shock, e.g., temperatures at or above 75 °C for 30 minutes
or more (Samson & al. 2000). The fungal structures able to survive these
extreme temperatures are mainly ascospores, but other propagules such
as chlamydospores, thick-walled hyphae, and sclerotia, also may survive
such temperature extreme (Scholte & al. 2004). Dijksterhuis & Samson
(2006) expanded the concept of heat-resistant fungi to include most of
fungal structures that survive after a thermal shock between 55-95 °C. Heat
resistance is associated with the ability to maintain the viability of certain
fungal structures in order to overcome natural thermal shock. Thus, heat-
resistant fungi can be mesophilic, thermotolerant, or thermophilic.

Soil, the primary reservoir of fungi, is also the main repository of dormant
propagules of true soil-borne fungi as well as of fungi that grow elsewhere.
Most fungi achieve survival through the production of both dormant
and dispersal spores (Carlile & Watkinson 1994). Latent spores normally
germinate due to slow dormancy decay or in response to a specific (physical
or chemical) stimulus that breaks the dormancy (Carlile & Watkinson 1994),
such as a thermal shock. Constitutive dormancy is a condition in which
the development is delayed by an innate property, such as a barrier to the
penetration of nutrients (including water), a metabolic blockage, or the action
of a self-inhibitory molecule (Dijksterhuis & Samson 2006, Dijksterhuis
2007). Ascospores, the sexual propagules of the Ascomycota, often have a
long survival capability (Dijksterhuis 2007). Ascospores of heat-resistant
fungi exhibit constitutive dormancy and require a robust signal (heat, high
pressure, or exposure to organic compounds, such as dimethylketone) to
break the dormancy (Dijksterhuis 2007, Stchigel 2000). Warcup & Baker
(1963) noted an increase in the number of ascomycete colonies when soil
samples were exposed to temperatures between 50-75 °C for 30 minutes
before culturing, compared with those not exposed to this thermal shock.

The fungal soil communities from arid regions are mainly characterized
by a low population coupled with a high biodiversity (Mouchacca 1993).
During broad research on heat resistant fungi from the semi-arid region
of Northern Argentina 194 isolates were obtained. Most isolates were
related to Aspergillus sect. Fumigati, but 34 isolates represented different

Heat resistant ascomycetes in Argentina ... 537

interesting taxa. This study documents those 34 miscellaneous heat-resistant
ascomycetes isolated from soil.

Materials & methods

Description of the sampling area

Fifty 200-g soil samples were collected in the summer of 2009 and winter of
2011 from several sites in Catamarca and La Rioja provinces, Northern Argentina.
Of the six phytogeographical regions of Catamarca (Morlans 1995), most samples
were collected from the “monte” region and only a few from the “chaquefia’” region;
additionally three collections were sampled from the “monte” region of La Rioja (with
five phytogeographical regions). The monte region in Catamarca, which comprises c.
14,600 km? (Manghi & al. 2005) and extends through the center of La Rioja province,
is characterized by steppe vegetation dominated by xerophilous, psammophilous,
or halophilous shrubs, and characterized by the almost constant presence of
Larrea (Zygophyllaceae) and Prosopis (Leguminosae). The climax community is Larrea
divaricata Cav. (“jarillal”), which develops in the sandy pockets and plains or stony-
sandy soils (Cabrera 1971). Climate in the monte is subtropical, arid, with an annual
150-200 mm precipitation occurring mostly in the summer (60-70% of total rainfall;
Morlans 1995). Temperature shows a relatively broad seasonal and daily variation,
with autumn/winter lows (-30 °C in west mountain region) and spring/summer
highs (45 °C in the east and central regions) (Gobierno de Catamarca 2018, Morlans
1995). The strong winds throughout the year favor environmental dryness. The monte
elevation ranges from 600-3000 m a.s.l. (Morlans 1995).

Fungal isolation

From each sample, c. 5 g of soil was placed into a conical flask, mixed with 100
ml of sterile melted malt extract agar (Oxoid MEA: malt extract 30.0 g, mycological
peptone 5.0 g, agar 15.0 g) plus 50 ppm of chloramphenicol, and heated at 75 °C for
30 min. The suspension was plated into sterile Petri dishes and, once gelled, incubated
at 30 °C <30 d (Samson & al. 2000). All colonies were transferred to individual Petri
dishes containing MEA to obtain pure cultures. The fungal strains were deposited
in the culture collection of the Herbarium, Universidad de Buenos Aires, Argentina
(BAFC) and the culture collection of Faculty of Medicine, Universitat Rovira i Virgili,
Reus, Catalonia, Spain (FMR). Author abbreviations include SMR (S.M. Romero),
AIR (A.I. Romero), AMS (Stchigel), ERA (Rodriguez Andrade), VB (Barrera), and
RC (Comerio). Abbreviations under CULTURE(S) EXAMINED are RN (Ruta Nacional)
and RP (Ruta Provincial).

Morphological study

Preliminary characterization at the genus level was conducted on MEA (Domsch
& al. 2007, Guarro & al. 2012). Species were identified by growing the fungal strains
on different culture media and temperatures (following the bibliography for each
genus mentioned in each description). Vegetative and reproductive structures were

538 ... Romero &al.

microscopically examined by mounting directly into lactic acid from cultures on MEA
and then observed under a Zeiss Axioskop bright field microscope. Mature ascomata
were crushed, coated with gold, and observed and photographed with a Zeiss Supra
40 (extra high tension = 3 Kv; working distance = 3.7-6 mm) scanning electron
microscope.

Molecular study

EXTRACTION: DNA was extracted directly from colonies on potato dextrose agar
(PDA) after 7-10 d at 25 °C in darkness, through the modified protocol of Miiller & al.
(1998). The following genetic markers were sequenced: fragments of -tubulin (BenA),
calmodulin (CaM), RNA polymerase II second largest subunit (rpb2) (Peterson & al.
2010, Samson & al. 2014), and the DNA replication licensing factor (Mcm7) (Schmitt
& al. 2009, Raja & al. 2011). The primers used were Bt2a and Bt2b for BenA, CMD5
and CMD6 for CaM (Glass & Donaldson 1995), RPB2-5F and RPB2-7R for rpb2 (Liu
& al. 1999), and Mcm7-709For and Mcm7-1348Rev for Mcm7 (Schmitt & al. 2009).
PCR products were sequenced in both directions using the same primers at Macrogen
Europe (Macrogen Inc., Madrid, Spain). Sequences were assembled and edited using
Sequencher v.4.1.4. The sequences generated were deposited in the GenBank database
(https:// www.ncbi.nlm.nih.gov/genbank) using the Webin platform of the European
Bioinformatics Institute (EMBL-EBI) (http://www.ebi.ac.uk/ena).

PHYLOGENETIC ANALYSIS: Multiple sequence alignment was conducted using
ClustalW (Thompson & al. 1994) and MUSCLE (Edgar 2004) within MEGA v.6
software (Tamura & al. 2013), with manual adjustments for refinement. The Maximum
Likelihood (ML) phylogenetic method was also run with MEGA v.6, as well as the
estimation of the best nucleotide substitution model. Support of the internal branches
was assessed by the bootstrap method with 1000 replications, where values 270 were
considered significant. The phylogenetic analyses were carried out first individually
for each gene followed by a concatenated study. To support our analyses, sequences
were obtained from GenBank and added to the analyses.

Taxonomy

In our study, 34 heat-resistant fungal strains from the semiarid region in
Argentina were all morphologically characterized and assigned to 17 taxa in
10 genera—Arthrinium (1), Aspergillus (3), Epicoccum (1), Gilmaniella (1),
Hamigera (2), Leiothecium (1), Penicillium (2), Talaromyces (4), Trichocladium
(1), and Trichoderma (1). For 11 strains, the morphological identification was
confirmed by molecular analyses. Five taxa are reported for the first time in
Argentina.

Arthrinium phaeospermum (Corda) M.B. Ellis, Mycol. Pap. 103: 8. 1965.
Cotontes on MEA, 25 °C, 7 d, floccose, covering the whole culture plate,
greyish, with dark specks and areas due to the anamorph presence.

Heat resistant ascomycetes in Argentina ... 539

Conrpi1a lenticular, dark brown, 9-11 x 5-7 um, smooth with a conspicuous
pale equatorial stripe.
CULTURES EXAMINED—ARGENTINA. CaTaMARCA: RP 46, km 70, 28°05’35”S
66°12’55”W, 859 m a.s.l., 24.VHI.2011, leg. SMR, identified by SMR & RC, isolation
22.X.2011 (BAFCcult 4624); 27°35’13”S 66°22’11’W, 996 m a.s.l, 24.VIII.2011, leg.
SMR, identified by SMR & RC, isolation 15.X1.2011 (BAFCcult 4625).
DISTRIBUTION— Worldwide, including Argentina (Broggi & al. 2007, Crous &
Groenewald 2013, Domsch & al. 2007).
Hasitat—Cereals and vegetable materials, dung, fresh water, and soil
(Domsch & al. 2007).

CoMMENTS—Otur isolates agreed morphologically with descriptions by Ellis
(1971), Domsch & al. (2007), and Crous & Groenewald (2013). In Argentina,
this species was isolated from soil in Buenos Aires (Cabello 1986) and cereals
collected in Entre Rios (Broggi & al. 2007, Sacchi & al. 2009).

Aspergillus flavus Link, Mag. Ges. Naturf. Freunde, Berlin 3: 16. 1809.

Cotoniges on MEA, 25 °C, 7 d, plane, granulose, floccose at the centre,
50-54 mm diam., yellowish green, exudate scarce uncolored; asexual sporulation
abundant. On Czapek yeast agar (CYA), 25 °C, 7 d, sulcate, granulose, floccose
at the centre, 60-68 mm diam., yellowish green, exudate scarce uncolored;
asexual sporulation abundant.

CONIDIAL HEADS commonly columnar, radiate, mainly uniseriate. STIPES
roughened, vesicles spherical. Conip1a globose, 3.5-4.5 um, with finely
roughened walls.

CULTURE EXAMINED—ARGENTINA. La Rioja: RN 60, km 1172, 28°40'30’S
66°30'23”W, 653 m a.s.l., 12.1.2009, leg. SMR, identified by SMR, isolation 1.III.2011
(BAFCcult 4615).
DIsTRIBUTION— Worldwide and cosmopolitan (Domsch & al. 2007; Ramirez-
Camejo & al. 2012).

HasitatT—Soil, cultivated or not (Domsch & al. 2007). This is the most
widely cited fungal species as a food contaminant (Klich 2002, Pitt & Hocking
2009).

ComMMENTS— The micromorphology of our isolate, and even its cultural
features, agreed with the descriptions of Klich (2002) and Pitt & Hocking
(2009). Horn & al. (2009) described the sexual stage for this heterothallic
species as Petromyces flavus B.W. Horn &al., but according to the International
Code of Nomenclature (Turland & al. 2018) and following Samson & al.
(2014), the correct name for this species is Aspergillus flavus. In Argentina,

540 ... Romero & al.

it has been isolated several times from soil (Allegrucci & al. 2009, Cabello
1986, Godeas & al. 1977, Mangiaterra & al. 2006, Winitzky 1948), foods
(Bresler & al. 1991, Castellari & al. 2015, Dalcero & al. 1998, Etcheverry & al.
1999, Romero & al. 2005, Sepulveda & Piontelli 2005) and medicinal herbs
(Sanchez & al. 2006).

Aspergillus montevidensis Talice & J.A. Mackinnon,
C.r. Seanc. Soc. Biol. 108: 1007. 1931. BIGiwTASB

CoLonies on MEA, 25 °C, 7 d, plane and dense, 14 mm diam., yellowish;
after 14 incubation d 26-28 mm diam., yellowish, with or without brown
center. On Czapek yeast agar with 20% sucrose, 25 °C, 7 d, velutinous, 35-47
mm diam., yellow, with green center due to the anamorph presence; after 14
incubation d covering the whole culture plate, velutinous to granulose due
to the abundant cleistothecia production, yellow with green center; asexual
sporulation copious; reverse yellowish under cleistothecia and greenish
under anamorph structures. At 37 °C, 7 d, 18-26 mm diam., yellow.

CLEISTOTHECIA superficial, mainly globose, discrete, 90-150 um diam.,
yellow, covered by a hyaline hyphal net. Asci globose, 8-spored, 10-12 x
8-11 um, evanescent. Ascosporss lenticular, 5-4 x 3-4 um, with rough
convex surfaces, furrowed and double-crested along the equator; SEM
images revealed pores distributed in the whole ascospore surface, but mainly
on crests. CONIDIAL HEADS radiate, uniseriate. STIPES 150-210 x 6-8 um,
smooth, vesicles globose, 15-27 um diam. PHIALIDEs ampulliform, 5-8 x 4
um. Conrp1A globose to subglobose, 5-4 x 4-3 um, spinulose.

CULTURES EXAMINED—ARGENTINA. CATAMARCA: RN 46, km 185, 27°45712”S
66°47°59”W, 1069 m a.s.l.. 9.1.2009, leg. SMR, identified by SMR, isolation
21.111.2011 (BAFCcult 4613; GenBank LT964777, LT964778); Papachacra, 2564 m
a.s.l., 10.1.2009, leg. SMR, identified by SMR, isolation 1.[1I.2011 (BAFCcult 4614;
GenBank LT964779, LT964780).
DIsTRIBUTION—Argentina (Winitzky 1952), Australia, Brazil, India, Israel,
Japan, Pakistan, Peru, South Africa, Syria, Tuamotu Archipelago, Turkey
(Domsch & al. 2007).

Hasitat—Soil, stored and/or decaying food products among other

substrates (Domsch & al. 2007, Pitt & Hocking 1997).

ComMMENTS—The morphological features of our strains agreed with
those described by Thom & Raper (1941), Raper & Fennell (1965), Klich
(2002) and Hubka & al. (2013). This species was also known as Eurotium
amstelodami because Thom & Raper (1941) changed the original species

Heat resistant ascomycetes in Argentina ... 541

concept of Mangin (1909), from a species with smooth-walled ascospores to
a species with ornamented ones. Their 1941 published name, E. amstelodami
was, in fact, a later illegitimate homonym. Pitt (1985) noted this confusion
and speculated that Thom & Church (1926) and Thom & Raper (1941)
did not base their description on the Mangin species concept. Hubka & al.
(2013) concluded that the first available and validly published name for the
species matching the concept of Thom & Raper (1941) is A. montevidensis,
which includes both the anamorph and the teleomorph states.

Aspergillus sydowii (Bainier & Sartory) Thom & Church, Aspergilli: 147. 1926.

CoLoniEs on MEA, 25 °C, 7 d, velutinous to slightly floccose, 14-15 mm
diam., blue green, asexual sporulation copious. On CYA, 25 °C, 7 d, sulcate,
velutinous, 20 mm diam., blue green, exudate brown copious; asexual
sporulation abundant; reverse orange brown. On 25% glycerol nitrate agar
(G25N), 25 °C, 7 d, plane and dense, 11-13 mm diam., bluish grey.

CONIDIAL HEADS radiate, biseriate; small and short penicillate heads
produced. Stipes 250-350 um, pigmented. Conip1A globose, 3.5-4 um,
very rough to spinose. HULLE CELLS abundantly produced.

CULTURES EXAMINED—ARGENTINA. Catamarca: Rincon, 28°22’03”S

66°13’39”W, 8.1.2009, leg. SMR, identified by SMR, isolation 4.VI.2009, (BAFCcult

4589); RP 25, 28°22’41”S 66°11'50”W, 1304 m a.s.l., 23.VIII.2011, leg. SMR,

identified by SMR, isolation 10.11.2012 (BAFCcult 4612).
DisTRIBUTION—Argentina, Australia, Austria, Brazil, British Isles, Canada,
Czechoslovakia, Egypt, India, Italy, Japan, Kuwait, Malaysia, Namibia,
Pakistan, Peru, Singapore, South Africa, Spain, Syria, ex USSR, U.S.A.
(Domsch & al. 2007).

Hasitat—Mainly isolated from soil, but also from air (indoor and
outdoor) (Klich 2002). This species has been reported from numerous
foods, especially dried ones (Pitt & Hocking 2009). It has been recovered
also from marine sponges (Ein-Gil & al. 2009).

CoMMENTS— The features of our isolates matched those described by
Raper & Fennell (1965) and Klich (2002). In Argentina, A. sydowii has been
previously isolated from air (Winitzky 1948), amaranth seeds (Bresler &
al. 1995), dried vine fruits (Romero & al. 2005), corn and soybean seeds
(Sepulveda & Piontelli 2005), soil (Allegrucci & al. 2007, Eliades & al. 2006a,
Mangiaterra & al. 2006) and medicinal herbs (Sanchez & al. 2006). This is
the first report for Catamarca province.

542 ... Romero &al.

Epicoccum nigrum Link, Mag. Gesell. Naturf. Freunde Berlin 7: 32. 1816.

Co.ontes on Blakeslee’s MEA, 25 °C, 7 d, floccose, 53-58 mm diam., orange
brown, exudate and soluble pigment absent; reverse orange. On oatmeal agar
(OA), 25 °C, 7 d, lanose to floccose, 60 mm diam., orange with yellowish centre,
exudate absent, soluble pigment yellow; reverse yellowish orange; after 12 d
of incubation brownish green centre due to sporulation. On PDA, 25 °C, 7 d,
23-30 mm diam., orange brown, exudate red caramel, soluble pigment amber;
reverse red brown.

CONIDIOPHORES crowded, even forming pustules. Conrp1A globose to
pyriform 22-30 x 18-29 um, orange brown to dark brown, verrucose, several
septa which divide the conidia in different directions, pale extending cell at the
base.

CULTURE EXAMINED— ARGENTINA. CATAMARCA: Papachacra, 2564 m as.l.,
10.1.2009, leg. SMR, identified by SMR, isolation 1.[II.2011 (BAFCcult 4622).
DISTRIBUTION— Worldwide (Domsch & al. 2007).

Hasitat—Cereals and grains, fruits, soil, among others (Domsch & al.

2007).

CoMMENTS—The morphologic characteristics of our isolate agreed with the
descriptions of Epicoccum nigrum by Ellis (1971) and Domsch & al. (2007). In
Argentina there are numerous records of this species, which were isolated from
soil samples of Jujuy province (Giusiano & al. 2002), wheat and soybean of
Entre Rios province (Broggi & al. 2007), soil and litter of Buenos Aires province
(Allegrucci & al. 2005, 2007), and alpataco fruits from La Pampa province
(Canafoglia & al. 2007), among others.

Gilmaniella humicola G.L. Barron, Mycologia 56: 514. 1964. FIG. 1P,Q

Cotontes on MEA, 25 °C, 7 d, velutinous to slightly floccose, 59-75 mm
diam., grayish, darkening in age; reverse very dark to black. At 30 °C, 7 d,
velutinous to slightly floccose, 79-83 mm diam., grayish, darkening in age;
reverse very dark to black.

Hypuae light brown in age, smooth. Conip14 globose, terminal or lateral,
usually in clusters and provided with a distinct germ pore, smooth, brown
7-9 um.

CULTURES EXAMINED—ARGENTINA. CaTAMaARca: RP 25, 28°15’31”S 66°08’47’W,
1424 m a.s.l., 23.VIH.2011, leg. SMR, identified by SMR & RC, isolation 11.1.2012
(BAFCcult 4610, 4588).
DIsTRIBUTION—Canada, Egypt, England, France, India, Japan, Namibia, Solomon
Islands, The Netherlands, United States of America (Domsch & al. 2007).

Heat resistant ascomycetes in Argentina ... 543

Fic. 1. Aspergillus montevidensis (BAFCcult 4613): A. Colonies on Czapek yeast extract agar
(CYA) with 20% of sucrose, 14 d, 25 °C; B. Ascospore (SEM). Hamigera paravellanea (BAFCcult
4605): C. Colonies on CYA, 7 d, 25 °C; D. Ascospores (SEM); E. Conidiophore and conidia.
Hamigera terricola (BAFCcult 4580): E Colonies on CYA, 7 d, 25 °C; G-H. Conidiophores and
conidia; I. Ascospores (SEM). Leiothecium ellipsoideum (BAFCcult 4598): J. Colony on MEA,
7 d, 25°C; K, L. Ascospores (SEM); M. Chlamydospore. Penicillium capsulatum (BAFCcult 1627):
N. Colonies on CYA, 7 d, 25 °C; O. Conidiophore and conidia. Gilmaniella humicola (BAFCcult
4588): P. Conidia with germination pores (arrows); Q. Colony on MEA 7 d, 30 °C. Trichocladium
pyriforme (BAFCcult 4623): R. Colony on MEA 14 d, 25 °C; S, T. Chlamydospores.

544 ... Romero &al.

Hasitat—Dung, groundnuts, plant debris, soil, among others (Domsch &
al. 2007).

COMMENTS—Otur isolates were phenotypically in accordance with Barron
(1964) and Ellis (1971). Gilmaniella humicola is a good representative example
of a heat-resistant fungus (Domsch & al. 2007), and it was the most thermal-
resistant fungus found by Bollen (1969), tolerating a temperature of 90 °C for
30 minutes. All our isolates were recovered from samples collected in winter.
In Argentina, the fungus was previously reported from soil in a Nothofagus
dombeyi forest in Rio Negro province (Godeas 1977).

Hamigera paravellanea S.W. Peterson, Jurjevi¢, Bills, Stchigel, Guarro & EE. Veja,
Mycologia 102: 852. 2010. FIG. 1C-E

Cotoniges on MEA, 25 °C, 7 d, plane somewhat floccose, 47-67 mm
diam., pale orange to tan; reverse dark, mainly at colony centre. On CYA, 25
°C, 7 d, low, slightly sulcate, 50-70 mm diam., pale orange to tan; reverse dark
reddish-brown.

GYMNOTHECIA globose, discrete, 120-280 um diam., cream coloured,
surrounded by a profuse hyphal net. Asci subglobose to claviform, 8-spored,
15-20 x 11-12 um, evanescent. Ascospores broadly ellipsoidal, 7—-7.5 x 5-6
um, hyaline, thick-walled, echinulate. ConrpIOPHORES penicillate, 120-480
x 3-5 um. Stipes slightly spathulate, smooth or roughened towards their
bases, widest at their apices. METULAE with wide apices, 10-15 x 4-6 um.
PHIALIDES ampulliform, 8-6 x 2-3 um. Conrp1a ellipsoidal, 3-4 x 2-3 um.,
smooth.

CULTURES EXAMINED—ARGENTINA. CATAMARCA: RP 25, 28°15’31”S 66°08’47’W,
1424 ma.s.L., 6.1.2009, leg. SMR, identified by SMR, AMS & ERA, isolation 20.1X.2011
(BAFCcult 4605, FMR 16758; GenBank LT991984, LT991994); 23. VII.2011, leg. SMR,
identified by SMR, AMS & ERA, isolation 11.1.2012 (BAFCcult 4606, FMR 16762;
GenBank LT992033, LT992032).
DIsTRIBUTION— Poland, Spain (Peterson & al. 2010).
Hasitat—Soil, dung (Peterson & al. 2010).

CoMMENTS—Morphological characters observed agreed with the description
of the protologue (Peterson & al. 2010). This is the first report for Argentina.

Hamigera terricola S.W. Peterson, Jurjevi¢, Bills, Stchigel, Guarro & EE. Veja
Mycologia 102: 855. 2010. FIG. 1F-I

COLONIES on MEA, 25 °C, 7 d, low, sulcate, velutinous, 58-70 mm diam.,
ochraceous buff to tan; reverse dark reddish-brown. On CYA, 25 °C, 7 d, low,

Heat resistant ascomycetes in Argentina ... 545

plane, velutinous, 40-43 mm diam., ochraceous buff with yellowish margins;
reverse dark reddish-brown.

GYMNOTHECIA globose, discrete, 80-180 um diam., cream coloured,
surrounded by a profuse hyphal net. Asci subglobose, 8-spored, 15-17.5 x
11-13 um, evanescent. AscosPorEs broadly ellipsoidal, 7-8 x 5-6 um, hyaline,
thick-walled, echinulate. CoNIDIOPHORES penicillate, 170-400 x 3-6 um.
STIPES sometimes spathulate, with apical vesicles 7-9 um wide, smooth or
slightly roughened. METULAE with wide apices, 7-11 x 3-6 um. PHIALIDES
ampulliform, 7-8 x 3 um. Conrp1a ellipsoidal, 3-4 x 2-3 um., smooth.

CULTURE EXAMINED—ARGENTINA. CATAMARCA: RN 60, km 1102, 28°55’15"S
66°08'46’W, 338 ma.s.l., 5.1.2009, leg. SMR, identified by SMR, AMS & ERA, isolation
4.V1.2011 (BAFCcult 4580, FMR 16756; GenBank LT991985, LT991995).
DIsTRIBUTION—Costa Rica, Equatorial Guinea, French Guiana, Guatemala,
Panama (Peterson & al. 2010).
HasitaT—Textile sample in contact with soil (Peterson & al. 2010).

CoMMENTS—In a broad sense, the features of this isolate matched with those
described by Peterson & al. (2010), but ascospores are slightly larger and
the asci smaller than in the original description. This is the first report of
Hamigera terricola for Argentina.

Leiothecium ellipsoideum Samson & Mouch.,
Can. J. Bot. 53: 1634. 1975. FIG. 1J-M

Cotonigs on MEA, 25 °C, 7 d, forming concentric rings, 82-83 mm diam.,
dark, superficial white mycelium present; reverse dark. At 35 °C, covering the
whole culture plate before 7 d; reverse dark due to ascomata abundance. On
OA, 25 °C, 7 d, colonies presenting a continuous layer of ascomata, dark, almost
lacking aerial mycelium. At 35 °C, covering the whole culture plate before 7 d;
subtle annularly developed, less aerial mycelium than on MEA.

VEGETATIVE HYPHAE smooth, 3-11 um diam., hyaline. CLEISTOTHECIA
globose, discrete, 40-90 um diam., dark brown, superficial or semi-submerged
in the substratum, covered by white mycelium supporting ascomata as well;
wall persistent, textura angularis, 5-8 um wide, composed by 15-25 um
diam. dark brown cells. Asci1 globose to subglobose, 14-18 x 13-15 um,
evanescent. Ascosporss ellipsoidal, 7-9 x 5.5-7 um, hyaline, spinulose under
low magnifications, broadly reticulate under high magnifications; young
ascospores presented an internal hyaline sheath which fades with maturity;
SEM observations revealed alveolate plaques on ascospore wall, alveoles
presented conspicuous projections at their edges which look as low frills.

546 ... Romero &al.

CHLAMYDOSPORES isolated, subglobose to ellipsoidal, umbonate, 4.5-11 um
diam., smooth, endogenous, and also terminal in maturity.

CULTURES EXAMINED— ARGENTINA. CATAMARCA: RN 60, km 1146, 28°13’05"S
66°22’41”W, 1051 m a.s.L., 5.1.2009, leg. SMR, identified by SMR, RC & AMS, isolation
13.IX.2011 (BAFCcult 4598, FMR 15064; GenBank LT992254, LT992257); km 1016,
29°30'04”S 65°37'57”W, 237 m a.s.L, 22.VIH.2011, leg. SMR, identified by SMR, RC
& AMS, isolation 12.XI.2011 (BAFCcult 4604, FMR 16765; GenBank LT992253,
LT992256); RP 47, km 35.5, 27°26'50”S 66°24’26”W, 2700 m a.s.l., 24.VHI.2011, leg.
SMR, identified by SMR, RC & AMS, isolation 18.1.2012 (BAFCcult 4609, FMR 16768;
GenBank LT992255, LT992258).
DISTRIBUTION—Canada (Samson & Mouchacca 1975), Greece, Hungary,
Portugal, Spain, United States of America, and Venezuela (CBS-KNAW Culture
Collection 2018).
HaBitTat—Soil, seeds of Capsicum annuum (Samson & Mouchacca 1975),
nest material of Nomia sp., a ground-nesting solitary bee (CBS-KNAW Culture
Collection 2018).

CoMMENTS—Argentinian isolates largely agreed with the description given
by Samson & Mouchacca (1975) and Guarro & al. (2012). However, these
strains grew faster on MEA at 35 °C than the ex-type strain. Regarding
micromorphology, no chlamydospores in chains were observed (solitary
chlamydospores were seen on small hyphal protrusions) and ascomata were
smaller (40-90 um vs. 125 um diam) than those described in the protologue.
This is the first report of Leiothecium ellipsoideum for Argentina.

Penicillium capsulatum Raper & Fennell, Mycologia 40: 528. 1948. Fic. 1N,o

Cotonigs on MEA, 25 °C, 7 d, low, plane, velutinous, 14-18 mm diam.,
white mycelium at the edges, grey green to dull green; conidiogenesis moderate;
exudate and soluble pigment absent; reverse pale to yellowish. On CYA,
25 °C, 7 d, moderately deep, sulcate, slightly fasciculate, 12-15 mm diam.;
conidiogenesis dense, grey green to dull green, white mycelium at the edges;
exudate and soluble pigment absent; reverse pale to yellowish. At 37 °C, 7 d,
funiculose, 18-21 mm diam., with white mycelium at the edges; exudate and
soluble pigment absent; reverse pale to buff. At 5 °C germination absent. On
G25N, 25 °C, 7 d, sulcate, velutinous to floccose, 6 mm diam., white mycelium
at the edges, conidia in mass grey green to dull green; exudate and soluble
pigment absent; reverse pale to yellowish.

TELEOMORPH absent. CONIDIOPHORE monoverticillate, arising from
substrate surface or from superficial mycelium. STIPES somewhat sinuose,
10-40 um long., smooth, mainly non-vesiculate, but sometimes vesicles up to

Heat resistant ascomycetes in Argentina ... 547

4 um diam. PHIALIDEs 5-8, ampulliform to acerose, 6 x 2 um, occasionally up
to 8 um in length, with short collula. Conrp1a ellipsoidal to cylindrical, 3-3.5
x 2 um, smooth-walled.

CULTURE EXAMINED—ARGENTINA. CaTAMARCA: RP 33, 28°42’03”S 65°46'08”W

418 m as.l., 22.VIH.2011, leg. SMR, identified by SMR & RC, isolation 23.X1.2011

(BAFCcult 1627).
DISTRIBUTION—China (Chen & al. 2013), Kiribati (Gilbert Islands), Panama
(Raper & Fennell 1948).

Hasitat—Optical instrument, environmentally exposed canvas and

deteriorated military equipment (Raper & Fennell 1948), and contaminated
beet pulp (Puls & Coughlan 1996).

CoMMENTS—Otr soil-borne isolate matched the Pitt (1979) description. We
also observed vesiculate conidiophores, but phialides were a bit shorter than in
the holotype. Pitt (1979) described the colonies on CYA at 25 °C as depressed
at the center, whereas the Argentinian strains presented a high and fasciculate
center. This is the first report of Penicillium capsulatum for Argentina.

Penicillium citrinum Thom, U.S.D.A. Bur. Animal Industr. Bull. 118: 61. 1910.
CoLonigs on MEA, 25 °C, 7 d, low, plane, centrally umbonate, velutinous,
18-22 mm diam., grey green to dull green; conidiogenesis dense; exudate pale,
soluble pigment absent; reverse pale. On CYA, 25 °C, 7 d, moderately deep,
sulcate, velutinous, 24-30 mm diam., grey green to dull green; conidiogenesis
dense, white mycelium at the edges; exudate pale, soluble pigment yellowish;
reverse yellow to orange. At 37 °C, 7 d, 2-11 mm diam. At 5 °C no germination.
TELEOMORPH absent. CONIDIOPHORES biverticillate, arising from substrate
surface or from superficial mycelium. STIPEs with smooth walls and a
conspicuous divaricate metulae whorl. METULAE of uniform length, 3-5
on each stipe. PH1ALIDES ampulliform, short collula. Conip1a globose to
subglobose, 2.5-3 um diam., smooth-walled.
CULTURE EXAMINED—ARGENTINA. CATAMARCA: Corral Quemado to Papachacra,
27°07'33"S 66°56'36"W, 2152 m a.s.l.: 10.1.2009, leg. SMR, identified by SMR & RC,
isolation 5.III.2011 (BAFCcult 4616).
DisTRIBUTION—Penicillium citrinum is considered a cosmopolitan and
frequently isolated fungus (Domsch & al. 2007).
Hasitat—The fungus has been reported from many substrates, including
food (Domsch & al. 2007).

CoMMENTS—Otmr isolate matched with the description of Penicillium citrinum
provided by Pitt (1979). In Argentina, it has been isolated many times, generally

548 ... Romero & al.

from food, e.g., soybeans (Bonera & al. 1982), amaranth seeds (Bresler & al.
1991, 1995), balanced feed for birds (Magnoli & al. 1998), and dried vine fruits
(Romero & al. 2005), among others.

Talaromyces macrosporus (Stolk & Samson) Frisvad, Samson & Stolk,
Antonie van Leeuwenhoek 57: 186, 1990.

Cotonigs on MEA, 25 °C, 14 d, almost covering the whole culture plate,
moderate deep, plane, granulose, covering the whole culture plate, yellow,
becoming orange at the centre.

CLEISTOTHECIA superficial, mainly globose, commonly confluent but at the
margin discrete, 200-400 um diam., yellow. Asci globose, 8-spored, evanescent;
initials showing thin antheridia coiled around slender clavated ascogonia.
ASCOSPORES ovoidal to broadly ellipsoidal, 5.5-6.5 x 3.5-4 um, pale yellow,
with thick walls and spines. ANAMORPH absent.

CULTURE EXAMINED—ARGENTINA. CaTAMARCA: RP 33, 28°42’03”S 65°46’08”W,

418 m asl, 22.VIL2011, leg. SMR, identified by SMR & AIR, isolation 23.X1.2011

(BAFCcult 4617).
DISTRIBUTION—Ghana, Japan, Korea, Malaysia, New Guinea, Panama, Poland,
South Africa, The Netherlands, United States of America (CBS-KNAW Culture
Collection 2018, Stolk & Samson 1972).

HasitatT—Soil, canned apples (Stolk & Samson 1972), freshly harvested
strawberries (Frison & al. 2012).

CoMMENTS—Our isolate agreed with the description of Talaromyces
macrosporus presented by Stolk & Samson (1972), who recognize two varieties:
T. flavus var. flavus and T. flavus var. macrosporus. Regarding these varieties,
Beuchat (1988) pointed out that the strains with small ascospores (T. flavus
var. flavus) are less thermal resistant than those with larger ones (T. flavus
var. macrosporus). Frisvad & al. (1990) raised them to species rank based on
ascospore size, heat-resistance, and secondary metabolite production. In
Argentina, the species has previously been recorded in soils either as T: flavus
s.l. or as T: flavus var. flavus (Bertoni 1973, Eliades & al. 2006 a,b, Magnoli & al.
1998). Frison & al. (2012) reported T: macrosporus on fresh strawberries.

Talaromyces pinophilus (Hedgc.) Samson, N. Yilmaz, Frisvad & Seifert, Stud.
Mycol. 70: 176. 2011.
CoLoniges on MEA, 25 °C, 7 d, moderately deep, plane, floccose, 34-36
mm diam., green; conidiogenesis sparse, yellow mycelium present, almost
dominating colony colour; exudate pale, soluble pigment absent; reverse

Heat resistant ascomycetes in Argentina ... 549

yellowish. On CYA, 25 °C, 7 d, moderately deep, plane, floccose, 19-20 mm
diam., greenish yellow; conidiogenesis sparse, yellow mycelium present
predominating in colony colour; exudate pale, soluble pigment absent; reverse
brown. At 37 °C, 7 d, 24-26 mm diam., with white mycelium at the edges;
exudate and soluble pigment absent; reverse buff. At 5 °C no germination. On
G25N, 25 °C, 7 d, plane, floccose, 3-5 mm diam., white mycelium; sporulation
absent; exudate pale, soluble pigment absent; reverse buff.

TELEOMORPH absent. CONIDIOPHORES biverticillate, arising from substrate
surface and also from aerial hyphae. Stipes 100-150 um long., smooth.
MetuLae in whorls mainly of 5 elements, 10-12 um long. PHIALIDEs 5-8,
acerose, 8-10 um long., tapered. Conip1A globose to subglobose, 3-4 um
diam., smooth-walled.

CULTURE EXAMINED—ARGENTINA. CATAMARCA: Corral Quemado to Papachacra,
27°07'33"S 66°56”36"W, 2152 m a.s.l., 10.1.2009, leg. SMR, identified by RC, isolation
5.I11.2011 (BAFCcult 4618).
DIsTRIBUTION—Argentina (Magnoli & al. 1998); Australia, France, India,
Papua New Guinea, United States of America (Pitt 1979); Uruguay (Galvalisi
& al. 2012).

Hasitat—Soil, decaying plants, deteriorated material, barley grains,

fermented dry sausages, balanced feed for birds (references as above).

ComMMENTS—Excluding conidia, which in this case were a little bit bigger (in
contrast to 2.5-2.8 x 2.2-2.5 um), we did not find morphological differences
compared to those of Talaromyces pinophilus given by Pitt (1979). In Argentina,
it has been previously reported as Penicillium pinophilum from corn, balanced
feed for birds, and soil (Etcheverry & al. 1999, Magnoli & al. 1998, Nesci & al.
2006, Mangiaterra & al. 2006).

Talaromyces trachyspermus var. macrocarpus J.E. Wright & Loewenb.,
Bol. Soc. Argent. Bot. 15(1): 100. 1973.

CoLonigs on MEA, 25 °C, 14 d, moderately deep, plane, granular, 37-44
mm diam., white to cream-colored; exudate absent; reverse orange.

CLEISTOTHECIA superficial, mainly globose, usually confluent, 400-930
uum diam., at first white becoming cream-colored in age, covered by a network
of hyphal net. Ascr globose to ovoid, 8-spored, 7-8 x 6-7 tm, evanescent.
AscosPpores ellipsoidal, 3-4 x 2-3 um, spinulose. ConrDIOPHORES slender
monoverticillate and biverticillate, short. METULAE 8-11 x 2 um. PHIALIDES
2-5 in verticils, lanceolate, tapering to neck, 9-10 x 2 um. Conrp1a ellipsoidal,
2-2.5 x 2 um, smooth-walled.

550 ... Romero & al.

CULTURE EXAMINED—ARGENTINA. CATAMARCA: RP 46, km 185, 27°45’12”S
66°47'59”’W, 1069 m a.s.l., 9.1.2009, leg. SMR, identified by SMR & AIR, isolation
21.111.2011 (BAFCcult 4621; GenBank LT968851).
DISTRIBUTION—Argentina (Bertoni & al. 1973).
HasitatT—Soil (Bertoni & al. 1973).

COMMENTS—The characteristics of isolate BAFCcult 4621 agreed with the
description of Talaromyces trachyspermus var. macrocarpus by Bertoni & al.
(1973). This variety was not accepted by Pitt (1979); however, we prefer to
recognize it until examination of the holotype, and study of more isolates and
their molecular data. T’ trachyspermus var. macrocarpus is distinguished from
T. trachyspermus by presenting bigger cleistothecia (500-1500 vs 50-350 um)
and ascospores (4-4.5 x 2.8-3.2 vs 3-3.5 x 2-2.5 um).

Talaromyces trachyspermus (Shear) Stolk & Samson, Stud. Mycol. 2: 32 (1973)
var. trachyspermus

CoLonigs on MEA, 25 °C, 14 d, moderately deep, plane, granular, 42-50
mm diam., white to cream-colored; exudate absent; reverse light orange and
orange to brown in the centre.

CLEISTOTHECIA superficial, mainly globose, usually confluent, 150-350
um diam., at first white becoming cream-colored in age, covered by a hyphal
network. Ascr globose to ovoid, 8-spored, 7-9 x 6-8 um, evanescent.
AscosPorss ellipsoidal, 3.5-4 x 2-3 um, spinulose. CONIDIOPHORES slender
monoverticillate and biverticillate, short. METULAE 8-11 x 2 um. PHIALIDES
2-5 in verticils, lanceolate, tapering to neck, 9-10 x 2 um. Conrp1a ellipsoidal,
2-2.5 x 2 um, smooth-walled.

CULTURES EXAMINED—ARGENTINA. CaTAMARCA: RP 46, 27°35'13”S 66°22’11”W,
996 m a.s.l., 9.1.2009, leg. SMR, identified by SMR & AIR, isolation 21.11.2011
(BAFCcult 4619; GenBank LT968849); (BAFCcult 4620; GenBank LT968850);
28°46'22”S 66°09'56”W, 1317 m a.s.l., 24.VIII.2011, leg. SMR, identified by SMR &
AIR, isolation 4.1.2012 (BAFCcult 4629); Belén, 27°07’33”S 66°56'36’W, 2152 m a.s.L.,
25.VIII.2011, leg. SMR, identified by SMR, isolation 27.1.2012 (BAFCcult 4630); RP 47,
km 35.5, 27°26'50”S 66°24’26”W, 2700 m a.s.l., 25.VII.2011, leg. SMR, identified by
SMR, isolation 18.1.2012 (BAFCcult 4631).

DIsTRIBUTION—Argentina, Bangladesh, France, Germany, India, Japan, Nepal,
Pakistan, South Africa, Tahiti, Uganda, United States of America (Domsch &
al. 2007).

Hasitat—Soil, cereals and grains, dung (Domsch & al. 2007).

CoMMENTS—The morphological features of our isolates agreed with the
original description of Talaromyces trachyspermus (Stolk & Samson 1972). In

Heat resistant ascomycetes in Argentina ... 551

Argentina Bertoni & al. (1973) and Godeas (1975) isolated this fungus from
soil.

Trichocladium pyriforme M. Dixon,
Trans. Br. Mycol. Soc. 51: 160. 1968. FIG. 1R-T

Co.tontges on MEA, a 25 °C, 7 d, plane, slightly floccose, 36-40 mm diam.,
grey green to olive, darkening in age; reverse very dark; covering the whole
culture plate in 21 d.

Hypuae hyaline when young, yellow brown in age, 2-5 um wide, smooth.
CHLAMYDOSPORES (holothallic conidia) terminal, pyriform, 3-4 celled, 16-19 x
6-7.5 um, smooth-walled; distal cell dark brown, with an acute apex and
germinative pore.

CULTURES EXAMINED—ARGENTINA. CaTAMaARCA: RN 60, km 934, 29°33’35’S
64°52’56’W, 186 ma.s.l., 5.1.2009, leg. SMR, identified by SMR & AIR, isolation 5.1.2011
(BAFCcult 4623); RN 40, km 4243.5, 26°51’23”S 66°05’52”W, 2031 ma.s.l., 25.VHIL2011,
leg. SMR, identified by SMR & AIR, isolation 12.X1.2011 (BAFCcult 4611).
DISTRIBUTION—Czech Republic (Mantle & al. 2006), Ireland (Dixon 1968).
Hasitat—Soil (Dixon 1968, Goh & Hyde 1999).

CoMMENTS—The morphological features of the Argentinian strains of
Trichocladium pyriforme agreed with those described by Dixon (1968) and by
Goh & Hyde (1999). Domsch & al. (2007) pointed out the remarkable thermal
resistance of the spores of this species, and Dixon (1968) stated that it tolerated
up to 95 °C for 10 min. Bollen (1969) isolated T. pyriforme from greenhouse
soil using a thermal shock at temperatures greater than 55 °C. This is the first
report of this fungus in Argentina.

Trichoderma saturnisporum Hammill, Mycologia 62: 112. 1970.

COLONIES on special nutrient agar (SNA), 72 h, 30 °C, in darkness,
somewhat annellated, 38-44 mm diam., green. At 35 °C, 72 h, 38 mm diam.
On PDA, 72 h, 30 °C, slightly annellated, 60 mm, dull green; at 35 °C, 69 mm
diam. in darkness.

CONIDIOPHORES associated in tufts up to 4 mm diam., branched, short
sterile projections present. PHIALIDES mainly in verticils, cylindrical, 8.5-11
x 3.3-4 um. Conrp1A subglobose to broadly ellipsoidal, 4-4.8 x 2.9-3.7 um,
greenish, walls with few notorious warts. CHLAMYDOSPORES not observed.

CULTURES EXAMINED—ARGENTINA. CATAMARCA: RN 60, km 1016, 29°30'04’S
65°37'57”W, 237 m a.s.l., 5.1.2009, leg. SMR, identified by SMR & RC, isolation
3.VHI.2010 (BAFCcult 4584, 4586, 4587); RP 25, 28°14’36”S 66°08’51”W, 1507 m
a.s.l., 6.12009, leg. SMR, identified by SMR & VB, isolation 1.X1.2010 (BAFCcult 4626);

552 ... Romero &al.

Rincon, 28°22’03"S 66°13’39’W, 8.1.2009, leg. SMR, identified by SMR & VB, isolation
19. VIII.2010 (BAFCcult 4627, 4628.
DIsTRIBUTION—Argentina (Godeas & al. 1977), Australia, Italy, South Africa,
Turkey, United States (Samuels & al. 1998).
HaBitaT—Soil.

CoMMENTS—The morphological features of the examined culture agreed
with those given by Samuels & al. (1998). Trichoderma saturnisporum is easily
recognized by conidia with large warts mimicking wings, which give a saturnian
appearance to the conidia.

Discussion

In previous papers we described two new species of Eurotiales, Talaromyces
systylus S.M. Romero & al. (Romero & al. 2016) and Aspergillus fuscicans S.M.
Romero & al. (Romero & al. 2018) from the same locations and substrate (soil)
as in the present work. ‘The isolates in Aspergillus sect. Fumigati, which were
prevalent in the analyzed samples, are currently under study.

Some of the fungal species found have been previously cited as heat-resistant,
such as Arthrinium phaeospermum (Kashiwagi & al. 2009, Pitt & Hocking
2009), Gilmaniella humicola (Bollen 1969, Jesenska & al. 1992), Leiothecium
ellipsoideum (Samson & Mouchacca 1975), Talaromyces macrosporus (Beuchat
1988, Frison & al. 2012) and Trichocladium pyriforme (Bollen 1969, Dixon
1968).

It was not possible to obtain information about the heat-resistance of
Aspergillus montevidensis; however, Aspergillus glaucus (L.) Link, another
species in A. sect. Aspergillus, was isolated from contaminated jellies and
grape marmalades, and its thermal resistance was analyzed (Splittstoesser &
al. 1989). No information about the heat resistance was found for Trichoderma
saturnisporum; however, chlamydospore production (Samuels & al. 1998)
would explain its survival after a thermal shock performed in the lab.

Byssochlamys nivea, perhaps the most well-known heat-resistant fungal
species, was not isolated during this study. This could be attributed to our
thermal treatment (75 °C, 30 min), since other authors have determined that
its ascospores can survive at 70 °C for 60-75 min but not at 80 °C for 1 min
(Pieckova & al. 1994). The same authors also mentioned that at 80 °C the
ascospores of Hamigera avellanea Stolk & Samson survive 120 min, whereas
the conidia of Gilmaniella humicola survive between 8-14 min. Although no
data were found on the thermal resistance of H. paravellanea and H. terricola
ascospores, given the heat resistance described for H. avellanea (Pieckova & al.

Heat resistant ascomycetes in Argentina ... 553

1994, Scaramuzza & Berni 2014), it can be assumed that other species of the
genera would possess a similar capacity.

Acknowledgements

S.M. Romero and A.I. Romero thank the Consejo Nacional de Investigaciones
Cientificas y Técnicas (CONICET-Argentina), PIP1086 and PICT-2018-03781 for
the financial support to perform the present study. In addition, the Instituto de
Microbiologia y Zoologia Agricola (Instituto Nacional de Tecnologia Agropecuaria)
is particularly recognized for the provision of supplies and facilities to carry out
this work. The authors acknowledge Dr. Maria Virginia Bianchinotti (CERZOS-
CONICET, Universidad Nacional del Sur, Argentina) and Dr. Andrew Miller (Illinois
Natural History Survey, University of Illinois, U.S.A.) for reading and improving the
manuscript as pre-submission reviewers. The insightful and careful review of the
Nomenclature Editor, Dr. Shaun R. Pennycook, is especially appreciated. The design
and preparation of the plate by the technician Mariana Valente (InMiBo-CONICET)
is held in high esteem.

Literature cited

Allegrucci N, Cazau MC, Cabello MN, Arambarri AM. 2005. Analisis de las comunidades de
microhongos de la hojarasca de Scutia buxifolia (Rhamnaceae) en el este de la provincia de
Buenos Aires, Argentina. Darwiniana 43: 1-9.

Allegrucci N, Eliades L, Bucsinszky AM, Cabello M, Arambarri A. 2007. Diversidad de Anamorfos
de Ascomycota en bosques nativos de Celtis tala (Ulmaceae) en la Provincia de Buenos Aires,
Argentina. Bol. Soc. Argent. Bot. 42: 79-86.

Allegrucci N, Cabello MN, Arambarri AM. 2009. Diversity of saprotrophic anamorphic
ascomycetes from native forests in Argentina: an updated review. Darwiniana 47: 108-124.
Barron GL. 1964. A new genus of the hyphomycetes from soil. Mycologia 56: 514-518.

https://doi.org/10.2307/3756356

Bertoni MD, Godeas AM, Loewenbaum ME, Wright JE. 1973. Micoflora del suelo de la Argentina.
IV Algunas formas ascosporicas adicionales de la Regidn Chaquenia. Bol. Soc. Argent. Bot. 1:
93-105.

Beuchat LR. 1988. Influence of organic acids on heat resistance characteristics of Talaromyces flavus
ascospores. Int. J. Food Microbiol. 6: 97-105. https://doi.org/10.1016/0168-1605(88)90046-3.

Bollen GJ. 1969. The selective effect of heat treatment on the microflora of a greenhouse soil. Neth.
J. Plant. Pathol. 75: 157-163. https://doi.org/10.1007/BF02137211

Bonera N, Pinto VF, Vaamonde G, Varsavsky E. 1982. Hongos toxicogénicos en la flora fungica de
semillas de soja. An. Asoc. Quim. Argent. 70: 773-781.

Bresler G, Vaamonde G, Brizzio S. 1991. Natural occurrence of zearalenone and toxicogenic
fungi in amaranth grain. Int. J. Food Microbiol. 13: 75-80.
https://doi.org/10.1016/0168-1605(91)90139-G

Bresler G, Brizzio SB, Vaamonde G. 1995. Mycotoxin-producing potential of fungi isolated
from amaranth seeds in Argentina. Int. J. Food Microbiol. 25: 101-108.
https://doi.org/10.1016/0168-1605(94)00117-O

Broggi LE, Gonzalez HHL, Resnik SL, Pacin A. 2007. Alternaria alternata prevalence in cereal
grains and soybean seeds from Entre Rios, Argentina. Rev. Iberoam. Micol. 24: 47-51.

554 ... Romero &al.

Cabello M. 1986. Analisis de la metodologia empleada en el aislamiento de hongos en suelos de la
region interserrana. Cienc. Suelo 2: 225-229.

Cabrera AL. 1971. Fitogeografia de la Republica Argentina. Bol. Soc. Argent. Bot. 14: 1-2.

Canafoglia M, Comerio R, Fernandez Pinto VF, Vaamonde G. 2007. Hongos toxicogénicos
contaminantes de frutos de alpataco. Rev. Iberoam. Micol. 24: 56-58.

Carlile MJ, Watkinson SC. 1994. The Fungi. Academic Press, London.

Castellari CC, Cendoya MG, Valle FJM, Barrera V, Pacin AM. 2015. Factores extrinsecos e
intrinsecos asociados a poblaciones fingicas micotoxigénicas de granos de maiz (Zea
mays L.) almacenados en silos bolsa en Argentina. Rev. Argent. Microbiol. 47: 350-359.
https://doi.org/10.1016/j.ram.2015.08.003

CBS-KNAW Culture Collection. (2018). Accessed December 2018: http://www.westerdijkinstitute.
nl/Collections/Biolomics.aspx? Table=CBS%20strain %20database

Chen M, Houbraken J, Pan W, Zhang C, Peng H, Wu L, Xu D, Xiao Y, Wang Z, Liao W. 2013.
Pulmonary fungus ball caused by Penicillium capsulatum in a patient with type 2 diabetes: a
case report. BMC Infect. Dis. 13: 496. https://doi.org/10.1186/1471-2334-13-496

Cooney DG, Emerson R. 1964. Thermophilic fungi. An account of their biology, activities and
classification. WH Freeman & Co., San Francisco & London.

Crous PW, Groenewald JZ. 2013. A phylogenetic re-evaluation of Arthrinium. IMA Fungus 4:
133-154. https://doi.org/10.5598/imafungus.2013.04.01.13

Dalcero A, Magnoli C, Luna M, Ancasi G, Reynoso MM, Chiacchiera S, Miazzo R, Palacio G. 1998.
Mycoflora and naturally occurring mycotoxins in poultry feeds in Argentina. Mycopathologia
141: 37-43. https://doi.org/10.1023/A:1006868002985

Dijksterhuis J. 2007. Heat-resistant ascospores. Chapter 6, in: J Dijksterhuis & R Samson (eds.)
Food Mycology, a multifaceted approach to fungi and food. CRC Press, Taylor & Francis Group.

Dijksterhuis J, Samson RA. 2006 Activation of ascospores by novel food preservation techniques.
247-260, in: AD Hocking & al. (eds). Advances in Food Mycology. Advances in Experimental
Medicine and Biology, vol 571. Springer, Boston. https://doi.org/10.1007/0-387-28391-9_17

Dixon M. 1968. Trichocladium pyriformis sp. nov. Trans. Br. Mycol. Soc. 51: 160-164.
https://doi.org/10.1016/S0007-1536(68)80139-1

Domsch KH, Gams W, Anderson TH. 2007. Compendium of soil fungi, 2nd ed., taxonomically
revised by W Gams. IHW, Eching.

Edgar RC. 2004. MUSCLE— multiple sequence alignment with high accuracy and high throughput.
Nucleic Acids Res. 32: 1792-1797. https://doi.org/10.1093/nar/gkh340.

Ein-Gil N, Ilan M, Carmeli S, Smith GW, Pawlik JR, Yarden O. 2009. Presence of Aspergillus
sydowii, a pathogen of gorgonian sea fans in the marine sponge Spongia obscura. ISME Journal
3: 752-755. https://doi.org/10.1038/ismej.2009.18

Eliades LA, Cabello MN, Voget CE. 2006a. Soil microfungi diversity in Celtis tala and Scutia
buxifolia forests in Eastern Buenos Aires Province (Argentina). J. Agr. Sci. Tech. 2: 229-249.

Eliades LA, Cabello MN, Voget CE. 2006b. Contribution to the study of alkalophilic and
alkalitolerant Ascomycota from Argentina. Darwiniana 44: 64-73.

Ellis MB. 1971. Dematiaceous hyphomycetes, Commonwealth Mycological Institute, Kew, Surrey.

Etcheverry M, Nesci A, Barros G, Torres A, Chulze S. 1999. Occurrence of Aspergillus section Flavi
and aflatoxin B1 in corn genotypes and corn meal in Argentina. Mycopathologia 147: 37-41.
https://doi.org/10.1023/A— 1007040123181

Frison L., Sobrero S, De Jesus J, Basilico M, Basilico. 2012. Identificacién y caracterizacién de
especies de Neosartorya aisladas de frutillas (Fragaria spp.) frescas y tratadas térmicamente.
Rev. Venez. Cienc. Tecnol. Aliment. 3: 319-329.

Heat resistant ascomycetes in Argentina ... 555

Frisvad JC, Filtenborg O, Samson RA, Stolk AC. 1990. Chemotaxonomy of the genus Talaromyces.
Antonie Leeuwenhoek 57: 179-189. https://doi-org/10.1007/BF00403953

Galvalisi U, Lupo S, Piccini J, Bettucci L. 2012. Penicillium species present in Uruguayan salami.
Rev. Argent. Microbiol. 44: 36-42. https://doi.org/10.1590/S0325-75412012000100008

Giusiano G, Piontelli L, Mangiaterra M, Sosa MA. 2002. Distribucion altitudinal de hongos
queratinofilos, epifitos y endofitos en suelos semiaridos del noreste argentino (Prov. de Jujuy,
23°L.S y 66°L.W). Boletin Micolégico 17: 51-62.
http://dx.doi.org/10.22370/bolmicol.2002.17.0.437

Glass NL, Donaldson GC. 1995. Development of primer sets designed for use with the PCR
to amplify conserved genes from filamentous ascomycetes. Appl. Environ. Microbiol. 61:
1323-1330.

Gobierno de Catamarca. 2018. https://www.portal.catamarca.gob.ar/provincia/clima/ [accessed
November 2018].

Godeas AM. 1975. Micoflora del suelo de la Argentina V. Formas ascosporicas adicionales de la Pcia.
De Buenos Aires, provincia fitogeografica del Espinal, Distrito de los Talares. Mycopathologia
56: 81-96. https://doi.org/10.1007/BF00472579

Godeas AM. 1977. Estudio cuali y cuantitativo de los hongos del suelo del bosque de Nothofagus
dombeyi. PhD dissertation, Universidad de Buenos Aires.

Godeas AM, Marchand SG, Bertoni MD. 1977. Micoflora del suelo de la Argentina IV. Algunos
hongos imperfectos hallados frecuentemente en el suelo de la Pcia. de Bs. As. Bol. Soc. Argent.
Bot. 28: 33-35.

Goh TK, Hyde KD. 1999. A synopsis of Trichocladium species, based on the literature. Fungal
Divers. 2: 101-118.

Guarro J, Gene J, Stchigel AM, Figueras MJ. 2012. Atlas of soil ascomycetes. CBS Biodiversity Series
no. 10. CBS-KNAW Fungal Biodiversity Centre, Utrecht.

Horn BW, Moore GG, Carbone I. 2009. Sexual reproduction in Aspergillus flavus. Mycologia 101:
423-429. https://doi.org/10.3852/09-011

Hubka V, Kolarik M, Kubatova A, Peterson SW. 2013. Taxonomic revision of the genus Eurotium
and transfer of species to Aspergillus. Mycologia 105: 12-151. https://doi.org/10.3852/12-151

Jesenska Z, Pieckova E, Bernat D. 1992. Heat-resistant fungi in the soil. Int. J. Food Microbiol. 16:
209-214. https://doi.org/10.1016/0168-1605(92)90081-D

Kashiwagi S, Baba H, Yoshida S, Udagawa S. 2009. Identification and cultural characters
of two species of Arthrinium isolated from spoilt foods. Jpn. J. Microbiol. 26: 16-22.
https://doi.org/10.5803/jsfm.26.16

Klich MA. 2002. Identification of common Aspergillus species. Centraalbureau voor
Schimmelcultures, Utrecht.

Liu YJ, Whelen S, Hall BD. 1999. Phylogenetic relationships among ascomycetes: evidence from
an RNA polymerase II subunit. Mol. Biol. Evol. 16: 1799-1808.
https://doi.org/10.1093/oxfordjournals.molbev.a026092

Magnoli C, Dalcero AM, Chiacchiera SM, Miazzo R, Saenz MA. 1998. Enumeration and
identification of Aspergillus group and Penicillium species in poultry feeds from Argentina.
Mycopathologia 142: 27-32. https://doi.org/10.1023/A:1006981523027

Manghi IFE, Brouver IFM, Montenegro IAC, Parmuchi LC, Bono LC, Strada GM. 2005. Mapa
Forestal Provincia de Catamarca. Accessed November 2018:
http://www.ambiente.gob.ar/archivos/web/UMSEF/File/2002_catamarca.pdf.

Mangiaterra M, Giusiano G, Gonzalez I. 2006. Algunos microhongos geofilicos de las planicies
semiaridas del noroeste de la Provincia de San Luis (Argentina). Boletin Micoldégico 21: 43-48.
https://doi.org/10.1023/A:1006981523027

556 ... Romero & al.

Mangin L.1909. Quest-ce que l’Aspergillus glaucus? Ann. Sci. Nat. Bot. Sér. 9, 10: 360.

Mantle PG, Hawksworth DL, Pazoutova S, Collinson LM, Rassing BR. 2006. Amorosia littoralis
gen. sp. nov., a new genus and species name for the scorpinone and caffeine-producing
hyphomycete from the littoral zone in the Bahamas. Mycological Research 110: 1371-1378.
https://doi.org/10.1016/j.mycres.2006.09.013

Morlans MC. 1995. Regiones naturales de Catamarca. Provincias geolégicas y provincias
fitogeograficas. Revista de Ciencia y Técnica 2: 1-42.

Mouchacca J. 1993. Thermophilic fungi in desert soils— a neglected extreme environment. 265-
288, in: J] Mouchacca & al. (eds). Microbial diversity and ecosystem function: proceedings of
the IUBS/IUMS Workshop held at Egham, UK, 10-13 August 1993. CAB International.

Mouchacca J. 2007. Heat tolerant fungi and applied research— Addition to the previously treated
group of strictly thermotolerant species. World J. Microbiol. Biotechnol. 23: 1755-1770.
https://doi.org/10.1007/s11274-007-9426-3

Miller FM, Werner KE, Kasai M, Francesconi A, Chanock SJ, Walsh TJ 1998. Rapid extraction
of genomic DNA from medically important yeasts and filamentous fungi by high-speed cell
disruption. J. Clin. Microbiol. 36: 1625-1629

Nesci A, Barros G, Castillo C, Etcheverry M. 2006. Soil fungal population in preharvest maize
ecosystem in different tillage practices in Argentina. Soil and Tillage Research 91: 143-149.
https://doi.org/10.1016/j.still.2005.11.014

Peterson SW, Jurjevic¢ Z, Bills GE Stchigel AM, Guarro J, Vega FE. 2010. Genus Hamigera,
six new species and multilocus DNA sequence-based phylogeny. Mycologia 102: 847-64.
https://doi.org/10.3852/09-268

Pieckova E, Bernat D, Jesenska Z. 1994. Heat resistant fungi isolated from soil. Int. J. Food
Microbiol. 22: 297-299. https://doi.org/10.1016/0168-1605(94)90181-3.

Pitt JI. 1979. The genus Penicillium and its teleomorphic states Eupenicillium and Talaromyces.
Academic Press Inc, London.

Pitt JI. 1985. Nomenclatorial and taxonomic problems in the genus Eurotium. 383-396, in: RA
Samson & JI Pitt (eds). Advances in Penicillium and Aspergillus systematics. Plenum Press,
New York. https://doi.org/10.1007/978-1-4757-1856-0_30

Pitt JI, Hocking AD. 1997. Fungi and food spoilage. Blackie Academic & Professional, New South
Wales.

Pitt JI, Hocking AD. 2009. Fungi and food spoilage. Springer, New York.

Puls J, Coughlan MP. 1996. Purification and characterization of two arabinofuranosidases from
solid-state cultures of the fungus Penicillium capsulatum. Appl. Environ. Microbiol. 62:
168-173.

Raja H, Schoch CL, Hustad V, Shearer C, Miller A. 2011. Testing the phylogenetic utility of MCM7
in the Ascomycota. MycoKeys 1: 63-94. https://doi.org/10.3897/mycokeys. 1.1966

Ramirez-Camejo LA, Zuluaga-Montero A, Lazaro-Escudero M, Hernandez-Kendall V, Bayman
P. 2012. Phylogeography of the cosmopolitan fungus Aspergillus flavus— is everything
everywhere? Fungal biology 116: 452-463. https://doi.org/10.1016/j.funbio.2012.01.006

Raper KB, Fennell DI. 1948. New species of Penicillium. Mycologia 40: 507-546.

Raper KB, Fennell DI 1965. The genus Aspergillus. Williams & Wilkins Co, Baltimore.

Romero SM, Comerio RM, Larumbe G, Ritieni A, Vaamonde G, Fernandez Pinto VE. 2005.
Toxigenic fungi isolated from dried vine fruits in Argentina. Int. J. Food Microbiol. 104: 43-49.
https://doi.org/10.1016/j.ijfoodmicro.2005.04.001

Romero SM, Romero AI, Barrera V, Comerio RM. 2016. Talaromyces systylus, a new synnematous
species from Argentinean semi-arid soil. Nova Hedwigia 102: 241-256.
https://doi.org/10.1127/nova_hedwigia/2015/0306

Heat resistant ascomycetes in Argentina ... 557

Romero SM, Comerio RM, Barrera VA, Romero AI. 2018. Aspergillus fuscicans (Aspergillaceae,
Eurotiales), a new species in section Usti from Argentinean semi-arid soil. Phytotaxa 343:
67-74. https://doi.org/10.11646/phytotaxa.343.1.6

Sacchi C, Gonzalez HHL, Broggi LE, Pacin A, Resnik SL, Cano G, Taglieri D. 2009. Fungal
contamination and mycotoxin natural occurrence in oats for race horses feeding in Argentina.
Anim. Feed Sci. Technol. 152: 330-335. https://doi.org/10.1016/j.anifeedsci.2009.04.008

Samson RA, Mouchacca J. 1975. Two new soil-borne cleistothecial ascomycetes. Can. J. Bot. 53:
1634-1639. https://doi.org/10.1139/b75-194.

Samson RA, Hoekstra E, Frisvad JC, Filtenborg O, eds. 2000. Introduction to food- and
airborne Fungi, 6th ed. Centraalbureau voor Schimmelcultures, Utrecht.

Samson RA, Visagie CM, Houbraken J, Hong SB, Hubka V, Klaassen CH, Perrone G., Seifert KA,
Susca A, Tanney JB, Varga J, Kocsubé S, Szigeti G, Yaguchi T, Frisvad JC. 2014. Phylogeny,
identification and nomenclature of the genus Aspergillus. Stud. Mycol. 78: 141-173.
https://doi.org/10.1016/j.simyco.2014.07.004

Samuels GJ, Petrini O, Kuhls K, Lieckfeldt E, Kubicek CP. 1998. The Hypocrea schweinitzii
complex and Trichoderma sect. Longibrachiatum. Stud. Mycol. 41. 54 p.

Sanchez V, Gonzalez AM, Lura MC. 2006. Analisis microbioldgico de hierbas medicinales y
su contaminacioén por especies de aspergillus toxicogénicos. Acta Farm. Bonaerense 25:
89-94.

Scaramuzza N, Berni E. 2014. Heat-resistance of Hamigera avellanea and Thermoascus
crustaceus isolated from pasteurized acid products. Int. J. Food Microbiol. 168: 63-68.
https://doi.org/10.1016/j.ijfoodmicro.2013.10.007

Schmitt I, Crespo A, Divakar PK, Fankhauser JD, Herman-Sackett E, Kalb K, Nelsen, MP,
Nelson NA, Rivas-Plata E, Shimp AD, Widhelm T, Lumbsch HT. 2009. New primers for
promising single-copy genes in fungal phylogenetics and systematics. Persoonia 23: 35-40.
https://doi.org/10.3767/003158509X470602

Scholte RPM, Samson RA, Dijksterhuis J. 2004. Spoilage fungi in the industrial processing of
food. In: Samson RA, Hoekstra E, Frisvad JC, Filtenborg O (eds) Introduction to Food- and
Airborne Fungi, Utrech.

Septlveda O, Piontelli L. 2005. Poblaciones de Aspergillus en semillas de maiz y soja de
importacién argentina: Enfasis en la seccién Flavi. Boletin Micolégico 20: 41-55.
http://dx.doi.org/10.22370/bolmicol.2005.20.0.276

Splittstoesser DF, Lammers JM, Downing DL, Churey JJ. 1989. Heat resistance
of Eurotium herbariorum, a _ xerophilic mold. J. Food Sci. 54: 683-685.
https://doi-org/10.1111/j.1365-2621.1989.tb04681.x

Stchigel AM. 2000. Estudio taxonédmico de los Ascomycetes del suelo. PhD dissertation,
Universitat Rovira i Virgili. http://tesisenxarxa.net/handle/10803/8735, 04/05/16.

Stolk AC, Samson RA. 1972. The genus Talaromyces: studies on Talaromyces and related genera
II. Stud. Mycol. 2: 1-65.

Tamura K, Stecher G, Peterson D, Filipski A, Kumar S. 2013. MEGA6: molecular evolutionary
genetics analysis version 6.0. Molecular biology and evolution 30: 2725-2729.
https://doi.org/10.1093/molbev/mst197

Thom C, Church MB. 1926. The Aspergilli. Williams and Wilkins Co., Baltimore.

Thom C, Raper KB. 1941. The Aspergillus glaucus group (Vol. 424). US Dept. of Agriculture.

Thompson JD, Higgins DG, Gibson TJ. 1994. CLUSTAL W— improving the sensitivity
of progressive multiple sequence alignment through sequence weighting, position-
specific gap penalties and weight matrix choice. Nucleic Acids Res. 22: 4673-4680.
https://doi.org/10.1093/nar/22.22.4673

558 ... Romero & al.

Turland NJ, Wiersema JH, Barrie FR, Greuter W, Hawksworth DL, Herendeen PS & al. 2018.
International Code of Nomenclature for algae, fungi, and plants (Shenzhen Code) adopted
by the Nineteenth International Botanical Congress, Shenzhen, China, July 2017. Regnum
Vegetabile 159. https://doi.org/10.12705/Code.2018

Warcup JH, Baker KE. 1963. Occurrence of dormant ascospores in soil. Nature 197: 1317-1318.

Winitzky J. 1948. Las especies de Aspergillus en muestras de tierra y aire de la Ciudad de Buenos
Aires. Revista de Investigaciones Agricolas 2: 97-104.

Winitzky J. 1952. Las especies de “Aspergillus” en muestras de tierra y aire de la “Estepa pampeana’.
Revista de Investigaciones Agricolas 5: 303-316.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 559-568
https://doi.org/10.5248/135.559

Cortinarius rapaceoides, a new record for Turkey

MERYEM SENAY SENGUL DEMIRAK * & HAKAN IsIk?

'Department of Molecular Biology and Genetics, Faculty of Arts and Sciences,
Tokat Gaziosmanpasa University, Tasliciftlik Campus, 60250, Tokat, Turkey
?Tokat M. Emin Sarac Anatolian Religious High School, 60030, Tokat, Turkey

*CORRESPONDENCE TO: senay.sengul@gop.edu.tr

ABSTRACT—A macrofungus collected from Akbelen village in Tokat has been identified
based on molecular evidence and morphology as Cortinarius rapaceoides, a new record from
Turkey. Sequence data generated from the nuclear ribosomal internal transcribed spacer
and ribosomal large subunit regions were deposited in GenBank and used to determine
phylogenetic relationships within Cortinarius subg. Phlegmacium. A morphological
description, illustrations, and phylogeny of the Turkish C. rapaceoides are provided.

Key worps—Cortinariaceae, ITS, LSU, taxonomy

Introduction

The ectomycorrhizal basidiomycete genus Cortinarius (Agaricales) is
the world’s most speciose mushroom genus. Ectomycorrhizal associations
formed with trees (e.g., Nothofagus, Quercus, Pinus) and herbaceous plants
are important for forest ecosystem (Moser & Horak 1975, Breitenbach &
Kranzlin 2000, Stensrud & al. 2014, Itoo & al. 2015). Morphological features
such as cortina covering young gills, rusty brown mature gills, ochraceous-
rusty to deep rusty spore print, and bulbous stipe distinguish this genus.
Species separation within Cortinarius is greatly complicated by a high
degree of inter- and intra-specific morphological variation.

Molecular markers have become important in helping resolve and
refine Cortinarius taxonomic classification. Previous studies have used
molecular markers derived from ribosomal gene loci containing the internal

560 ... Sengiil Demirak & Isik

transcribed spacer regions (ITS1 and ITS2), ribosomal large subunit (LSU),
and the two largest subunits of RNA polymerase II (RPB1, RPB2) (Garnica
& al. 2003, 2009; Froslev & al. 2005, 2007; Niskanen & al. 2009; Liimatainen
& Niskanen 2013; Stensrud & al. 2014; Liimatainen & al. 2017; Sesli &
Liimatainen 2018). Among those, ITS data strongly supports phylogenetic
delimitation of species among Cortinarius sections and our understanding
of the evolution of the genus (see Garnica & al. 2009). Most studies stress the
necessity of combining sequence data with morphological studies to resolve
the relationships among Cortinarius species.

Cortinarius species have been previously recorded in Turkey (Sesli &
Denchev 2014; Akata & al. 2015; Giingor & al. 2015; Sesli & al. 2015, 2016;
Sesli 2018; Sesli & Liimatainen 2018; Kalmer & al. 2019). Our research
provides the first identification of C. rapaceoides in Turkey with detailed
description of morphological characteristics and evidence at the molecular
level.

Materials & methods

Morphological studies

Fresh Cortinarius basidiomes were collected from Akbelen village (Tokat) in
the autumn of 2018, photographed in the field, and important morphological and
ecological features noted. Basidiomes were stored in paper bags and kept in a box.
The fresh collection was transported to the laboratory in paper bags, and collection
numbers were assigned. The dried basidiomes were placed into polyethylene bags
for storage. Tissues were mounted in Melzer’s reagent, distilled water, Congo red,
and KOH prior to examination under a light microscope. At least 25 measurements
from each microscopic structure were obtained from a mature basidiome, which
was initially identified based on its morphological features with the help of Boisselet
(2012a) and Tanchaud (2016). The identified collection was deposited in the
Fungarium of the Department of Biology, Tokat Gaziosmanpasa University, Tokat,
Turkey (GOPUF).

Molecular studies

Genomic DNA was extracted from lamella using the ZR Fungal/Bacterial DNA
MiniPrep kit as described by the manufacturer's protocol. The primer pair ITS4-
ITS5 (White & al. 1990) was used to amplify ITS1-5.8S-ITS2 region and the primer
pair LROR-LRS (Vilgalys & Hester 1990) was used to amplify 28S LSU rRNA gene
region. The DNA was amplified in a 30 ul volume mixture containing 3 ul 10X buffer,
3 ul dNTP mix, 3 ul degenerate primer pair (final concentration of 1 uM each), 0.3 ul
Dream Taq DNA polymerase (Thermo), 10 ul gDNA and 7.7 ul sterile ddH,O. PCR
amplification for ITS region was set as: A negative control reaction using only sterile
ddH,O was also run in parallel. 5 min initial denaturation at 95°C + 40 denaturation

Cortinarius rapaceoides new for Turkey ... 561

cycles (95°C for 30 sec) + annealing (53°C for 30 sec) + extension (72°C for 1 min)
and a final extension for 10 min. The LSU PCR protocol comprised: a 3 min initial
denaturation at 95°C + 40 denaturation cycles (95°C for 30 sec) + annealing (48°C
for 30 sec) + extension (72°C for 1 min) and a final extension for 10 min.

PCR products were run in a 1% agarose gel electrophoresis and positive PCR
products were gel purified by using Wizard SV Gel and PCR Clean-up System.
Purified PCR products were sequenced in both directions using the same primer
pairs by BM Labosis Inc. (Ankara).

Sequence and phylogenetic analysis

Chromatograms were checked for any nucleotide errors for each genomic
sequence generated from both ends and errors were corrected manually. Assembled
rDNA sequences were examined using Basic Local Alignment Search Tool (BLAST)
programme to select the most closely related ITS and LSU sequences in the database.
Representative ITS and LSU sequences of Cortinarius species were retrieved from
GenBank for phylogenetic analysis. The sequence alignments and phylogenetic trees
for each genomic region were analysed using MEGA 6.0 (Tamura & al. 2013). In the
CLUSTALW alignment, sequences were trimmed at both ends. Phylogenetic trees
were constructed using the maximum likelihood (ML) and maximum parsimony
(MP) methods. Tamura-Nei model (Tamura & Nei, 1993) was used to construct
the ML tree with bootstrap support of 1000 replicates and default settings. The
bootstrap support values >50% were marked on the branches of the tree.

Taxonomy

Cortinarius rapaceoides Bidaud, G. Riousset & Riousset,
Micologia 2000: 68 (2000) Fic. 1
PitEus 50-100(-120) mm diam., at first convex then plane-convex to
plane; surface dull when dry, lubricous when moist; colour overall yellowish
to ochre-yellow, in the centre orange-yellow with darker brown squamules.
LAMELLAE pale lilac, soon rust-brown, broad, crowded, edges smooth to
slightly crenate. Stipe whitish, sometimes gray-purplish at the apex, fragile,
solid, cylindrical, base with a marginate bulb, surface longitudinally whitish-
fibrillose when young, brownish when old. FLEsH whitish sometimes bluish
in the upper and lower stipe. KOH negative on the flesh, amber yellow colour
on the pileal surface. ODorR of chocolate.
BASIDIOSPORES (9.6—)10-13(-13.8) x (6.0-)6.5-8(-8.5) um, elliptical to
amygdaliform, strongly verrucose, yellow-brown. BasIpIA, (30—)35-40(-44.6) x
(9-)10.5-12(-12.4) um, with 2-4 sterigmata, clavate.

SPECIMENS EXAMINED: TURKEY, TOKAT, Akbelen village, 40°27’0”N 36°39'16’E,
1050 m, among dead leaves of Quercus sp, 8 November 2018, leg. Isik 798 (GOPUF;
GenBank MN094878, MN099705).

562 ... Sengiil Demirak & Isik

Cortinarius rapaceoides new for Turkey ... 563

HABITAT & DISTRIBUTION—Among fallen leaves on calcareous soils in
deciduous woods. Previously recorded from France and Italy (Liimatainen
& al. 2014).

Molecular phylogeny

The ITS1-5.8S-ITS2 (666 bp) and LSU rRNA (996 bp) sequences were
deposited in GenBank. ITS sequence MN094878 BLAST results matched
closely with the sequences representing C. caroviolaceus (EU057049),
C. rapaceoides (KF732407, ex-holotype), and C. saporatus (DQ663413),
which are included in the /Caroviolacei clade (Garnica & al. 2009).
The remaining BLAST hits were also matched with species within the
same clade. Accordingly, 67 sequences in the /Calochroi & Fulvi clade of
Cortinarius subg. Phlegmacium (Liimatainen & al. 2014) were selected and
ITS sequences were retrieved from GenBank for phylogenetic analyses. The
outgroup Cortinarius aureifolius and C. caerulescens were used to root the
phylogeny (Froslev & al. 2005, Garnica & al. 2009).

Although fewer in number, LSU sequences for genus Cortinarius were
also selected to construct a phylogenetic tree, but the LSU-based phylogeny
was not well resolved due to low bootstrap values and no phylogenetic
separation at the subgenus level was observed for LSU regions.

Our two constructed MP and ML phylogenetic trees showed similar
topologies for each genomic region. We present only the ML tree to indicate
phylogenetic relationship of the studied species based on the ITS region.
The sequence from our Cortinarius specimen clustered with sequences
derived from C. rapaceoides described from Italy and France (including
the ex-holotype sequence KF732407) and C. caroviolaceus (EU057049)
from Italy with high bootstrap support (Fic. 2). Liimatainen & al. (2014)
suggested that C. caroviolaceus sequence actually represented C. rapaceoides
based on their ITS sequence phylogeny; and our phylogeny also supports it
as conspecific with C. rapaceoides.

Discussion

Cortinarius rapaceoides, originally described from France and collected
under Quercus ilex in a deciduous forest with calcareous soil, is characterized
by a cream to yellow color, smooth convex pileus with a rolled margin,

Fic. 1. Cortinarius rapaceoides (GOPUF - Isik 798): A. basidiomata; B. basidia and basidioles;
C. basidia; D. basidiospores. Scale bars: A = 3 cm; B-D = 10 um.

564 ... Sengiil Demirak & Isik

cream to purple lamellae, blue, cream or purple colored cylindrical stipe
with a marginate bulb, 10-13 x 6-7 um verrucose spores, and a hardwood
mycorrhizal association (Boisselet 2012a, Tanchaud 2016).

‘The species is morphologically similar to C. aleuriosmus Maire [= C. caro-
violaceus P.D. Orton] and C. saporatus Britzelm. These fungi may be
confused with each other due to their similar ecological features; however,
C. aleuriosmus can be distinguished from C. rapaceoides by its whitish pileus
and lamellae, smaller, almond-to lemon-shaped rough spores, abundant
white veil, and farinaceous taste and odor (Orton 1955, Moser 1983, Phillips
1981, 2013; Boisselet 2012a, 2012b; Tanchaud 2016). Cortinarius saporatus
differs in its bigger pileus and stipe, dark brown colour changes with KOH
on the pileus, its yellowish colour at the stipe base, and an odor that is
initially fruity but later more sour (Phillips 1981, 2013). Although some
spores of Turkish C. rapaceoides are larger, the morphological characters
are very similar and agree with French C. rapaceoides (Boisselet 2012a,
Tanchaud 2016).

Sequence analyses also support identification of Turkish collection as
C. rapaceoides. It belongs in Cortinarius subg. Phlegmacium, a polyphyletic
subgenus (Peintner & al. 2004, Garnica & al. 2005). Although Cortinarius
species are morphologically quite variable, their ITS sequences show a
high sequence identity and are reliably used for species delimitation and
identification (e.g. Froslev & al. 2005, 2007; Ortega & al. 2008; Garnica &
al. 2009; Niskanen & al. 2009). We found the ITS region more useful than
the LSU region for inferring the phylogenetic relationships and were able to
determine independent phylogenetic lineages with high boostrap support.
Our ITS sequence clustered in Cortinarius sect. Calochroi and showed
100% sequence identity with C. rapaceoides from France and Italy without
any intraspecific sequence polymorphisms.

Our first record of C. rapaceoides in Turkey is well supported by both
morphological and molecular evidence.

Acknowledgments
We would like to thank Dr. Ibrahim Turkekul for critically reviewing this article.
We also thank the referees, Drs Abdullah Kaya (Gazi University, Ankara, Turkey)

Fic. 2. Phylogeny of selected Cortinarius species inferred from ITS sequences using the
ML method. The diamond [@] indicates the Turkish C. rapaceoides identified in this study.
Ex-type sequences are annotated with [T]. Cortinarius aureifolius and C. caerulescens represent
the outgroup. Bootstrap support values =>50% from ML analysis are shown on the branches.
Bar = 0.02 expected changes per site per branch.

Cortinarius rapaceoides new for Turkey ... 565

67 Cortinarius caesiocinctus DQ663239 [T]
Cortinarius caesiocinctus DQ663241
63 | Cortinarius cobaltinus KF673472
Cortinarius cobaltinus KF673471
Cortinarius cobaltinus KF673470 [T]
Cortinarius bigelowii KF732265 [T]
97, Cortinarius metarius KF732347 [T]
Cortinarius barbarorum DQ663236
Cortinarius flavipallens KF732554 [T]
Cortinarius olympianus KF732364 [T]
74' Cortinarius olympianus KF732553
99 | Cortinarius sublilacinopes KF732561 [T]
Cortinarius sublilacinopes DQ663434
Cortinarius pseudogracilior KF732394 [T]
Cortinarius calojanthinus KF732272 [T]
73' Cortinarius corrosus DQ663281
Cortinarius arenicola KF732252 [T]
Cortinarius frondosophilus KF732562 [T]
96! Cortinarius platypus KF732563 [T]
Cortinarius magnivelatus EU056976
Cortinarius spectabilis DQ663425
Cortinarius spectabilis DQ663426
99 Cortinarius sannio KF732536
Cortinarius sannio KF732537
76, Cortinarius pseudoglaucopus DQ663395
97| | Cortinarius pseudoglaucopus AY669573
Cortinarius elotoides KF732300 [T]
Cortinarius rapaceoides DQ663417
Cortinarius caroviolaceus EU057049
99| | Cortinarius rapaceoides KF732407 [T]
74 | Cortinarius rapaceoides NR130253
@ Cortinarius rapaceoides MN094878
Cortinarius cacodes KF732270 [T]
80 ; Cortinarius saxamontanus KF732421 [T]
Cortinarius saxamontanus EU057026
Cortinarius cf. aureofulvus KF732544
Cortinarius cf. aureofulvus KF732545
Cortinarius cf. aureofulvus KF732543
Cortinarius sulphurinus var. fageticola DQ663439
: Cortinarius sulphurinus KC842431
Cortinarius sulphurinus DQ663437
Cortinarius luteicolor KF732546
Cortinarius luteicolor KF732547
Cortinarius luteicolor FJ717511
Cortinarius citrinipedes KF732281 [T]
Cortinarius osmophorus DQ663368
Cortinarius evosmus KF732302 [T]
9 Cortinarius osmophorus AY174815
Cortinarius cupreorufus KF732548
Cortinarius cupreorufus KF732549
98 | Cortinarius cupreorufus KF732550
Cortinarius cupreorufus KF732294 [T]
96 Cortinarius flavobulbus EU057017
Cortinarius flavobulbus KF732305 [T]
98 , Cortinarius viridirubescens KF732476 [T]
Cortinarius viridirubescens EU057007
Cortinarius dibaphus DQ663286
79, Cortinarius alnobetulae EU655672
Cortinarius alnobetulae KF732246 [T]
Cortinarius amnicola KF732249 [T]
Cortinarius subpurpureophyllus KF732450 [T]
Cortinarius subpurpureophyllus KF732557
79| Cortinarius napus GU363492
Cortinarius napus KC842428
Cortinarius cf. meinhardii KF732551
96 | Cortinarius meinhardii AY174840
Cortinarius parafulmineus EF014269
99! Cortinarius parafulmineus KF732552 [T]
Cortinarius caerulescens AY174863
Cortinarius aureifolius AF268893

566 ... Sengiil Demirak & Isik

and Yusuf Uzun (Van Yuzuncu Yil University, Turkey), for their helpful comments
and suggestions. We greatly appreciate Dr. Lorelei Norvell’s editorial review and
Dr. Shaun Pennycook’s nomenclatural review.

Literature cited

Akata I, Kabaktepe S, Akgiil H. 2015. Cortinarius caperatus (Pers.) Fr., a new record for
Turkish mycobiota. Kastamonu University Journal of Forestry Faculty 15: 86-89.
https://doi.org/10.17475/kuofd.94670

Boisselet P. 2012a. https://www.mycocharentes.fr/pdf2/8%201152%201%20.pdf (accessed 14
May 2019).

Boisselet P. 2012b. https://www.mycocharentes.fr/pdf2/965.pdf (a ccessed 14 May 2019).

Breitenbach J, Kranzlin F. 2000. Fungi of Switzerland. Vol. 5. Verlag Mykologia, Lucerne,
Switzerland.

Froslev TG, Matheny PB, Hibbett DS. 2005. Lower level relationships in the mushroom
genus Cortinarius (Basidiomycota, Agaricales): a comparison of RPB1, RPB2,
and ITS phylogenies. Molecular Phylogenetics and Evolution 37(2): 602-618.
https://doi.org/10.1016/j.ympev.2005.06.016

Froslev TG, Jeppesen TS, Lzessge T, Kjoller R. 2007. Molecular phylogenetics and delimitation
of species in Cortinarius section Calochroi (Basidiomycota, Agaricales) in Europe. Molecular
Phylogenetics and Evolution 44(1): 217-227. https://doi.org/10.1016/j.ympev.2006.11.013

Garnica S, WeifS M, Oertel B, Oberwinkler F. 2003. Phylogenetic relationships of
European Phlegmacium species (Cortinarius, Agaricales). Mycologia 95(6): 1155-1170.
https://doi.org/10.1080/15572536.2004.11833025

Garnica S, Weif} M, Oertel B, Oberwinkler FE. 2005. A framework for a phylogenetic classification
in the genus Cortinarius (Basidiomycota, Agaricales) derived from morphological and
molecular data. Botany 83(11): 1457-1477. https://doi.org/10.1139/b05-107

Garnica S, Weifs M, Oertel B, Ammirati J, Oberwinkler F. 2009. Phylogenetic relationships in
Cortinarius, section Calochroi, inferred from nuclear DNA sequences. BMC Evolutionary
Biology 9(1): 1. https://doi.org/10.1186/1471-2148-9-1

Gingor H, Solak MS, All H, Isiloglu M, Kalmis E. 2015. New records for Turkey and
contributions to the macrofungal diversity of Isparta Province. Turkish Journal of Botany
39: 867-877. https://dx.doi.org/10.3906/bot- 1406-28

Itoo ZA, Reshi ZA, Basharat Q, Majeed ST, Andrabi KI. 2015. Identification and
characterization of ectomycorrhizal Cortinarius species (Agaricales, Basidiomycetes) from
temperate Kashmir Himalaya, India, by ITS barcoding. Advances in Molecular Biology
2015: 1-9. https://dx.doi.org/10.1155/2015/507684

Kalmer A, Acar I, Dizkiric1 Tekpinar A. 2019. Phylogenetic and taxonomic studies on
Cortinarius caerulescens (Schaeff.) Fr. a new record for Turkish mycota. The Journal of
Fungus 10(1): 8-16. https://doi.org/10.30708mantar.453731

Liimatainen K, Niskanen T. 2013. Cortinarius bovarius (Agaricales), a new species from
western North America. MycoKeys 14: 7-23. https://doi.org/10.3897/mycokeys.7.5182

Liimatainen K, Niskanen T, Dima B, Kytévuori I, Ammirati JF, Froslev TG. 2014.
The largest type study of Agaricales species to date: bringing identification and
nomenclature of Phlegmacium (Cortinarius) into the DNA era. Persoonia 33: 98-140.
https://doi.org/10.3767/003158514X684681

Cortinarius rapaceoides new for Turkey ... 567

Liimatainen K, Carteret X, Dima B, Kytévuori I, Bidaud A, Reumaux P, Niskanen T,
Ammirati JF, Bellanger JM. 2017. Cortinarius section Bicolores and section Saturnini
(Basidiomycota, Agaricales), a morphogenetic overview of European and North American
species. Persoonia 39: 175. https://doi.org/10.3767/persoonia.2017.39.08

Moser M. 1983. Keys to agarics and boleti (Polyporales, Boletales, Agaricales, Russulales).
Stuttgart: Gustav Fischer Verlag.

Moser M, Horak E. 1975: Cortinarius Fr. und nahe verwandte Gattungen in Siidamerika.
Beiheft zur Nova Hedwigia 52. 628 p.

Niskanen T, Kytévuori I, Liimatainen K. 2009. Cortinarius sect. Brunnei (Basidiomycota,
Agaricales) in North Europe. Mycological Research 113(2): 182-206.
https://doi.org/10.1016/j.mycres.2008.10.006

Ortega A, Sudrez-Santiago VN, Reyes JD. 2008. Morphological and ITS identification of
Cortinarius species (section Calochroi) collected in Mediterranean Quercus woodlands.
Fungal Diversity 29: 73-88.

Orton PD. 1955. The genus Cortinarius 1. Myxacium and Phlegmacium. The Naturalist. 1-80,
London, UK.

Peintner U, Moncalvo JM, Vilgalys R. 2004. Toward a better understanding of the infrageneric
relationships in Cortinarius (Agaricales, Basidiomycota). Mycologia 96(5): 1042-1058.
https://doi.org/10.1080/15572536.2005.11832904

Phillips R. 1981. Mushrooms and other fungi of Great Britain and Europe. Pan Books Ltd., London,
WK:

Phillips R. 2013. Mushrooms: a comprehensive guide to mushroom identification. Pan Macmillan.
384 p.

Sesli E, Denchev CM. 2014. Checklists of the myxomycetes, larger ascomycetes, and
larger basidiomycetes in Turkey. 6th edn. 139 p. Mycotaxon Checklists Online,
https://www.mycotaxon.com/resources/checklists/sesli-v106-checklist.pdf [Abstract
Mycotaxon 106: 65-67].

Sesli E, Contu M, Jordi VI, Moreau PA, Battistin E. 2015. Taxonomic studies on some
agaricoid and boletoid fungi of Turkey. Turkish Journal of Botany 39(1): 134-146.
https://doi.org/10.3906/bot- 1403-63

Sesli E, Tiirkekul I, Akata I, Niskanen T. 2016. New records of Basidiomycota from Trabzon,
Tokat, and Istanbul provinces in Turkey. Turkish Journal of Botany 40(5): 531-545.
https://doi.org/10.3906/bot-1601-12

Sesli E. 2018. Cortinarius ve Lyophyllum cinslerine ait yeni kayitlar. Mantar dergisi 9(1): 18-23.
https://doi.org/10.30708/mantar.339707

Sesli E, Liimatainen K. 2018. Cortinarius conicoumbonatus (Cortinarius subgen. Telamonia
sect. Hinnulei): a new species from spruce-beech forests of the East Black Sea Region of
Turkey. Turkish Journal of Botany 42(3): 327-334. https://doi.org/10.3906/bot-1710-8

Stensrud ©, Orr RJS, Reier-Roberg K, Schumacher T, Hgiland K. 2014. Phylogenetic
relationships in Cortinarius with focus on North European species. Karstenia 54: 57-71.
https://doi.org/10.29203/ka.2014.464

Tamura K, Nei M. 1993. Estimation of the number of nucleotide substitutions in the control
region of mitochondrial DNA in humans and chimpanzees. Molecular Biology and
Evolution 10(3): 512-526. https://doi.org/10.1093/oxfordjournals.molbev.a040023

Tamura K, Stecher G, Peterson D, Filipski A, Kumar S. 2013. MEGA6: molecular evolutionary
genetics analysis version 6.0. Molecular Biology and Evolution 30(12): 2725-2729.
https://doi.org/10.1093/molbev/mst197

568 ... Sengiil Demirak & Isik

Tanchaud P. 2016. https://www.mycocharentes.fr/pdf1/1338.pdf (accessed 14 May 2019).

Vilgalys R, Hester M. 1990. Rapid genetic identification and mapping of enzymatically
amplified ribosomal DNA from several Cryptococcus species. Journal of Bacteriology
172(8): 4238-4246. https://doi.org/10.1128/jb.172.8.4238-4246.1990

White TJ, Bruns T, Lee SJ, Taylor J. 1990. Amplification and direct sequencing of fungal
ribosomal RNA genes for phylogenetics. 315-322, in: MA Innis & al. (eds). PCR
protocols: a guide to methods and applications. New York, NY, USA: Academic Press.
https://doi.org/10.1016/B978-0- 12-372 180-8.50042-1

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 569-578
https://doi.org/10.5248/135.569

New records of Toninia from China

CoNGCONG Mi1Ao*', MEIJIE SUN*’,
XIAO ZHANG!, ZHAOJIE REN’, LING Hu?

' Key Laboratory of Plant Stress Research, College of Life Sciences,
Shandong Normal University, Jinan, 250014, P. R. China

? Shandong Museum, Jinan, 250014, P. R. China

3 Institute of Environment and Ecology,
Shandong Normal University, Jinan, 250014, P. R. China

“ CORRESPONDENCE TO: ccmjy123@163.com

ABSTRACT—Four Toninia taxa (T. albilabra, T: poeltii, T. tristis subsp. Arizonica, and T. tristis
subsp. fujikawae) are reported for the first time from China. Descriptions with morphological
and chemical characters and known distribution are given for each taxon. A key to the species
of Toninia s.l. in China is also provided.

KeEyYworps—lichen-forming fungi, Lecanorales, Ramalinaceae, taxonomy

Introduction

Toninia, widely distributed in drought and arid areas, is an important
component of desert lichen communities (Timdal 1991, 2002). The current

delimitation of the genus is based mainly on the features of the asci and
paraphyses (Meijie & al. 2019) and molecular genetic characters (cf. Kistenich
& al. 2018, Ekman 2001, Ekman & al. 2008). Toninia is characterized
by a crustose to squamulose and epruinose to densely pruinose thallus;

lecideine, epruinose to densely pruinose apothecia; dark brown to colourless

hypothecium; usually colourless, grey, green, or brown epihymenium and

exciple that changes colour in K and N; clavate, Biatora-type, 8-spored asci;

and elliptical to spindle-shaped, colourless, 1-8-celled ascospores. Toninia

* ConGCONG Miao & MEWIE SUN contributed equally to this work.

570 ... Miao, Sun & al.

was previously placed in Lecideaceae (Massalongo 1852; Timdal 1991;
Zahlbruckner 1890). With the advent of the molecular age, phylogenetic
analysis of lichens is carried out in combination with their morphological
and anatomical features; currently, Toninia is classified in Ramalinaceae
(Timdal 2002; Ekman 2001).

In this paper we contribute to the knowledge of Toninia in China and
add accurate data for the Lichen Flora of China project by reporting on four
taxa new to the country: T. albilabra, T: poeltii, T: tristis subsp. arizonica and
T: tristis subsp. fujikawae.

Materials & methods

The specimens studied are preserved in the Lichen Section of Botanical
Herbarium, Shandong Normal University, Jinan, China (SDNU) and the
Lichen Herbarium of the Kunming Institute of Botany, Kunming, China
(KUN). The morphological and anatomical characters of the specimens were
examined under a COIC XTL7045B2 stereomicroscope and an Olympus CX41
polarizing microscope. Thallus and medulla were tested with K (a 10% aqueous
KOH solution), Cl (a solution of aqueous NaOCl), and I (Lugol’s iodine) for
identification. Lichen substances were identified using standardized thin
layer chromatography (TLC) techniques with system C (Orange & al. 2010).
Photographs were taken with Olympus SZX16 and BX61 microscope with a
DP72 camera.

Taxonomy

Toninia albilabra (Dufour) H. Olivier, Bull. Géogr. Bot. 21: 196 (1911) Fic. 1

THALLUS squamulose, indeterminate. Squamules <2(-4) mm diam.,
scattered or contiguous to irregularly imbricate, orbicular or sometimes
slightly lobed, weakly concave to weakly convex. Upper side reddish brown,
usually epruinose, shiny, with regular and usually deep fissures in the cortex,
pores and pseudocyphellae absent. Margin partly to entirely white pruinose.
Underside white to pale brown. Algal layer continuous. Lower cortex poorly
developed or absent.

APOTHECIA $1.5(-2.5) mm diam., weakly concave to weakly convex,
usually persistently (but narrowly) marginate, densely white pruinose or
more rarely epruinose. Proper exciple reddish brown throughout or with an
additional grey pigment near the rim, lacking crystals. Hypothecium medium
brown in upper part, pale brown to colourless in lower part. Hymenium 60-70
um high; epithecium grey, K+ violet, N+ violet, containing crystals of calcium
oxalate. Spores broadly to narrowly fusiform, 1-septate, 13.5-22.5 x 3-4 um.

Toninia taxa new for China... 571

aN Baa Dh. fh «
ao iy,
‘ > P

Why

rs

Fic. 1. Toninia albilabra (15-49721 KUN).
A. Thallus; B. Epihymenium; C. Purple K reaction of epihymenium; D. Ascospores.

PYCNIDIA not seen.
CHEMISTRY— Terpenoids detected by TLC.

SPECIMENS EXAMINED—CHINA. TIBET, Baju County, on the way from Bangda
to Bangda Airport, alt. 4129 m, 17 Sep. 2014, Wang Lisong & al. 14-47025 (KUN);
Jiangda County, Tongpu Township, 317 national highway side slope, 31°38’33”N
98°26'10’E, alt. 3940 m, 5 Oct. 2016, Wang Lisong & al. 16-51356 (KUN). YUNNAN,
Zhongdian, Benzilan Town, 28°10.47’N 99°23.01’E, alt. 2115 m, 27 Aug. 2006,
Wang Li Song & al. 06-26674 (KUN); Deqin, Baima Snow Mountain, 28°19.47’N
99°05.13’E, 2 Nov. 2015, alt. 4350 m, Wang Lisong & al. 15-49721 (KUN).
DisTRIBUTION—On rock or soil. Toninia albilabra has been reported in
Europe, North Africa, Macaronesia, and the Middle East (Timdal 1991).

New to China.

COMMENTS— The Chinese material closely matches the previously published
description by Timdal (1991). Toninia albilabra is morphologically similar to
T: sedifolia, which differs mainly by having a smooth upper cortex, a thinner
epinecral layer, and farinose pruina. The white edge of the squamules in

572 ... Miao, Sun & al.

T. sedifolia is caused by pruina on the cortex surface and is not sharply
delimited from the less pruinose inner part of the upper side. The white edge in
T: albilabra, however, is caused by the white medulla being visible outside the
sharply delimited, usually entirely epruinose, upper cortex (Timdal 1991).

Fic. 2. Toninia poeltii (16-53317 KUN).
A. Thallus and apothecia; B. Epihymenium; C. Purple K reaction of epihymenium; D. Ascospores.

Toninia poeltii Timdal, Opera Bot. 110: 85 (1991) Fic. 2

Thallus squamulose, indeterminate. Squamules <1 mm diam. More or
less continuous crust. Upper side dark greyish brown, epruinose, dull, with
a few shallow fissures in the cortex, lacking pores and pseudocyphellae.
Margin concolorous with upper side, epruinose. Upper cortex 30-80 um
thick, lacking crystals. Algal layer continuous. Medulla lacking crystals.
Lower cortex <40 um thick, brown pigment hyphae.

Apothecia <0.8 mm diam., plane and indistinctly marginate when young,
later more or less convex and immarginate, epruinose. Proper exciple
olivaceous green in the rim, colourless in inner part, K+ violet or brown,
N-, lacking crystals. Hypothecium colourless. Hymenium 60-70 um high;

Toninia taxa new for China... 573

epithecium olivaceous green, K+ violet or brown, N-. Spores bacilliform,
often slightly curved, 1-3-septate, 12-21.5 x 4-5 um.

Pycnidia not seen.

CHEMISTRY—Terpenoids detected by TLC.

SPECIMENS EXAMINED—CHINA. TIBET, Mangkang, on the way from Lawushan to
the town of Rumei, alt. 4290 m, 20 Sep. 2016, Wang Lisong & al. 16-53317 (KUN);
Dingri County, Alpine meadow, alt. 5250 m, 22 Aug. 2007, Wang Lisong & al. 07-
28528 (KUN). YUNNAN, Deqin County, Sola Mountain, 28°38.19’N 98°36.30’E, alt.
4800 m, 10 Sep. 2012, Niu Dongling & al. 12-35865 (KUN).

DiIsTRIBUTION—On soil or rock. Reported only in the Himalayas (Timdal
1991). New to China.

COMMENTS— The Chinese material closely matches the previously published
description by Timdal (1991). Toninia poeltii is morphologically similar to
T. squalida (which has not been recorded for China), but differs in having
an olivaceous green, K+ violet/brown, N- pigment in the epithecium and
exciple rim. Toninia poeltii has at most 3-septate spores, but T. squalida has
3-7-septate spores (Timdal 1991).

Toninia tristis subsp. arizonica Timdal, Opera Bot. 110: 112 (1991) Fia. 3
THALLUS squamulose, squamules <6(-8) mm diam., scattered to adjacent,
rounded, bullate but often with an irregular depression. Upper surface
castaneous brown to dark brown, epruinose, dull, smooth in the cortex, lacking
pseudocyphellae. Upper cortex <160 um high, lacking crystals.

APOTHECIA <6 mm diam., plane and weakly convex, distinctly marginate,
epruinose. Proper exciple brown to dark brown, colourless in inner part.
Epithecium brown, partly with a green tinge. Spores simple, narrowly ellipsoid
to fusiform, 8-17 x 4-4.5 um. Orange pigment present in the upper part of the
hypothecium and in the lumina of many paraphyses, asci, and spores; yellow
pigment present in the upper part of the hypothecium.

CHEMISTRY—Terpenoids and fatty acid detected by TLC.

SPECIMENS EXAMINED—CHINA. INNER MONGOLIA, Urad Rear Banner, Huhe
Bash GeTusheng, alt. 1600 m, 19 Aug. 2011, Tong Debao 20123675 (SDNU).
NINGXIA, Jingyuan County, Migang Mountain, alt., 2300 m, 20 Jun. 2011,
Cheng Yuliang 20116001 (SDNU). Sicnuan, Ningnan County, Baihetan Town,
alt. 701 m, 18 Oct. 2013, Wang Lisong & al. 13-39450 (KUN); Jinsha River,
alt. 1550 m, 20 Apr. 2014, Wang Lisong & al. 14-43367 (KUN). TIBET, Naqu
County, 317 country road side slope, alt. 4680 m, 30 Sep. 2016, Wang Lisong
& al. 16-51961 (KUN). YUNNAN, Yunmin County, Jinsha River Valley, alt. 920
m, 27 Nov. 2014, Wang Lisong & al. 14-46464 (KUN); Dongchuan, Sandstone
from Dongchuan to Qiaojia Road, alt. 1080 m 11 May 2017, Wang Lisong & al.
17-55053 (KUN).

574 ... Miao, Sun & al.

Fic. 3 Toninia tristis subsp. arizonica (16-53317 KUN).
A. Thallus; B. Epihymenium; C. Ascus; D. Ascospores.

DISTRIBUTION—On soil. Arizona, USA (Timdal 1991). New to China.

ComMMENTS—The Chinese material closely matches the previously
published description by Timdal (1991). Toninia tristis subsp. arizonica
produces orange asci similar to T! tristis subsp. asiae-centralis, which differs
in having 1-septate spores (Timdal 1991). In its possession of simple spores,
the Chinese material closely matches previously published descriptions
of T. tristis subsp. pseudotabacina, which differs in its absence of orange
pigments (Timdal 1991).

Toninia tristis subsp. fujikawae (M. Satd) Timdal,
Opera Bot. 110: 113 (1991) Fic. 4
Thallus squamulose, squamules <4(-5) mm diam., continuous, bullate,
often forming cushions. Upper side castaneous brown to dark brown,
lacking pseudocyphellae. Margin concolorous with upper side, epruinose.
Upper cortex not containing crystals. Algal layer continuous. Medulla

Toninia taxa new for China... 575

lacking crystals. Lower cortex resembling upper cortex, but stainable layer
often dark reddish brown.

Apothecia <4 mm diam., plane and weakly convex, distinctly marginate,
epruinose, Proper exciple brown to dark brown, colourless in inner part, K-,
N-, lacking crystals. Hypothecium pale brown, 60-70 um high; epithecium
olivaceous green to bright green, K+ violet or brown, N-. Spores simple,
ellipsoid, 7-12 x 3-5 um. Orange and yellow pigments lacking.

CHEMISTRY—Terpenoids and fatty acid detected by TLC.

SPECIMENS EXAMINED—CHINA. SICHUAN, Huili County, Jinsha River, alt. 1550 m, 20
Apr. 2014, Wang Lisong & al. 14-43349; 14-43368 (KUN); TiBET, Wuqi County, next to
the 214 state road, 31°09’51”N 96°37'54’E, alt. 3840 m, 2 Oct. 2016, Wang Lisong & al.
16-51390 (KUN); Baqing County, Laxi village, 317 national road side slope, 31°50’17”N
94°23’24’E, alt. 4180 m, 1 Oct. 2016, Wang Lisong & al. 16-53934 (KUN). YUNNAN,
Luquan County, alt. 2540 m, 19 Apr. 2014, Wang Lisong & al. 14-43234 (KUN);
Deqin County, Benzilan, 28°1135.54”N 99°21’08’E, alt. 2112 m,19 Aug. 2018, Wang
Chunxiao & al. 20180326 (SDNU).

DiIsTRIBUTION—On rock or soil. Japan (Timdal 1991). New to China.

CoMMENTS— Toninia tristis subsp. fujikawae may be confused with T. tristis
subsp. canadensis in having green epithecium, but the latter subspecies has
mainly 1-septate ascospores (Timdal 1991). Although also characterized
by simple spores, T! tristis subsp. arizonica is distinguished by a brown
epithecium (Timdal 2002).

Key to the species of Toninia s.|. in China

Kistenich & al. (2018) place some species below in Thalloidima (T. opuntioides,
T: physaroides, T. sedifolia) or other genera (e.g., T: gobica, T. poeltii). Here we follow
Timdal (1991) and treat all species in Toninia s.1.

ie Thalliis proinose (arinose.or-cranulaty .) wees lie ete scorn ae eels as ae 2
i thallusseprumeseto faintly prtimoses £2 4 5.53 2 5.x Alay ton eschg eo nes oaoraae eget 14
22 Epitheciom: prays PIO NG VAIOlet th. nres WN An Reh cba eieee MO sear ece 2 3
2. Epithecium brown, K+ red, or epithecium dark green to bright green,

Ka, N+ Violet® oes iG cage ee eee! eens Hae bios ate ee ne eae eee 13
SRASGOSPOLeSzat LEASt AN Sep tate’ Seo see Steeirerd aca Shepton agit ree A aoa scl eRe or AR Biss 9s 4
3. ASCOSPOres OU ESeptate®.... oe eck che sah ile eee fend a eee ee Dee eae T. toniniana
A) Aseospotes.maily. s-septater... Strachan s.r tet cc ohne get kes ARS Aen een ct S)
Av Ascosporesiexclusively.lusepiate s+ %. 18 As dchaa sort. Set Ake, BB eee ne: Book 6
5. Ascospores 1-3-septate, 13.5-22.5 3.5-5 UM ..... 2. ce eee ee cece ee T. superioris
5. Ascospores mainly 3-septate, 23.5-33 x 3-4 Um... 6... eee eee eee T. alutacea
6. Thallts pruingse; pruinatarinose® 42.2 oni we ee ne eee sca pet we ee ees Yi

6. Thallus:prutnhose, pruina. granulate) 0-4 iu oh este sict wide SIE Pack andi 10

576 ... Miao, Sun & al.

7. Thallus rosulate, pruina exposed surface of thallus .................... T. candida
7: Thallusnot-rosulate, priuina-patehy.en thallus: ../ 5.2 eee5 an se ee ee 8
SeThalluswvithpsetidocyphellae %) 1.34.0 2048 oer sek bat teed T. physaroides
Sathallusswithout pseudocyphellae ¢ .. GoW akg ete poe he Gear a eS 9
9. Squamules bullate and partly vertically flattened, more or less imbricate,

containing an unknown substance (TLC solvent system C Rf.21) ... T. opuntioides
9. Squamules weakly convex to bullate but not vertically flattened or imbricate; not

containing an unknown substance (TLC solvent system C Rf. 21) ... T. sedifolia
10. Squamules margin usually densely with white pruina ............... T. albilabra
10. Pruina not only on the edge of squamules ............... 00. e eee e eee eee 11
11. Ascosporeés: stall (835-13 4-5: (ith) att we ole PE ee ina eae es T. nordlandica
LL-Ascospores larger(12—24-% 335 punt) ee ge Ae arte papa ah ped eka s Panam aiaite 12
12;-Thallus-rosulate; apothecia S4omime. aoe ky Been ee ae eee T. rosulata
12Atnallasnoetrosulate;apothecia S157 tien. sho: opt Max doar eee T. diffracta
13, Epithecttimred-brown, K+ red) ni. c. gered be Sedo Vee Pes ee ees T. lutosa
13. Epithecium green, K-, N+ purple; ascospores 3-septate ................ T. gobica
14, Thallus epruinose-or slighthypruinose <3 * 2; 2s cajos 53556652 ba Rees oS: 15
WAS. Phalitis<e premise” af Seen. eh Mea ents fein tiis eared Meta Ye tae tae Bae Rwy 17
15. Thallus pale brown; epithecium dark brown ..................... T: sculpturata
15. Thallus of different colour; epithecium not dark brown...................06- 16
16. Thallus crustose; epithecium gray, K+ purple, N+ purple ............. T. pennina
16. Thallus squamulose, epithecium olive green to bright green, K-,

NEF ipurplesascosperes las-sepiate Mg... 2. s Cok ah maker Ges T aromatica
17. Epithecium olive green to bright green, K-, N+ purple ....................04. 18
17. Epithecium red-brown, K+ red; ascospores (1-)7(-9) -septate ........ T. ruginosa
18. ‘thallus :crustose:ascospores-luseptate: +... nee Be ee ee T. philippea
18. Thallus squamulose, or crustose to subsquamulose ............... 22.0020 eee 19
19. Thallus crustose to subsquamulose; epithecium olive green;

ASCOSPOLES 3S + SCWUALE ac iso's, ote Cecio E es Shope Mites) oot ew Aten Lane T. coelestina
19. Thallus squamulose; epithecium olive green to bright green .................. 20
20. Ascospores simple to 1-septate; epithecium bright green to dark brown .. T. tristis
20. Ascospores 1 to more septate; epithecium olivaceous to bright green .......... 21
21. Epithecium olivaceous to bright green (K-),

ascospores 1(—3)=septate s..sess02. Gs vas tees ee seee tom euesnes T’ cinereovirens
21. Epithecium olivaceous (K+ purple to brown), ascospores 1-(-3)-septate ... T. poeltii

Key to the subspecies of Toninia tristis

Ik -ASCUSIOLAM OC GE PEGE tote Metta totale Stas Phas Ue BRR OR MRE 51 .C cea ale Geet ah IRE se aE CP 2
LPASCUSHIO LOPAN CGPI oh aa. ov hge bers tee OS Sane Makes: Sng shne tees hy SMe Pa hah Sr cots 3

Toninia taxa new for China... 577

Zi ASCOSPOLeS L-SEPtate,. shea srs oihtetier as map Ue eleye a! ath wen odes subsp. asiae-centralis
D SASEOSPOLES SUN pLeT ae. Y ye rik. toree 4g. C28 Se he sees eee oe ates subsp. arizonica
J MEpit DE CWT AO FEEN Bc i at Te rguee eet Siete Ay eee See a ON dan ee Ue as 4
Deve PIC Ve CAUTION TA. ta heel = Leche iay ens coisas eater os bSK oheaeraaih sant Tae Males SEA» ene Ns nce 7
At ASCOSPOLES. Ue SEDIALE bo ah cttlaliee ek SAP ace te Sethe 8 PeRSO Nees, Lei bee We. /e SG subsp. canadensis
Al PASCOS POLES SLIP agen give eo trend rer ase he ape te, ates Pe SE AR MB Cha 5
5, sxscospores largerd OES 5: WIT) tena Ms es anos Nae es subsp. pseudotabacina
d. Ascosporesismall(Sa12-Minn): Wier ics kone. nee oe es ae eRe nee «Ae 6
G. No, chemical substance Ss. s.enzo se Seo ook oR a at. Seek oe subsp. thalloedaemiformis
6: Containine-chemical substance: e's ont ee hg ete co eons ie subsp. fujikawae
FacNSCOSPOTES STAPLE Maes 42h. harks tee agers ten Saitek a GME e eke. aah subsp. scholanderi
7, EXSCOS POLES! | -SEPTAte a eo ule satan, sleet ics, as telns a edz “niet Beles ase, hn 0 Dhow de onde Gaagaet 8
Se OGM ATMS Se NCO IN TaNaIN 81a: PS Rt a ec dT es aT MI otc tetne dd tay tla subsp. tristis
8. Squamules <3(—4) mim! ps esas Feec dw ead Gee eee awa ee eee ae subsp. coahuilae

Acknowledgments

We thank Dr Edit Farkas (MTA Centre for Ecological Research, Vacratot,
Hungary) and Dr Shou-Yu Guo (State Key Laboratory of Mycology, Institute of
Microbiology, Chinese Academy of Sciences, Beijing, China) for presubmission
review. The authors would also like to thank Lisong Wang and Xinyu Wang
(Kunming Institute of Botany, CAS, China) for assistance during this study. This
work was supported by the Emergency Management Project of National Natural
Science Foundation of China (31750001), the National Natural Science Foundation
of China (31900010).

Literature cited

Ekman S. 2001. Molecular phylogeny of the Bacidiaceae (Lecanorales, lichenized Ascomycota).
Mycological Research 105(7): 783-797. https://doi.org/10.1017/s0953756201004269

Ekman S, Andersen HL, Wedin M. 2008. The limitations of ancestral state reconstruction and the
evolution of the ascus in the Lecanorales (lichenized Ascomycota). Systematic Biology 57(1):
141-156. https://doi.org/10.1080/10635150801910451

Kistenich S, Timdal E, Bendiksby M, Ekman S. 2018. Molecular systematics and character
evolution in the lichen family Ramalinaceae (Ascomycota: Lecanorales). Taxon 67(5):
871-904. https://doi.org/10.12705/675.1

Massalongo AB. 1852. Ricerche sull’autonomia dei licheni crostosi. Verona.

Orange A, James PW, White FJ. 2010. Microchemical methods for the identification of lichens.
2nd edition. London, British Lichen Society.

Scopoli JA. 1760. Flora carniolica. Wien, Sumptibus Joannis Thomae Trattner.

Scopoli JA. 1772. Flora carniolica, ed. 2. Tom. 2. Wien, Impensis Ioannis Pauli Krauss.

Sun MJ, Yan SK, Tang R, Wang CX, Zhang LL. 2019. New records of Bilimbia and Toninia from
China. Mycotaxon. 134: 139-146. https://doi.org/10.5248/134.139

578 ... Miao, Sun & al.

Timdal E. 1991. A monograph of the genus Toninia (Lecideaceae, Ascomycetes). Opera Botanica
110. 137 p.

Timdal E. 2002. Toninia. 488-501, in: TH Nash & al. (eds). Lichen Flora of the Greater Sonoran
Desert Region. Vol. 1. Tempe, Lichens Unlimited, Arizona State University.

Zahlbruckner A. 1890. Prodromus einer Flechtenflora Bosniens. Annalen des Kaiserlich-
K6niglichen Naturhistorischen Hofmuseums, Wien 5: 20-48.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 579-587
https://doi.org/10.5248/135.579

Serendipita sacchari sp. nov.
from a sugarcane rhizosphere in southern China

LING XIE?*, YAN- YAN LONG?”*, YAN ZHANG’”,
YAN-Lu CHEN’”, WEN-LONG ZHANG?*

'Plant Protection Research Institute, Guangxi Academy of Agricultural Science,
Nanning 530007, China

? Microbiology Research Institute, Guangxi Academy of Agricultural Science,
Nanning 530007, China

*CORRESPONDENCE TO: chris1933@126.com

ABSTRACT—We isolated a new species, proposed here as Serendipita sacchari, from a
sugarcane rhizosphere in Guangxi Province, China. This species is characterized by its
unstable nucleus numbers (1-15) in its chlamydospores versus their regular distribution in
hyphal cells. ITS rDNA and combined LSU+ TEFl-a sequence analyses also support the
uniqueness of this new plant symbiont.

Key worps—molecular phylogeny, Sebacinales, Serendipitaceae, taxonomy

Introduction

Serendipita P. Roberts (Basidiomycota, Sebacinales, Serendipitaceae), typified
with S. vermifera (Oberw.) P. Roberts, originally comprised seven species
(Roberts 1993). Two additional new species S. lyrica Trichiés (Trichiés 2003),
and S. herbamans K. Riess & al. (Riess & al. 2014) have been proposed in this
genus, and two anamorphic species in Piriformospora Sav. Verma & al. have
been recombined as S. indica (Sav. Verma & al.) M. Weiss & al., and S. williamsii
(Zuccaro & M. Weiss) M. Weiss & al. (Verma & al. 1998; Basiewicz & al. 2012;
WeifS & al. 2016). Serendipita currently contains 11 species and DNA barcodes
are widely accepted as an important tool in delineating species (Schoch & al.
2012; Riess & al. 2014).

* LING XIE & YAN-YAN LonG contributed equally to this work.

580 ... Xie, Long & al.

During an investigation of plant endophytes in sugarcane rhizosphere in
Guangxi Province, China, an interesting strain has been morphologically and
phylogenetically confirmed as a new species of Serendipita and is described
herein.

Materials & methods

Soil samples were collected from a 5-15-cm sugarcane rhizosphere layer
in Tanluo Town, Nanning City, Guangxi Province, China, in Feb 2011. Fungal
isolates were obtained by baiting with Chinese cabbage as described by Narisawa
& al. (1998), cultured on PDA media, and deposited in the China General
Microbiological Culture Collection Center (CGMCC3.19906). A pure culture of
the fungus was air-dried and frozen to prepare the holotype specimen, which is
curated in the Mycological Herbarium, Institute of Microbiology, Chinese Academy
of Sciences, Beijing, China (HMAS). Observations and measurements were made
with an Olympus BX53 Ci-L light microscope and Tescan-vega3 LMU scanning
electron microscope (SEM).

DNA extraction, amplification, sequencing

Genomic DNA was extracted using the Sangon Biotech Rapid Fungi Genomic
DNA Isolation Kit from mycelia grown at 28 °C for 10 d on oatmeal medium
(OA, 10 g oatmeal, 10 g bacto agar, 1 g MgSO,e7H,O, 1.5 g H,PO,, 1 g NaNO,,
for 1 L distilled water). The internal transcribed spacer of ribosomal DNA (ITS
rDNA), large subunit of ribosomal DNA (LSU), and translation elongation factor
1-a (TEF1-a) were amplified with fungal specific primer pairs ITS1/ITS4, LROR/
LRS, and EF1-983f/EF1-2218r1, respectively (Vilgalys & Hester 1990, Basiewicz & al.
2012). PCR reaction mixture and conditions followed the protocol of 2xEasyTaq
PCR SuperMix. The DNA was amplified in 50 uL volumes containing PCR buffer
[20 mM KCl, 10 mM (NH,),SO,, 2 mM MgCl , 20 mM Tris-HCl, pH8.4], 200 uM
of each dNTP, 15 pmol of each primer, 100 ng DNA template, and 2.5 units of Taq
DNA polymerase (Biocolor BioScience & Technology). Thermal cycling began with
5 min of denaturation at 94 °C, followed by a 35 cycles of denaturation (94 °C for
40 s) + annealing (56 °C for 40 s) + extension (72°C for 60 s), and finalized with
a final extension at 72 °C for 10 min. A negative control using sterilized distilled
water instead of template DNA was included in the amplification process. The
PCR products were examined by electrophoresis at 75 V for 2 h in 0.8 % (W/V)
agarose gel in 1xTAE buffer (0.4 M Tris, 50 mM NaOAc, 10 mM EDTA, pH 7.8)
and visualized under an ultraviolet light after staining with ethidium bromide (0.5
ug mL). The PCR products were purified using MultiScreen® PCRw96 Cleanup
Filter Plates according to the manufacturer’s protocol. Purified PCR products were
directly sequenced with primer pairs mentioned above in an ABI 3730-XL DNA
sequencer. The sequences were deposited at GenBank (http://www.ncbi.nlm.nih.
gov) and compared through a BLAST search.

Serendipita sacchari sp. nov. (China) ... 581

TABLE 1. Taxa with GenBank ITS accession numbers

SPECIES VOUCHER GENBANK NO.
Cantharellus avellaneus 1217/ER KX857081
Chaetospermum camelliae MFLUCC12-0433 KF516965
C. chaetosporum CBS:154.59[T] KJ710461
Craterocolla cerasi TUB 020203 KF061265
Ditangium altaicum LE 231836 [T] NR 163760
Efibulobasidium albescens — AF384860
Globulisebacina rolleyi — AY509550
Helvellosebacina concrescens TUB 019706 JQ665516
H. helvelloides TUB 019983 KF000415
Paulisebacina allantoidea — AF490396
RoKi 179 KF061266
Sebacina candida TUB 020331 KF061278
S. pallida TUB 019650 JQ665562
Serendipita herbamans S1[T] KF061285
S. indica DSM 11827[T] KF061284
S. sacchari CGMCC3.19906 [T] KY496808
S. williamsii DAR 29830 KY509323
Tremellodendron ocreatum TH8577 KT339265
Tremelloscypha dichroa VB4212 KF061281

TABLE 2. Taxa with GenBank LSU and TEF1-a accession numbers

GENBANK NO.

SPECIES VOUCHER LSU TEF1-a
Serendipita. indica DSMZ 11827[T] AY505557 AJ249911
S. sacchari CGMCC3.19906 [T] KY496809 MF196313
S. vermifera MAFF 305835 DQ983814 JN211111
MAFF 305838 DQ983816 JN211116
MAFF 305828 DQ520096 JN211115
S. williamsii DAR 29830 AY505556 JN211110

Phylogenetic analyses

The three DNA loci were separately aligned using Clustal-X (1.83). Two
neighbour-joining trees were derived from ITS1-5.8S-ITS2 and the combined
LSU+ TEF1-a datasets using MEGA v. 4 (Tamura & al. 2007)(TABLES 1,2; Fics 2,3).

Bayesian analyses of the aligned DNA sequence dataset were conducted with
MrBayes v. 3.1.2 (Huelsenbeck & Ronquist 2001) following Sun & Guo (2010). The
best-fit evolutionary model was determined for each dataset by comparing different
evolutionary models via MrModeltest v. 2.3 (Nylander 2008). Four simultaneous
Markov Chain Monte Carlo chains were run by starting from random trees and
sampling every 100 generations. The analyses were halted at 4,000,000 generations
after the calculation reached stationarity. Of the 40,000 trees generated, 25% were

582 ... Xie, Long & al.

excluded as “burn in” when calculating the posterior probabilities. Bayesian posterior
probabilities were obtained from the remaining 50% majority rule consensus trees.
Significant support was defined by clades contained in >95% of the sampled trees.

Taxonomy

Serendipita sacchari L. Xie, Y.Y. Long & Y.L. Chen, sp. nov. Fig. 1
MB 836761
Differs from other Serendipita species by its variable nucleus numbers (1-15 nuclei) in

the chlamydospore cells.

Type: China. Guangxi Province: Nanning City, Tanluo Town, in sugarcane rhizosphere,
22°55’30"N 107°58’34’E, alt. 96 m, Apr. 2011 (holotype, HMAS 247074; ex-type culture
CGMCC3.19906; GenBank KY496808, KY496809, MF196313).

EtryMo.oey: sacchari, referring to the plant from whose rhizosphere the species was

first collected.
Colonies reaching 50 mm in diam on PDA medium at 28 °C after 2 weeks, light
yellow, circular (or nearly circular), less aerial hyphae. Hyphae hyaline to light
yellow-green, septate, 1.2-3.4 um (2.2 + 0.5 um, n = 50), each cell regularly
containing 1-2 nuclei. Chlamydospores abundant, spherical to pear-shaped,
singly on top of hypha, aseptate. Spores 11.1-17.6 um (13.5 + 1.3 um, n = 55)
in diameter, variably containing 1-15 nuclei. Neither conidiophores nor sexual
structures observed.

Sequences & the phylogenetic analyses

The obtained ITS (610 bp), LSU (945 bp), and TEF1-a (1131 bp) sequences
were deposited in GenBank. To determine the phylogenetic position of
Serendipita sacchari, all available ITS, LSU, and TEFl-a sequences from
Serendipita and related genera were downloaded from GenBank (TABLES
12s

The ITS sequences from one isolate of Serendipita sacchari, five
Serendipitaceae, nine Sebacinaceae, three Sebacinales incertae sedis, and
one outgroup Cantharellus avellaneus, were included in the phylogenetic
analysis. In the alignment of these 19 sequences, the data matrix comprised
591 characters. The alignment dataset was analyzed using MrBayes, applying
the GTR+G model selected by MrModeltest as the best-fit model. The
prior probability density is a flat Dirichlet (all values = 278 1.0) with both
Revmatpr and Statefreqpr as default settings. Posterior probability (BPP)
and bootstrap (BS) values are shown on the branches of the ITS Bayesian
tree (Fic. 2). The ITS phylogeny places S. sacchari in Serendipitaceae and in
a clade with S. indica (BPP = 0.83; NJ support = 97%).

Serendipita sacchari sp. nov. (China) ... 583

Fic. 1. Serendipita sacchari (ex-type, CGMCC3.19906). A: Colony; B, C: Bright field microscopic
image of chlamydospores; D-F: Scanning electron microscopic image of chlamydospores;
G, H: DAPI-stained chlamydospores; I: DAPI-stained hyphae. Scale bars: B-I = 10 um.

A combined LSU+TEF1-a dataset comprising one Serendipita sacchari
isolate, five Serendipita isolates, and the outgroup Sebacina incrustans was
included in a second phylogenetic analysis. These seven sequence pairs
(LSU+TEF1-a) aligned in a 1990-character data matrix. The alignment
dataset was analyzed in MrBayes, applying the GTR+G model selected
by MrModeltest as the best-fit model. The prior probability density is a
flat Dirichlet (all values = 278 1.0) with both Revmatpr and Statefreqpr as
default settings. Here also BPP and BS values are shown on the branches of
the combined Bayesian tree (Fic. 3).

584 ... Xie, Long & al.

Sebacina pallida JQ665562

0.86/88

0.97/81 | Tremelloscypha dichroa KF061281
Sebacina candida KF061278

0.89/* . :
1.00/100 Helvellosebacina concrescens JQ665516

0.90/*
0.85/*

Helvellosebacina helvelloides KF000415 :
Sebacinaceae

Tremellodendron ocreatum KT339265

)-S1/* 4 men
ee Globulisebacina rolleyi AY 509550
0.94/100 Craterocolla cerasi KF061265

Ditangium altaicum NR 163760

Paulisebacina allantoidea AF490396

1.00/100

0.97/99 Paulisebacina allantoidea KF061266

Serendipita herbamans KF061285
aT / . Serendipitaceae
Serendipita sacchari KY 496808

0.83/97

Serendipita indica KF061284

1.00/100
Serendipita williamsii KY 509323

0.56/* Chaetospermum chaetosporum KJ710461

0.80/88 Efibulobasidium albescens AF384860

Sebacinales incertae sedis
Chaetospermum camelliae KF516965

Cantharellus avellaneus KX857081

OL

Fic. 2. Phylogenetic tree based on ITS sequences of Serendipita and related Sebacinales species.
Cantharellus avellaneus was included as outgroup. The numbers at each branch represented
Bayesian posterior probabilities (left) and bootstrap support calculated from 1000 replicates (right).
The sequence derived from the proposed new species is in bold. Bar = 0.1 expected changes per site.

In the LSU+TEF1-a phylotree, S. sacchari formed a clade with S. williamsii
with 0.95 BPP support and 100% NJ support. A comparison of the ITS,
LSU and, TEFl-a sequence dataset indicates that S. sacchari differs from
S. williamsii in 12/530 bp (2.3%, ITS), 15/930 bp (1.6%, LSU), and 60/1068
bp (5.6%, TEF1-a); and from S. indica in 22/552 bp (4.0%, ITS), 21/938 bp
(2.2%, LSU), and 63/1132 bp (5.6%, TEF1-a).

COMMENTS. Four species in Serendipita—S. herbamans, S. indica, S. williamsii,
and S. vermifera—were closely related to and allied with S. sacchari.
Neither conidiophores nor sexual structures were observed in these four
taxa. Serendipita sacchari can be easily distinguished from S. herbamans

Serendipita sacchari sp. nov. (China) ... 585

Serendipita vermifera DQ983814+JN2 11111

Serendipita vermifera DQ983816+JN211116

Serendipita vermifera DQ520096+JN2 11115

Serendipita sacchari KY 496809+MF196313

Serendipita williamsti AY 505556+JN2 11110

1.00/100

Serendipita indica AY 505557+AJ2499 11

Sebacina incrustans FJ6445 13+KF3 13907

Q.']

Fic. 3. Phylogenetic tree based on the combined LSU+TEF 1-a sequence data of Serendipita species.
Sebacina incrustans was designated as outgroup. The numbers at each branch point represented
Bayesian posterior probabilities (left) and bootstrap support calculated from 1000 replicates (right).
The sequence derived from the proposed new species is in bold. Bar = 0.1 expected changes per site.

and S. vermifera by its bigger (11.1-17.6 um diam.) chlamydospores (3-5
um x 4-5 um in S. herbamans; approximately 8 um diam. in S. vermifera;
Riess & al. 2014, Ray & Craven 2016). The main difference among
S. sacchari, S. indica, and S. williamsii is the distribution and number of nuclei
in the cells (Basiewicz & al. 2012). Nuclear number in the chlamydospores
of Serendipita sacchari (1-15 nuclei) distinguishes the new species from
S. indica (8-25 nuclei) and S. williamsii (<10 nuclei) (Basiewicz & al. 2012).
Moreover, hyphal cells of S. sacchari have fewer nuclei and exhibit a more
regular distribution compared with S. williamsii (2-6 nuclei irregularly
distributed) (Verma & al. 1998; Basiewicz & al. 2012). Morphological traits
and phylogenetic data both support the recognition of Serendipita sacchari
as an independent species.

Serendipita herbamans is a common species in plant roots and widely
distributed across agricultural and grassland ecosystems. It has the potential
to promote the growth of herbaceous plants (Riess & al. 2014). Serendipita

586 ... Xie, Long & al.

indica (= Piriformospora indica) is widely distributed and well known as
a symptomless root endophyte that colonizes bryophytes, pteridophytes,
gymnosperms and angiosperms. It has been reported to occur in four
continents, is extremely versatile in its mycorrhizal associations, and
is known for its ability to promote plant growth (Varma & al. 2012).
Serendipita williamsii (= Piriformospora williamsii) was isolated from the
spore of arbuscular mycorrhizal fungal in Australia (Basiewicz & al. 2012).
Serendipita vermifera was isolated from the Australian orchid Cyrtostylis
reniformis (Warcup 1988). It is reported to induce beneficial effects on plant
performance including growth promotion, increase nutrient uptake, enhance
seed production, and increase resistance against different biotic and abiotic
stresses (Ray & Craven 2016). Serendipita sacchari was from sugarcane
rhizosphere soil, and symbiotic with Chinese cabbage and sugarcane as a
symptomless root endophyte (data not shown). All five Serendipita species
are plant symbiotic microbionts.

Acknowledgements

This work was supported by the National Natural Science Foundation of China
(No. 31460016), Guangxi Natural Science Foundation (No. 2015GXNSFBA139083),
and Basic Scientific Research Special Project of Guangxi Academy of Agricultural
Sciences (No. 2015YT80). We appreciate the thoughtful reviews of Dr. Xiaoyong Liu
(Institute of Microbiology, Chinese Academy of Sciences) and Dr. Jiwen Xia (College
of Plant Protection, Shandong Agricultural University).

Literature cited

Basiewicz M, WeifS M, Kogel KH, Langen G, Zorn H, Zuccaro A. 2012. Molecular and
phenotypic characterization of Sebacina vermifera strains associated with orchids,
and the description of Piriformospora williamsii sp. nov. Fungal Biology 116: 204-213.
https://doi.org/10.1016/j.funbio.2011.11.003

Huelsenbeck JP, Ronquist E 2001. MRBAYES: Bayesian inference of phylogeny trees.
Bioinformatics 17: 754-755. https://doi.org/10.1093/bioinformatics/17.8.754

Narisawa K, Tokumasu S, Hashiba T. 1998. Suppression of clubroot formation in Chinese
cabbage by the root endophytic fungus, Heteroconium chaetospira. Plant Pathology 47:
206-210. https:// doi.org/10.1046/j.1365-3059.1998.00225.x

Nylander JAA. 2008. MrModeltest 2.3 REAME. Accessed 22 May 2008:
http://www.abc.se/nylander/mrmodeltest2/mrmodeltest2.html.

Ray P, Craven KD. 2016. Sebacina vermifera: a unique root symbiont with vast agronomic
potential. World Journal of Microbiology & Biotechnology 32: 1-10.
https://doi.org/10.1007/s11274-015-1970-7

Riess K, Oberwinkler F, Bauer R, Garnica S. 2014. Communities of endophytic Sebacinales
associated with roots of herbaceous plants in agricultural and grassland ecosystems are
dominated by Serendipita herbamans sp. nov. Plos One 9:
e94676. https://doi.org/10.1371/journal.pone.0094676

Serendipita sacchari sp. nov. (China) ... 587

Roberts P. 1993. Exidiopsis species from Devon, including the new segregate genera
Ceratosebacina, Endoperplexa, Microsebacina, and Serendipita. Mycological Research 97:
467-478. https://doi.org/10.1016/S0953-7562(09)80135-4

Schoch CL, Seifert KA, Huhndorf S, Robert V, Spouge JL, Levesque CA, Chen W & al. 2012.
Nuclear ribosomal internal transcribed spacer (ITS) region as a universal DNA barcode
marker for Fungi. Proceedings of the National Academy of Sciences, USA 109: 6241-6246.
https://doi.org/10.1073/pnas.1117018109

Sun X, Guo LD. 2010. Micronematobotrys, a new genus and its phylogenetic placement based
on rDNA sequence analyses. Mycological Progress 9: 567-574.
https://doi.org/10.1007/s11557-010-0664-7

Tamura K, Dudley J, Nei M, Kumar S. 2007. MEGA4: molecular evolutionary genetics
analysis (MEGA) software version 4.0. Molecular Biology and Evolution 24: 1596-1599.
https://doi.org/10.1093/molbev/msm092

Trichiés G. 2003. Serendipita lyrica sp. nov., Achroomyces lotharingus sp. nov. et quelques
autres hétérobasidiés notables de Lorraine (France). Bulletin trimestriel de la Société 118
(4): 351-379.

Verma A, Varma S, Rexer KH, Hassel A, Kost G, Sarbhoy A, Bisen P, Bittehorn B, Franken
P. 1998. Serendipita indica, gen. et sp. nov., a new root-colonizing fungus. Mycologia 90:
896-903. https://doi.org/10.2307/3761331

Varma A, Bakshi M, Luo B, Hartmann A, Oelmueller R. 2012. Serendipita indica: a novel
plant growth-promoting mycorrhizal fungus. Agricultural Research 1: 117-131.
https://doi.org/10.1007/s40003-012-0019-5

Vilgalys R, Hester M. 1990. Rapid genetic identification and mapping of enzymatically
amplified ribosomal DNA from several Cryptococcus species. Journal of Bacteriology 172:
4238-4246.

Vohnik M, Panek M, Fehrer J, Selosse MA. 2016. Experimental evidence of ericoid
mycorrhizal potential within Serendipitaceae (Sebacinales). Mycorrhiza 26: 831-846.
https://doi.org/10.1007/s00572-016-0717-0

Warcup JH. 1988. Mycorrhizal associations of isolates of Sebacina vermifera. New Phytologist
110: 227-231. https://doi.org/10.1111/j.1469-8137.1988.tb00256.x

WeifS M, Waller F, Zuccaro A, Selosse MA. 2016. Sebacinales - one thousand and one
interactions with land plants. New Phytologist 211: 20-40.
https://doi.org/10.1111/nph.13977

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 589-612
https://doi.org/10.5248/135.589

Five Nolanea spp. nov. from Brazil

FERNANDA KARSTEDT*, SARAH E. BERGEMANN?, MARINA CAPELARI’

* Nucleo de Pesquisa em Micologia, Instituto de Botanica,
Caixa Postal 68041, 04045-902 Sao Paulo, SP, Brazil

* Biology Department, Middle Tennessee State University,
PO Box 60, Murfreesboro, TN 37132, USA

" CORRESPONDENCE TO: fernanda.karstedt@gmail.com

ABSTRACT—Five new species of Nolanea (Entolomataceae, Agaricales)—N. albertinae,
N. atropapillata, N. pallidosalmonea, N. parvispora, and N. tricholomatoidea—were
collected from the Sao Paulo metropolitan region. Phylogenetic analyses based on partial
sequences of the mitochondrial small subunit (mtSSU), nuclear large subunit (nLSU)
and second largest RNA polymerase subunit (rpb2), confirm that all these species belong
to Nolanea. Morphological descriptions, comments, illustrations, scanning electron
microscopy and color photos are included.

Key worps—basidiomycetes, Entoloma, Neotropical fungi, South America, taxonomy

Introduction

Currently, Nolanea has two main circumscriptions, one according to
Largent (1994) and Henkel & al. (2014) as Nolanea (Fr.) P. Kumm., and the
other according to Noordeloos (1992, 2004) and Noordeloos & Gates (2012)
as Entoloma subg. Nolanea (Fr.) Noordel. Both circumscriptions agree that
Nolanea comprises species often mycenoid with the pileus surface typically
hygrophanous, usually translucent-striate and with angled basidiospores
with five, six or seven angles in profile view, which can be subisodiametric or
heterodiametric. The main difference between the accepted circumscriptions
of the genus Nolanea is in the pileipellis structure. Largent (1994) considers
Nolanea to encompass only species that have a pileipellis composed of two
layers, with a suprapellis composed of a cutis or a repent entangled hyphae

590 ... Karstedt, Bergemann, Capelari

layer overlying a subpellis of inflated hyphae, whereas Noordeloos accepts
species in Entoloma subg. Nolanea in which the repent, cylindrical hyphae of
the pileipellis often (but not necessarily always) overlie a distinct differentiated
subpellis of inflated cells.

In general, the few phylogenetic studies that include Nolanea species
do not define which circumscription is the most appropriate for the group;
additionally, they suggest Nolanea can be polyphyletic (Co-David & al. 2009,
Baroni & Matheny 2011). However, Nolanea species are always in the Nolanea-
Claudopus clade, independent of the combination of loci used: mtSSU, nLSU,
and rpb2 (Co-David & al. 2009, Baroni & Matheny 2011) or ITS, nLSU, and
rpb2 (Kinoshita & al. 2012). Also, it is usually possible to visualize two separate
branches within the Nolanea—Claudopus clade, with a clade of Nolanea species
separate from a clade comprising Claudopus species.

More recent molecular studies of Entoloma subg. Nolanea (Vila & al. 2013,
Raj & al. 2014, Raj & Manimohan 2016) examined Nolanea species using
only ITS sequences, with special emphasis on taxa delimitation and new taxa
proposition. The phylogeny produced in these studies supports, even with only
ITS sequences, the recognition of Nolanea as a good phylogenetic group and
would seem to support Nolanea as an autonomous genus in the Entolomataceae.

Nolanea (with about 250 names in MycoBank and Index Fungorum) is
considered a common and speciose genus, especially in temperate regions
(Noordeloos 1992, 2004, Largent 1994, Horak 2008), but it is also present in
tropical and subtropical regions (Romagnesi & Giles 1979). In Brazil of the 23
Nolanea species recorded (Rick 1919, 1920, 1930, 1961, Bresadola 1920, Singer
1953, Horak 1977, Capelari 1989, Putzke & Cavalcanti 1997, Pegler 1997, de
Meijer 2001, 2006, Rosa 2002), eleven have been cited and/or described by
Rick (1919, 1920, 1930, 1961, Singer 1953) and are considered as incertae sedis
(Horak 1977). Many other species have been reported in dissertations (Capelari
1989, Rosa 2002), an identification key (Pegler 1997), and lists (Singer 1953, de
Meijer 2001, 2006), but only three have been published with a full description
(Putzke & Cavalcanti 1997).

In this work, we describe five new species found in the Sao Paulo metropolitan
region accompanied by molecular information and phylogenetic analyses.

Materials & methods

Basidiomata collection and morphological observations
The studied materials were collected mainly at the Parque Estadual da Cantareira
and the Parque Estadual das Fontes do Ipiranga in Sao Paulo City and Reserva

TABLE I. Collections used in the phylogenetic analyses
Cl. = Claudopus; E. = Entoloma; I. = Inocephalus; L. = Leptonia; P. = Pouzarella;

Nolanea spp. nov. (Brazil) ... 591

Rh. = Rhodocybe; R. = Richoniella; T. = Trichopilus; Sequences generated in this study in bold.

NCBI spECIES NAME

Cl. minutoincanus

Cl. viscosus

E. abortivum

E. albidoquadratum
E. bloxamii

E. cephalotrichum
E. conferendum

E. cf. conferendum
E. gasteromycetoides

E. haastii
E. hebes

E. nidorosum

E. pallideradicatum
E. parasiticum

E. porphyrescens

E. procerum

E. pygmaeopapillatum
Entoloma readiae

E. sericatum

E. sericionitidum
E. serrulatum

E. sinuatum

E. strictius

E. strictius var.
isabellinus

E. turbidum

E. undatum

RPB2

HQ731517

HQ731518

GU384642
GQ289222
GQ289223

GQ289226
GQ289229

GQ289231

GQ289235

GQ289238

GQ289241

GU384643

GQ289247
GQ289248

GQ289253

GQ289254

GQ289256

GQ289257

GQ289260

EF421016
GQ289263

GQ289264

GU384641

GU384656
GQ289270

LSU

HQ731514

HQ731516

GU384616
GQ289150
GQ289151

GQ289154
GQ289157
GQ289160

JQ320115
GQ289164

GQ289167

GQ289170

GU384617

GQ289176
GQ289177

GQ289182

GQ289183

GQ289185

GQ289186

GQ289189

AF261315
GQ289192

GQ289193

AF042620
GU384618

GU384630
GQ289202

GENBANK ACC. NO.

mtSSU

HQ731511

HQ731513

GU384595
GQ289290
GQ289291

GQ289294
GQ289297

GQ289300

GQ289304

GQ289307

GQ289310

GU384596

GQ289316
GQ289317

GQ289322

GQ289323

GQ289325

GQ289326

GQ289329

EF421098
GQ289332

GQ289333

GU384594

GU384603
GQ289342

VOUCHER

DLL 9871

DLL 9788

TB6693
den Bakker 92

Manimohan 667-T

Noordeloos
200442

Ulje 1997-08-01

Noordeloos
200313

HKAS 48953
Gates E2031

Noordeloos
2004055

Hartman 1992-
10-28

TB9971

Hausknecht
Noordeloos
200330

Noordeloos
2004113

Noordeloos
2004070

Noordeloos
200364

Noordeloos
2004050

Noordeloos
200328

TB7144

Noordeloos
2004062

Wisman 2003-
09-19

M96/10

1TB7710

TB6949

Noordeloos 200327

ORIGIN

Australia,
NSW

Australia,
QLD

USA, NY
Canada

India, KL
Austria
Netherlands
Belgium

China, SC

Australia,
TAS

Australia,
TAS

Netherlands

USA, NY

Austria
Belgium

Australia,
TAS

Australia,
TAS

Slovakia

Australia,
TAS

Slovakia

USA, NY

Australia,
TAS

Netherlands

USA, TN

USA, NY

Belgium

592 ... Karstedt, Bergemann, Capelari

GENBANK ACC. NO.

NCBI sPECIES NAME RPB2 LSU mtSSU VOUCHER ORIGIN
E. valdeumbonatum GQ289271 GQ289203 GQ289343 Meusers E4565 [T] Germany
I. murrayi GU384637 GU384620 GU384590 VHAs02.02 —
I. sp. MCA2479 GU384640 GU384622 GU384593 MCA2479 —
L. serrulata GU384634 GU384624 GU384588 VHAs01.02 —
L. sp. MCA1486 GU384635 GU384623 GU384589 MCA1486 —
N. albertinae — KF738937 KF738925 FK1731 Brazil, RJ
KF771345 KF738938 KF738926 FK1732 Brazil, RJ
KF771344 KF738936 KF738924 FK0935-T Brazil, SP
N. atropapillata — KF738940 KF738929 FK0898-T Brazil, SP
N. cetrata KF771346 KEF738942 KF738927 DLL9531 USA, CA
— AF261319 — TB7382 USA, NY
N. conferenda KF771351 KF738946 KEF738935 ~—11CA014 USA, CA
N. conferenda — AF261321 — TB7660 USA, NY
N. hirtipes — AF261320 — K1171992
N. pallidosalmonea — KF738941 KF738930 _—_‘-FK0891 Brazil, SP
N. parvispora KF771348 KF738943 KF738931 FK1140 Brazil, SC
— — KF738932 FK2135 Brazil, SC
N. sericea DQ367435 DQ367423 EF421099 VHAs 03/02 —
GQ289262 GQ289191 GQ289331 Noordeloos Slovakia
200329
KF771349 KF738944 KF738933 11CA055 USA, CA
KF771350 KF738945 KF738934 11CA056 USA, CA
— AF261318 —_— TB6506 USA, CA
N. strictior EF421017 — EF421100 DUKE-JM96/10
N. tricholomatoidea KF771347 KF738939 KF738928 FK1049-T Brazil, SP
P. albostrigosa HQ876513 HQ876535 HQ876557 __Largent 9641 Australia
P lasia HQ876507. HQ876529 HQ876555 _Largent 9662 Australia
P. nodospora _ AF261308 — TB5716 USA, SC
P. setiformis HQ876503 HQ876525 HQ876525 _ Largent 9809 Australia
Rhodocybe trachyspora GU384658 GU384629 GU384605 TB5856 USA, CA
Richoniella asterospora JF706311 JF706310 — PBM3268 USA, TN
iG dar ee Le AF261290 — TB6957 USA, NC
OUTGROUP
Clitocybe dealbata DQ825407 = AF223175 AF357138 IE-BSG-HC95cp3 —
Lyophyllum IE-BSG-

DQ367434 AF223202 AF357101 =

leucophaeatum HAe251.97

Nolanea spp. nov. (Brazil) ... 593

Bioldgica de Paranapiacaba in Santo André City, in remnants of the Atlantic Forest
in Sao Paulo State, Southeast Brazil.

Revived sections of tissues from dried basidiomata mounted in 5% KOH, 5%
NH,OH, or 1% aqueous Congo Red dye used to stain hyaline structures were
examined microscopically. All the micrographs were drawn with the aid ofa drawing
tube. ‘Q’ represents the minimum and maximum length/width quotient, and ‘Qn
represents the mean length/width quotient of the total sample of measured spores.
The pileipellis structure was examined from the middle portion of the pileus and not
the disc or margin. The specimens were deposited in the herbarium of the Instituto
de Botanica (SP) and of the Royal Botanic Gardens (K). The samples were prepared
for SEM following Baroni (1981) and scanning electron micrographs (SEMs) were
made using a LEO 435 VP scanning electron microscope.

DNA extraction, amplification, sequence analyses

The DNA was extracted with hexadecyltrimethylammonium bromide (CTAB)
(Ferreira & Grattapaglia 1995) using lyophilized tissues from basidiomata ground
to a fine power in liquid nitrogen. The sample was resuspended in 50 uL of TE and
stored at —20 °C. The partial sequences of the mitochondrial small subunit (mtSSU)
were amplified via the polymerase chain reaction (PCR) primed by MS1 and MS2
(White & al. 1990); the 28S nuclear large subunit (nLSU) rDNA was amplified
using LROR and LR5 (Moncalvo & al. 2000); the ITS1-5.8S-ITS2 was amplified
using ITS1-F and ITS4 (White & al. 1990, Gardes & Bruns 1993); and the second
largest subunit of the RNA Polymerase II (rpb2) using rpb2-i6F and rpb2-i7R (Co-
David & al. 2009) or rpb2-F1 and rpb2-R1b (Largent & al. 2013). The PCRs were
performed in 25-50 uL reaction volumes, where the reaction concentration was 1x
for PCR Buffer, 2 mM for MgCl2, 0.2 mM for each dNTP, 0.5 uM for each forward
and reverse primer, and 0.025 U of Taq polymerase. Products from multiple
reactions were pooled for weak PCR amplifications. The reaction was performed
using the following cycling parameters: 94 °C for 2 min, 34 cycles at 94 °C for 45 s,
50 °C (54C? for rpb2) for 1 min and 10 s and 72 °C for 2 min, and then 72 °C for 10
min. PCR amplifications products were purified using the AxyPrep PCR Clean-up
Kit (Axygen Biosciences, Union City, USA) or alternatively, using the ExoSapIT kit
following the protocols outlined in Largent & al. (2011). DNA sequencing reactions
were performed with BigDye Terminator v3.1 Cycle Sequencing Kit. The sequences
were run in a ThermoFisher 3730 DNA Analyzer using Sequencing Analysis 5.3.1
and Base Caller KB. The forward and reverse sequences for each sample were
aligned and edited using CodonCode Aligner or Sequencher.

The phylogenetic analysis was conducted using sequences obtained in this study
and sequences found in GenBank of species traditionally accepted as Nolanea
[Nolanea—Claudopus clade sensu Co-David & al. (2009) and Baroni & Matheny
(2011)] (TaBLeE I). Lyophyllum leucophaeatum (P. Karst.) P. Karst. and Clitocybe
dealbata (Sowerby) P. Kummer were selected as outgroups based on phylogenetic
analyses performed by Co-David & al. (2009). The sequences were manually
aligned using Se-Al Sequence Alignment Editor; spliceosomal introns in the rpb2

594 ... Karstedt, Bergemann, Capelari

were delimited using Augustus ver. 2.4 webserver (Stanke & al. 2008) and omitted
along with ambiguous sites in mtSSU. For these phylogenetic analyses, sequences
from the three genes including missing data were assembled. The final alignment
after the exclusion of introns and ambiguous sites was 3162 bp including gaps:
592 bp for the mtSSU, 1390 bp for the nLSU and 1180 bp for the rpb2 (Tree-BASE
database ID14850).

Phylogenetic analyses were performed using maximum likelihood (ML),
Bayesian Inference (BI), and maximum parsimony (MP). For the BI, the best-fit
model of nucleotide substitution was performed using the Akaike information
criterion (AIC) in TOPALI v.2 (Milne & al. 2009). ML analysis was performed using
RAXML 7.0.4 with a GTR + G model according to recommendations (Stamatakis
2006, Stamatakis & al. 2008). Support for nodes was tested using 1000 bootstrap
replicates. For the BI phylogeny, the best-fit model of nucleotide substitution for
each gene partition and codon for the rpb2 (GTR + G for LSU, mtSSU and codons
and 3 of rpb2, and GTR + G + I for first codon of rpb2). The BI was performed with
MrBayes 3.2.2 (Huelsenbeck & Ronquist 2001, Ronquist & Huelsenbeck 2003)
specifying four chains (one cold, three heated) for 2,000,000 generations (sampling
trees every 1000 generations), with a burn-in of 30,000 generations. MP heuristic
searches were performed using the program TNT (Goloboff 1999, Nixon 1999,
Goloboff & al. 2008). Tree searches were conducted with equal weights and treating
gaps as a fifth character state. Branch support was calculated with 1000 bootstrap
replicates. A bootstrap value of 70% was considered significant for ML and MP. The
Bayesian posterior probability (BPP) statistical support values of branches were
considered informative if = 0.95.

Phylogenetic results

The DNA sequences obtained, including partial sequences of the nLSU,
mtSSU,andrpb2maresummarizedin TABLE I. Additionally, sequences obtained
from Nolanea albertinae (FK0912: KF679349, FK0935 [holotype]: KF679348),
N. atropapillata (FK0898 [holotype]: KF679354), N. pallidosalmonea (FK0891
[holotype]: KF738923), N. parvispora (FK1140 [holotype]: KF679353) and N.
tricholomatoidea (FK1049 [holotype]: KF679352) were deposited in GenBank.

The phylogenetic analyses placed all five species studied into /Nolanea-
Claudopus (Co-David & al. 2009, Baroni & Matheny 2011, Kinoshita & al.
2012), an unsupported clade based on ML, MP, and BPP. The phylogenies
place all five species into one of two strongly supported internal clades (Fie. 1)
in the /Nolanea clade with other species of Nolanea.

Taxonomy
Five new species are described and illustrated with line drawings,
macroscopic photographs and SEMs of basidiospores.

Nolanea spp. nov. (Brazil) ... 595

Entoloma cf.conferendum HKAS48953
Nolanea cf. conferenda11CA014
Entoloma conferendum MEN200313
Nolanea conferendaTB7660

Nolanea albertinae FK1731

Nolanea albertinae FK1732

Nolanea albertinae FK0935

Nolanea tricholomatoideaFK1049
Entoloma cephalotricum CU19970801
Nolanea atropapillata FK0898

Nolanea pallidosalmoneaFK0891
Entoloma strictus var.isabelina TB7710
Nolanea cetrata DLL9531

Nolanea cetrata TB7382

Entoloma pallideradicatumWU189010
Nolanea parvispora FK1140

Nolanea parvispora FK2135

Entoloma pygmaeopapillatum MEN200364
Nolanea sericea VHAs03/02

Entoloma strictius M9610 lI
Nolanea sericea MEN200329

"/ Nolanea sericea 11CA055

Nolanea sericea11CA056

Entoloma valdeumbonatum MME4565

sya Nolanea sericea TB6506

Nolanea hebes CH19921028

Nolanea hirtipes K1171992

Nolanea strictior DUKEJM9610

Entoloma readiae MEN2004050
Entoloma arbortivum TB6693
Entoloma abortivum Bakker92
Entoloma sericeonitidumTB7144
Entoloma undatum MEN200327

Claudopus minutoincanus DLL9871

Entoloma parasiticum MEN200330

Claudopus viscosusDLL978 Claudopus
Inocephalus sp. MCA2479

Inocephalus murrayi VHAs02/02

Entoloma procerum MEN2004070

Entoloma albidoquadratum PM667

Entoloma porphyrescens MEN2004113

Trichopilus porphyrophaeusTB6957

Entoloma gasteromycetoides GGE2031

Entoloma serrulatum MEN2004062

Leptonia sp. MCA1486

Leptonia serrulata VHA01/02 Inocephalus-Cyanula
Pouzarella albostrigosa DLL9641
Pouzarella lasiaDLL9662
Pouzarella setiformis DLL9809
Pouzarella nodospora 1B5716 Pouzarella
Richoniella asterospora PBM3268

adie *t00°_ Entoloma nidorosum 1B9971
100 100 / 100) Entoloma sinuatum JW20030919 J
ae ae sericatum MEN200328 Entoloma s.s. / Rhodopoloid

Entoloma haastii MEN2004055

Entoloma turbidum TB6949

| Rhodocybe trachyspora TB5856

Entoloma bloxamii MEN200442
Clitocybe dealbata HC95cp3
Lyophyllum leucophaeatum HAe25197

Nolanea-Claudopus

93/81
100

100 497.
100

Fic. 1. Phylogram of maximum likelihood (ML) phylogenetic reconstruction using rpb2, nLSU,
and mtSSU sequences. Support is indicated with ML/MP bootstrap percentage above and
Bayesian posterior probabilities (BPP) below branches. The names of species studied in this
paper are in boldface. I. Species with heterodiametric basidiospores. II. Species with iso- to
subisodiametric basidiospores.

596 ... Karstedt, Bergemann, Capelari

Nolanea albertinae Karstedt & Capelari, sp. nov. FIGS. 2A-E, 3, 8A,B
MB826784

Differs from Entoloma belouvense by its smaller basidiospores and presence of refractive
hyphae.

Type—Brazil, Sao Paulo State, Santo André: Reserva Bioldgica de Paranapiacaba,
23°46’S 46°18’W, trail 15, 18.V.2006, F. Karstedt & M. Capelari FK0935 (Holotype: SP;
GenBank KF771344, KF738936, KF738924).

EtymMoLoGy—an honour to Albertina Teresinha Karstedt.

PitEus 14-18 mm diam., broadly conic, conico-convex, convex, plano-convex
or plane, often slightly papillate, rarely with the center plane or depressed, pale
brown, brown, dark brown (chocolate-colored), or gray-brown, center often
darker than the margin, surface glabrous or with a few appressed, concolorous
radial fibrils, when humid strongly translucent-striate, when dry, opaque,
hygrophanous, margin slightly or strongly eroded. PILEUS CONTEXT very
thin, whitish. LAMELLAE adnexed or sinuate, pale pinkish brown, subdistant,
with 1-5 lamellulae (3 series), margin slightly eroded. ST1PE 36-71 x 1-4 mm,
often cylindrical, rarely tapered above or subbulbous over base, brownish
beige, pale brown, gray-brown or ocher brown, rarely yellowish brown or
concolorous with pileus, apex always paler than the base, sometimes beige
or whitish, surface glabrous, often with the apex slightly pruinose, fibrillose-
twisted, hollow, base of stipe often with a white tomentum. SPORE PRINT not
recorded.

BASIDIOSPORES 7.5-10(-11.2) x 5-7.5 um (Q = 1.16-1.75, Qm = 1.36),
heterodiametric, strongly angled, with 5 or 6 angles in profile, slightly pinkish
brown, thin-walled. Basip1A 23-37 x 8.7—15 um, clavate, hyaline, thin-walled,
tetrasporic. LAMELLAE EDGES heterogeneous. CHEILOCYSTIDIA always
present, dispersed or present [in portion of] on the lamellae edges near the
stipe, 26-68 x 5-7.5 um, cylindrical, often apex capitate, hyaline, thin-walled.
PLEUROCYSTIDIA absent. LAMELLAR TRAMA subparallel, with hyphae 5-40 um
diam., cylindrical or fusiform, hyaline, thin-walled; subhymenium ramose.
PILEITRAMA composed of radially arranged and parallel hyphae, with hyphae
8.7-25 um diam., inflated or fusiform, hyaline, thin-walled. PILEIPELLIs
a cutis, made up of cylindrical hyphae, with brown intracellular pigment,
hyphae thin-walled, 3.7-7.5 um diam., with cylindrical or cylindrical-clavate
terminal elements; subpellis made up of inflated or fusiform, hyaline, thin-
walled hyphae, 10-37 um diam. STIPITIPELLIs a cutis of straw yellow, thin-
walled hyphae 5-15 um diam. CAULocysTIDIA absent. CLAMP CONNECTIONS
present, but inconspicuous. REFRACTIVE HYPHAE present at pileipellis.

Nolanea spp. nov. (Brazil) ... 597

Fic. 2. Basidiomata. Nolanea albertinae: a. FK735; b. FK883; c. FK912; d. FK935 (holotype);
e. FK1111. N. atropapillata: f. FK649; g. FK898 (holotype). N. pallidosalmonea: h. (FK892,
holotype). N. parvispora: i. FK664 (holotype); j. FK689; k. FK794. N. tricholomatoidea: |. (FK1049,
holotype). Scale bars = 1 cm. Photos: a, b, d-j, 1: F. Karstedt; c, k: M. Capelari.

Hasitat—Solitary or sometimes gregarious, on litter or in soil with
fragmented organic material.

ADDITIONAL SPECIMENS EXAMINED—BRAZIL, SAO PauLo STATE: Sao Paulo,
Parque Estadual da Cantareira, Nucleo Engordador, 23°20’S 46°41’W, Macuco
trail, 27.1V.2006, EF Karstedt & M. Capelari FK630 (SP); 29.VI.2006, F. Karstedt &
M. Capelari FK0690 (SP); 19.IX.2006, E Karstedt & M. Capelari FK0735 (SP);
Cachoeira trail, 20.III.2007, F. Karstedt & al. FK0883 (SP); 29.V.2007, F. Karstedt &
al. FK0912 (SP); 13.III.2008, F. Karstedt FK1101 (SP); Parque Estadual das Fontes do
Ipiranga, 23°39’S 46°37’W, Nascente trail, 20.V1.2006, F. Karstedt & al. FK0682 (SP);
28.VIII.2008, FE. Karstedt & K. Patekoski FK1111 (SP); Santo André, Reserva Bioldgica
de Paranapiacaba, 23°46’S 46°18’W, trail 15, 18.V.2006, F. Karstedt & M. Capelari
FK0651 (SP), FK0652 (SP); trail 2, 18.V.2006, F. Karstedt & M. Capelari FK0656 (SP);
trail 3, 22.VI.2006, F. Karstedt FK0685 (SP); trail 1, 23. VIII.2006, F. Karstedt FK0727

598 ... Karstedt, Bergemann, Capelari

(SP). SANTA CATARINA STATE: Gaspar, #1111 Pedro Schmitt Street, hill behind the

Joao Pedro Lenfers’ house, 02.VIII.2008, F. Karstedt & A.T. Karstedt FK1110 (SP).

RIO DE JANEIRO STATE: Parque Nacional do Itatiaia, 11.1.2011, EF Karstedt, PB.

Schwartsburd & J.B. Pereira FK1731 (SP; GenBank KF738937, KF738925), FK1732

(SP; GenBank KF771345, KF738938, KF738926).
CoMMENTS—WNolanea albertinae apparently isa common species in the Atlantic
Forest of southern and southeastern Brazil; additionally it is usually solitary
and almost undetectable in the litter, considering that both have similar color.
Nolanea albertinae is similar to N. atripes Dennis and N. pseudopapillata Pegler,
which are both described from Central America (Horak 1977, Pegler 1983). It
also resembles Entoloma dissimile (Singer) E. Horak (described from Argentina;
Singer 1969, Horak 1977), N. fuscifolia (Peck) Sacc. (described from the United
States (Peck 1874, Hesler 1963) but also found in Argentina; Singer 1969) and
Entoloma novum E. Horak, (described from Chile; Horak 1977). These species
have a similar stature including the mycenoid habit; a pileus that is brownish,
conical to plane, papillate and hygrophanous; a similar pileipellis with brown
pigmented repent hyphae; and similarly shaped and sized basidiospores,
7-10 x 5-7.5 um. All also can be separated morphologically besides lacking the
cylindrical to capitate cheilocystidia that characterize N. albertinae.

Nolanea atripes has a darker pileus, no cheilocystidia, and pileipellis with a
vacuolar pigment (Pegler 1983). Nolanea pseudopapillata, Entoloma dissimile
and Entoloma novum differ (from N. albertinae) by the absence of cheilocystidia
and clamp connections and by the presence of encrusted pileipellis hyphae
(Singer 1969, Horak 1977, Pegler 1983). Nolanea fuscifolia grows on wood
(instead soil or litter), has a dark brown pileus, lacks cheilocystidia, and
has clamp connections; additionally, N. fuscifolia was originally described
from New York (Peck 1874, Hesler 1963). Nolanea fuscifolia sensu Singer
(1969) from Argentina, is closer to Nolanea albertinae in its very infrequent
cheilocystidia and not (or only slightly) encrusted pigmentation; however it
is distinguished by its growth on dead wood and by the presence of fusoid-
ventricose caulocystidia.

The species most closely related to Nolanea albertinae is Entoloma belouvense
Noordel. & Hauskn. from the Republic of Seychelles, an island archipelago
in the Indian Ocean off the east coast of Africa (Noordeloos & Hausknecht
2007). Entoloma belouvense has similar macroscopic features and scattered
cheilocystidia that are cylindrical and often capitate. However, in addition to
its different distribution, N. albertinae has distinctly smaller basidiospores
(7.5-10 x 5-7.5 um versus 10-12 x 6-7,5 um) and the presence of refractive
hyphae at pileipellis.

Nolanea spp. nov. (Brazil) ... 599

Fic. 3. Nolanea albertinae (holotype, FK935):
a. Basidiospores; b. Basidia; c. Cheilocystidia; d. Pileipellis.
Scale bars: a-c = 10 um; d = 20 um.

600 ... Karstedt, Bergemann, Capelari

Nolanea atropapillata Karstedt & Capelari, sp. nov. FIGS. 25,G, 4, 8C,D
MB805603

Differs from N. albertinae, N. atripes, N. pseudopapillata, and Entoloma dissimile by its
bisporic basidia, by its intracellular and encrusted pigment in pileipellis hyphae, and by
the absence of clamp connections.

Type—Brazil, Sao Paulo State, Santo André: Reserva Bioldgica de Paranapiacaba,
23°46’S 46°18’W, Estrada Frederico Carlos Hoehne, 12.IV.2007, F. Karstedt & al. FK0898
(Holotype: SP, GenBank KF738940, KF738929).

EtryMoLocy—refers to the color of the papillae that are darker than the pileus.

PILEus 9-25 mm diam., convex, plano-convex or plane, papillate or umbonate,
brown or dark brown, darker in the center compared to the edge, turning
grayish brown or pale gray-brown with blackish papilla, surface smooth or
sometimes slightly squamulose-fibrillose at center, striate-translucent, strongly
hygrophanous then silky, margin slightly eroded or split and upturned with
age. PILEUS CONTEXT very thin. LAMELLAE almost free, narrowly adnexed,
pink or pink-brown, subdistant, with 1-5 lamellulae (2 tiers), margin smooth
or slightly eroded. St1pzE 20-55 x 1-7 mm, cylindrical, with subbulbous base
or slightly tapering upwards from swollen base, nearly white, pale beige or very
pale brown, apex that is paler than the base, fibrillose-twisted, hollow, base of
stipe often with a white tomentum. SPORE PRINT not recorded.

BASIDIOSPORES 8.7-12.5 x 6.2-8.7 um (Q = 1.16-1.6, Qm = 1.4),
heterodiametric, strongly angled, with 5-6 angles in profile, slightly brownish
pink, thin-walled. Basrp1a 20-35 x 7.5-10 um, clavate, hyaline, thin-walled,
bisporic. LAMELLAE EDGE fertile. CHEILOCYSTIDIA and PLEUROCYSTIDIA
absent. LAMELLAR TRAMA made up of regular cylindrical or fusiform, hyaline,
thin-walled hyphae, 6.2-26 um diam.; subhymenium ramose. PILEITRAMA
composed of radially arranged and parallel cylindrical or fusiform, hyaline,
thin-walled hyphae, 3.7-37 tm diam. PILEIPELLIS a cutis, suprapellis made
up of cylindrical hyphae, with brown intracellular pigment, sometimes
with brown encrusted pigment, hyphae thick or thin-walled, 2.5-18 um
diam.; terminal elements repent or anticlinal and then almost a trichoderm,
cylindrical or cylindrical-clavate at center of pileus; subpellis composed of
inflated or fusiform, hyaline or slightly straw yellow, thin-walled hyphae,
13.7-44 um diam. STIPITIPELLIS a cutis made up of hyaline or slightly straw
yellow, thin-walled hyphae, 2.5-10 um diam. CAULOCysTIDIA absent. CLAMP
CONNECTIONS absent. REFRACTIVE HYPHAE not observed.

HasBitaT—Solitary or dispersed in litter.

ADDITIONAL SPECIMENS EXAMINED—BRAZIL, SAO PAuLo State, Santo André:
Reserva Bioldgica de Paranapiacaba, 23°46’S 46°18’W, trail 12, 18.V.2006, F. Karstedt

Nolanea spp. nov. (Brazil) ... 601

Fic. 4. Nolanea atropapillata (holotype, FK898): a. Basidiospores; b. Basidia; c. Pileipellis.
Scale bars: a, b = 10 um; c = 20 um.

& M. Capelari FK0649 (SP), FK0650 (SP); trail 6, 18.V.2006, F. Karstedt & M. Capelari

FK0655 (SP); Estrada Frederico Carlos Hoehne, 12.V.2007, E. Karstedt & al. FK0899

(SP).
CoMMENTS—Nolanea atropapillata resembles N. albertinae, N. atripes,
N. pseudopapillata, and Entoloma dissimile from South America and
N. fuscifolia from the United States. All of these species have papillate, pale
brown pilei with a darker center and a translucent-striate surface and
heterodiametric basidiospores in the 8-13 x 6-9 um range. However, all
differ from N. atropapillata in producing tetrasporic basidia and clamp
connections. Nolanea atripes is further distinguished by its slender basidioma,
membranaceous pileus, and black stipe (Dennis 1961). The description of
N. atripes by Pegler (1983) differs from the Dennis's type description, in which
Dennis (1961) emphasized the contrast between the black stipe and gray-
brown pileus, while Pegler (1983) described the stipe as pale brown to dark,
and the basidiomata illustrated is much more robust.

Nolanea albertinae also differs by the presence of cheilocystidia and absence
of encrustations in the pileipellis hyphae, and Entoloma dissimile differs by
the pileipellis as a cutis without a differentiated subpellis. Nolanea fuscifolia
is distinguished by its subnodulose basidiospores (Hesler 1963, Singer 1969)
and N. pseudopapillata by its strongly heterodiametric basidiospores (Q = 1.61,
Pegler 1983).

602 ... Karstedt, Bergemann, Capelari

Nolanea pallidosalmonea Karstedt & Capelari, sp. nov. FIGS. 2H, 5, 8E,F
MB805604

Nolanea pallidosalmonea differs from other Nolanea spp. by its delicate and slender
basidiomata, by a pale pinkish salmon pileus with salmon pink striations and slightly
brownish center, by 5-6-angled heterodiametric basidiospores, by a pileipellis composed
of repent hyphae, and by the presence of refractive hyphae.

Type—Brazil, Sao Paulo State, Santo André: Reserva Bioldgica de Paranapiacaba,
23°46’S 46°18’W, trail 1, 23.11.2007, F. Karstedt & al. FK0892 (Holotype, SP; isotype K).

EtryMoLoGy—the name refers to the pale salmon pink coloration of the basidioma.

PitEus 4-15 mm diam., convex, slightly papillate, when young with more
pronounced papillae, very pale salmon pink or whitish salmon pink, darker
at the center and strongly translucent-striate when in fresh condition,
hygrophanous and then whitish from the margin towards the center and
finally whitish salmon pink and when dry, sometimes slightly brownish at
center, translucent-striate, after opaque and silky-fibrillose, margin entire.
PILEUS CONTEXT thin, translucent. LAMELLAE adnexed or sinuate, pale pink,
ventricose, subdistant, with 2 tiers of lamellulae. Stipe 25-54 x 1-3 mm,
cylindrical or slightly tapering, pale salmon pink or light brownish, hollow,
fibrous, with a small amount of white tomentum at the base. SPORE PRINT not
recorded.

BasIDIosPpoREs 8.7-10 x 6.2-7.5 um (Q = 1.16-1.6; Qm = 1.41),
heterodiametric, strongly angled, with (5)6-7 angles in profile view, hyaline
or slightly pinkish brown, thin-walled. Basip1a 25-37 x 8.7-11.2 um, clavate,
hyaline, thin-walled, tetrasporic. PLEUROCYSTIDIA and CHEILOCYSTIDIA
absent. LAMELLAE EDGE fertile. LAMELLAR TRAMA subparallel, hyphae with
5-20 um diam., cylindrical or slightly inflated, sometimes fusiform, hyaline,
thin-walled; subhymenium ramose. PILEITRAMA trama composed of regular
cylindrical, inflated or fusiform, hyaline, thin-walled hyphae, 11.2-26 um
diam. PILEIPELLIS a cutis made up of cylindrical, hyaline, thin-walled hyphae,
2.5-8.7 um diam.; subpellis made up of inflated or fusiform, hyaline, thin-walled
hyphae, 10-21 um diam. STIPITIPELLIs a cutis of hyaline, thin-walled hyphae,
3.7-12.5 um diam. CauLocysTipia not observed. CLAMP CONNECTIONS
absent. REFRACTIVE HYPHAE abundant in pileipellis.

HaBITAT— Gregarious or scattered, on soil.

ADDITIONAL SPECIMEN EXAMINED—BRAZIL, SAo PAULO STATE, Santo André:
Reserva Bioldgica de Paranapiacaba, 23°46’S 46°18’W, trail 1, 23.11.2007, FE. Karstedt &
al. FK0891 (SP; GenBank KF738941, KF738930).
ComMMENTS—Nolanea pallidosalmonea resembles Entoloma quadratum (Berk.
& M.A. Curtis) E. Horak, cited from Borneo, Singapore, Costa Rica, United

Nolanea spp. nov. (Brazil) ... 603

JOYSHOLOHOEGOOLY

Fic. 5. Nolanea pallidosalmonea (holotype, FK892): a. Basidiospores; b. Basidia; c. Pileipellis.
Scale bars: a, b = 10 um; c = 20 um.

States, Madagascar, Malaysia and Papua New Guinea, in its conical pileus and
a smooth surface (a cutis) that is salmon colored. However, E. quadratum is
clearly separated from N. pallidosalmonea by its cuboidal basidiospores and
clavate cheilocystidia (Horak 1975, 1977, Baroni & Halling 2000).

Nolanea minuta P. Karst., described from Europe, is another species with
pale and pinkish basidiomata, a silky-fibrillose pileus surface, heterodiametric
basidiospores, and absence of cheilocystidia. However, N. minuta differs from
N. pallidosalmonea in basidiospores with 5-7 angles in profile view, and a
pileitrtama composed of hyphae with intracellular and encrusted pigments
(Noordeloos 1980).

Nolanea parvispora Karstedt & Capelari, sp. nov. FIGS. 21-K, 6, 8G-I
MB805605
Nolanea parvispora differs from other Nolanea spp. by its lignicolous habitat, pale beige
pileus with dark center, stipe with a dark base and pale apex, sinuate lamellae, small
(6.2-7.5 x 6.2-7.5 um) isodiametric basidiospores, a lack of cystidia, and a pileipellis
composed of repent hyphae with dispersed groups of anticlinal hyphae.

TypE—Brazil, Sao Paulo State, Santo André: Parque Estadual da Cantareira, 23°20’S
46°41’W, Nucleo Engordador, Cachoeira trail, 25.V.2006, E Karstedt & M. Capelari
FK0664 (Holotype, SP).

EtyMoLoGcy—refers to the small size of the basidiospores.

PiLteEus 13-23 mm diam., convex, plano-convex or plane, sometimes with a
slightly or prominent papilla or slightly depressed at the center, whitish beige

604 ... Karstedt, Bergemann, Capelari

or pale brownish beige or light pinkish beige, brown at the center (insertion
of stipe), smooth and sometimes pruinose at the center, glabrous, translucent-
striate, margin revolute, even, or sometimes lobate. PILEUS CONTEXT very
thin. LAMELLAE sinuate, white or pinkish beige, abundant, with 5-7 lamellulae
(2 series), margin even. STIPE 25-42 x 2-4 cm, cylindrical or flattened,
brown or brownish translucent, beige at the apex, surface smooth, base with
white tomentum. SPORE PRINT pinkish. BASIDIOSPORES 6.2-7.5 x 6.2-7.5
um (Q = 1-1.2; Qm = 1.1), isodiametric, with 5-6 angles in profile view,
slightly pinkish, thin-walled. Bastp1a 27-43 x 8.7-10 um, clavate, hyaline,
thin-walled, tetrasporic. PLEUROCYSTIDIA and CHEILOCYSTIDIA absent.
LAMELLAE EDGE fertile. LAMELLAR TRAMA subregular, cylindrical, inflated
or fusiform, hyaline, thin-walled hyphae 3.7-12.5 um diam.; subhymenium
ramose. PILEITRAMA regular, made up of cylindrical, inflated or fusiform,
hyaline, thin-walled hyphae, 3.7-25 um diam. PILEIPELLIS a cutis composed
of cylindrical, hyaline or pale straw yellow, thin-walled hyphae, 6.2-13.7 um
diam., with dispersed or clustered thin-walled cylindrical or clavate, hyaline or
pale straw yellow anticlinal terminal elements; subpellis made up of inflated or
fusiform, hyaline, thin-walled hyphae 10-20 um diam. STIPITIPELLIs a cutis,
made up of hyaline or pale straw yellow, sometimes with encrusted (external)
yellow-brown pigment, thin or thick-walled hyphae, 6.2-16.2 um diam.
CAULOCYSTIDIA rare, cylindrical, clavate or ventricose, with pale straw yellow
plasmatic pigment, thin-walled, 28-75 x 2.5-7.5 um. CLAMP CONNECTIONS
absent. REFRACTIVE HYPHAE present in pileipellis.
HasitatT—Solitary or gregarious, on hardwood.

ADDITIONAL SPECIMENS EXAMINED—BRAZIL, SAO PAULO STATE, Sao Paulo:
Parque Estadual da Cantareira, Nucleo Engordador, 23°20’S 46°41’W, Macuco trail,
29.V1.2006, F. Karstedt & M. Capelari FK689 (SP); Cachoeira trail, 29.VI.2006, F.
Karstedt & M. Capelari FK0696 (SP); 25.VII.2006, E. Karstedt & M. Capelari FK0723
(SP); 24.X.2006, E. Karstedt & M. Capelari FK794 (SP); 30.X.2007, E Karstedt & al.
FK0926 (SP). SANTA CATARINA STATE, Joinville: Reserva Particular de Patrimdénio
Natural Caetezal, 02.1].2009, F. Karstedt FK1140 (SP; GenBank KF771348, KF738943,
KF738931); Corupa, Reserva Particular de Patriménio Natural Emileo F. Battistella,
falls route, 12.XII.2011, FE Karstedt FK2135 (FLOR; GenBank KF738932).

CoMMENTS—Rhodophyllus avellanicolor Romagn. & Gilles, Nolanea
mazophora (Berk. & Broome) Pegler, Entoloma myceliosum E. Horak, and
Entoloma imbecille (E. Horak) E. Horak ex Segedin & Pennycook [= E. fragile
E. Horak, nom. illegit.] are among the few species that resemble Nolanea
parvispora based on pale basidiomata and isodiametric basidiospores
measuring c. 7 x 7 um. Rhodophyllus avellanicolor, described from Africa, and

Nolanea spp. nov. (Brazil) ... 605

506909HQGO6O

Fic. 6. Nolanea parvispora (holotype, FK664):
a. Basidiospores; b. Basidia; c. Caulocystidia; d. Pileipellis.
Scale bars: a-c = 10 um; d = 20 um.

Nolanea mazophora, described from Sri Lanka, are terrestrial. Rhodophyllus
avellanicolor has clamp connections (Romagnesi & Gilles 1979) and
N. mazophora has a convex pileus with prominent papillae (Pegler 1977,
Horak 1980).

Entoloma myceliosum, described from Chile, is also lignicolous but differs
from N. parvispora by having a white pileus and stipe and a pileus surface
densely covered by white fibrils (Horak 1977). Entoloma imbecille, found in
New Zealand (Horak 1973, as “E. fragile”) and Argentina (Horak 1977, as
“E. fragile”), differs by a pileus that is initially brown and then turns beige, brown
encrusted pigments in the pileipellis hyphae, and abundant clamp connections.

606 ... Karstedt, Bergemann, Capelari

Nolanea tricholomatoidea Karstedt & Capelari, sp. nov. FIGS. 2L, 7, 8J,K
MB805607

Nolanea tricholomatoidea differs from other Nolanea spp by its robust stature, a
mostly beige pileus that turns brownish beige at the center; its whitish beige stipe,
its often pentagonal basidiospores; its basidial basal clamp connections at the base of
the basidia; and the encrusted pigment in the subpellis hyphae.

Type—Brazil, Sao Paulo State, Santo André: Parque Estadual da Cantareira, Nucleo
Engordador, 23°20’S 46°41’W, Cachoeira trail, 31.1.2008, F. Karstedt, L.A. Silva
Ramos & M. Capelari FK1049 (Holotype, SP; GenBank KF771347, KF738939,
KF738928).

ETyMoLoGy—the name refers to the tricholomatoid stature.

PiLEuS 80-92 mm diam., conico-campanulate or plane, umbonate, pale
beige, beige or brownish beige at center, surface smooth or slightly pruinose
at center, opaque, hygrophanous, translucent-striate at margin. PILEUS
CONTEXT white. LAMELLAE adnexed (almost free), beige, ventricose,
subdistant, with 2 tiers of lamellulae. Stipe 100-116 x 8-12 mm, and 39 mm
at base, subclavate, beige or whitish, fibrous and fibrillose, with white basal
mycelium. Opor indistinct. SPORE PRINT not recorded.

BASIDIOSPORES 8.7-10 x 7.5-8.7 um (Q = 1-1.33; Qm = 1.2), iso-
diametric or subisodiametric, strongly angled, with 5-6 angles in profile
view, with an obvious hilar appendix, hyaline or slightly brownish pink,
thin-walled. Basrp1a 37-51 x (8.7—)10-15 um, clavate with a narrow base,
hyaline, thin-walled, tetrasporic. LAMELLAE EDGE fertile. PLEUROCYSTIDIA
and CHEILOCYSTIDIA absent. LAMELLAR TRAMA regular and hyaline, with
hyphae 3.7-17.5 um diam., cylindrical or slightly inflated, hyaline, thin-
walled, septate; subhymenium ramose. PILEITRAMA regular, composed
of cylindrical or inflated, hyaline, thin-walled hyphae 3.7—27 um diam.
PILEIPELLIS a cutis, made up of cylindrical, hyaline, thin-walled hyphae
2.5-8.7 um diam., with rare anticlinal elements; subpellis composed
of inflated, hyaline, thin-walled hyphae 16.2-46 x 50-120 um diam.
STIPITIPELLIS a cutis made up of straw-yellow, hyaline, thin-walled hyphae,
3.7-7.5 um diam. CAULOCYSTIDIA absent. CLAMP CONNECTIONS present in
the hymenium. REFRACTIVE HYPHAE present in the pileipellis.

HABITAT—Solitary, on soil.

ADDITIONAL SPECIMEN EXAMINED—BRAZIL. Rio DE JANEIRO STATE, Nova
Iguacu: Reserva Bioldgica de Tingua, Ouro road, 8 Dec 2004, M.P. Albuquerque &
A.A. Carvalho-Jr. 29-VI (RB415680).
COMMENTS—Nolanea tricholomatoidea was collected in Rio de Janeiro
State but reported as Entoloma lividoalbum (Kihner & Romagn.) Kubicka

Nolanea spp. nov. (Brazil) ... 607

0O9HCO0G000

Fic. 7. Nolanea tricholomatoidea (holotype, FK1049):
a. Basidiospores; b. Basidia; c. Pileipellis.
Scale bars: a, b = 10 um, c = 20 um.

(Albuquerque & al. 2007). The robust stature is reminiscent of a feature
common to Entoloma sensu stricto, and based mainly on its stature, its
umbonate pileus that is sometimes translucent-striate, and its white stipe,
N. tricholomatoidea might seem related to species of Entoloma s.s., such as
E. lividoalbum and E. prunuloides (Fr.) Quél.

Entoloma lividoalbum, described from Europe and recorded from
the United States, differs in its pileus that varies from dark brown, dark
yellowish brown, pale yellowish white to pale grayish beige, and clamp
connections that are present in all tissues (Largent 1994, Noordeloos &
Polemis 2008). Entoloma prunuloides, recorded from Europe, differs in its
smaller basidiospores (6.5-8 x 6.5-8 um), an ixocutis-type pileipellis, and
the presence of clamp connections in all tissues (Noordeloos 1992).

Although a tricholomatoid stature is uncommon in Nolanea, the
pileipellis structure in N. tricholomatoidea, comprising a subpellis with
inflated elements and a suprapellis with thin elements, is a feature shared
among many Nolanea spp.

608 ... Karstedt, Bergemann, Capelari

Discussion

The phylogenetic analyses as supported by ML, MP, and BPP cluster the
species described here and other species traditionally accepted as Nolanea
within a single clade, the /Nolanea clade (Fia. 1).

Four of the species described in this paper—Nolanea albertinae,
N. atropapillata, N. pallidosalmonea, and N. tricholomatoidea—occur in
litter or soil and have heterodiametric basidiospores. They cluster in clade
I. Nolanea parvispora, the only lignicolous species and characterized by
isodiametric basidiospores, clusters in clade II.

Species that are placed in Nolanea often have a mycenoid habit (Henkel
& al. 2014, Largent 1994, Noordeloos 1992, 2004, Noordeloos & Gates
2012). Nolanea tricholomatoidea described herein and the two species
classified as Entoloma s.s. (E. pallideradicatum Hauskn. & Noordel. and
E. valdeumbonatum Noordel. & Meusers) have a tricholomatoid habit and
yet are included in the /Nolanea clade. These species share with Nolanea
species a pileipellis with a subpellis composed of inflated hyphae and
heterodiametric basidiospores.

Curiously, all species studied and almost all species (that have been
published with a detailed description of the pileipellis) in the /Nolanea
clade have a pileipellis composed of a suprapellis with narrow hyphae and
a subpellis with inflated hyphae. We recommend paying careful or close
attention to this character in the future to determine if these features are
phylogenetically informative.

Acknowledgments

The authors are grateful to Dr. David L. Largent and Ms. Kerri Kluting for the
donation of collections that were included in DNA amplification and the phylogenetic
analyses. A special thanks to Dr. David L. Largent and Dr. Genevieve M. Gates
for their suggestions, and Dr. Timothy J. Baroni and Dr. Felipe Wartchow for the
reviews. This study was supported by the grants FAPESP 2006/58549-4 to Fernanda
Karstedt (master’s grant) and FAPESP 2004/04319-2 to Marina Capelari provided by
Fundacao de Amparo a Pesquisa do Estado de Sao Paulo. M. Capelari also thanks the
CNPg - Conselho Nacional de Desenvolvimento Cientifico e Tecnoldgico.

Literature cited

Albuquerque MP, Carvalho Jr. AA, Pereira AB. 2006. Novas ocorréncias de Agaricales
(Basidiomycota) para o Brasil. R Bras Bioci 5: 1143-1145.

Baroni TJ. 1981. A revision of the genus Rhodocybe Maire (Agaricales). Beih Nova Hedwigia 67:
1-194,

Baroni TJ, Halling RE. 2000. Some Entolomataceae (Agaricales) from Costa Rica. Brittonia 52:
121-135. https://doi.org/10.2307/2666502

Nolanea spp. nov. (Brazil) ... 609

Fic. 8. Basidiospores in SEM:
a, b. Nolanea albertinae; c, d. N. atropapillata;
e, f. N. pallidosalmonea; g-i. N. parvispora;
j, k. N. tricholomatoidea. Scale bar = 10 um.

Baroni TJ, Matheny PB. 2011. A re-evaluation of gasteroid and cyphelloid species of
Entolomataceae from Eastern North America. Harv Pap Bot 16: 293-310.
https://doi.org/10.3100/0.25.016.0205

Bresadola G. 1920. Selecta mycologica. Ann mycol 18: 26-70.

Capelari M. 1989. Agaricales do Parque Estadual da Ilha do Cardoso (exceto Tricholomataceae)
[Master’s thesis]. Sao Paulo: Universidade de Sao Paulo. 356 p.

Co-David D, Langeveld D, Noordeloos ME. 2009. Molecular phylogeny and spore evolution
of Entolomataceae. Persoonia 23: 147-176. https://doi.org/10.3767/003158509X480944

de Meijer AAR. 2001. Mycological work in the Brazilian State of Parana. Nova Hedwigia 72:
105-159.

de Meijer AAR. 2006. Preliminary list of the macromycetes from the Brazilian State of Parana.
Bol Mus Bot Mun 68: 1-55.

Dennis RWG. 1961. Fungi venezuelani IV. Agaricales. Kew Bull 15: 67-156.
https://doi.org/10.2307/4115784

Ferreira ME, Grattapaglia D. 1995. Introdugao ao uso de marcadores RAPD e RFLP em
analise genética. Brasilia: Embrapa-Cenargen. 220 p.

610 ... Karstedt, Bergemann, Capelari

Gardes M, Bruns TD. 1993. ITS primers with enhanced specificity of Basidiomycetes:
application to the identification of mycorrhizae and rusts. Mol Ecol 2: 113-118.
https://doi.org/10.1111/j.1365-294X.1993.tb00005.x

Goloboff PA. 1999. Analyzing large data sets in reasonable times: solutions for composite
optima. Cladistics 15: 415-428. https://doi.org/10.1111/j.1096-0031.1999.tb00278.x

Goloboff PA, Farris JS, Nixon KC. 2008. TNT, a free program for phylogenetic analysis.
Cladistics 24:774-786. https://doi.org/10.1111/j.1096-0031.2008.00217.x

Hesler LR. 1963. A_ study of Rhodophyllus types. Brittonia 15: 324-366.
https://doi.org/10.2307/2805380

Henkel TW, Aime MC, Largente DL and Baroni TJ. 2014. The Entolomataceae of the
Pakaraima Mountains of Guiana 6: ten new species and a new combination in Nolanea.
Mycotaxon 129: 119-148. https://doi.org/10.5248/129.119

Horak E. 1973. I. Entoloma (Fr.) and related genera. 1-86. In: Fungi agaricini Novazelandiae I-V.
Beihefte zur Nova Hedwigia 43. 200 p.

Horak E. 1975. On cuboid-spored species of Entoloma (Agaricales). Sydowia 28: 171-236.

Horak E. 1977. Entoloma in South America. I. Sydowia 30: 40-110.

Horak E. 1980. Entoloma (Agaricales) in Indomalaya and Australasia. Beih Nova Hedwigia 65:
1-352.

Horak E. 2008. Agaricales of New Zealand 1: Pluteaceae (Pluteus, Volvariella); Entolomataceae
(Claudopus, Clitopilus, Entoloma, Pouzarella, Rhodocybe, Richoniella). Fungi of New Zealand
Volume 5. Fungal Divers Res Ser 19: 1-305.

Huelsenbeck JP, Ronquist E 2001. MrBayes: Bayesian inference of phylogenetic trees.
Bioinformatics 17: 754-755. https://doi.org/10.1093/bioinformatics/17.8.754

Kinoshita A, Sasaki H, Nara K. 2012. Multiple origins of sequestrate basidiomes within
Entoloma inferred from molecular phylogenetic analyses. Fungal Biol 116: 1250-1262.
https://doi.org/10.1016/j.funbio.2012.09.006

Largent DL. 1994. Entolomatoid fungi of the Western United States and Alaska. Eureka:
Mad River Press. 495 p.

Largent DL, Bergemann SE, Cummings, G.A., Ryan, K.L., Abell-Davis SE, Moore, S. 2011.
Pouzarella (Agaricales, Entolomataceae) species from New South Wales (Barrington
Tops National Park) and northeastern Queensland, Australia. Mycotaxon 117: 435-483.
https://doi.org/10.5248/117.435

Largent DL, Bergemann SE, Abell-Davis SE, Kluting KL, Cummings GA. 2013. Five
Leptonia species from New South Wales and Queensland, Australia. Mycotaxon 125:
11-35. https://doi.org/10.5248/125.11

Milne I, Lindner D, Bayer M, Husmeier D, McGuire G, Marshall DF, Wright F 2009.
TOPALi v2: a rich graphical interface for evolutionary analyses of multiple alignments
on HPC clusters and multi-core desktops. Bioinformatics 25: 126-127.
https://doi.org/10.1093/bioinformatics/btn575

Moncalvo J-M, Vilgalys R, Redhead SA, Johnson JE, James TY, Aime MC, Hofstetter V,
Verduin SJW, Larsson E, Baroni TJ, Thorn RG, Jacobson S, Clémencon H, Miller Jr. OK.
2002. One hundred and seventeen clades of euagarics. Mol Phylogenet Evol 23: 357-400.
https://doi.org/10.1016/S1055-7903(02)00027-1

Nixon KC. 1999. The parsimony ratchet, a new method for rapid parsimony analysis. Cladistics
15: 407-414. https://doi.org/10.1111/j.1096-0031.1999.tb00277.x

Noordeloos ME. 1980. Entoloma subgenus Nolanea in the Netherlands and adjacent regions
with a reconnaissance of its remaining taxa in Europe. Persoonia 10: 427-534.

Nolanea spp. nov. (Brazil) ... 611

Noordeloos ME. 1992. Entoloma s.1. Fungi Europae 5: 1-760.

Noordeloos ME. 2004. Entoloma s.1. Fungi Europae 5a: 761-1378.

Noordeloos ME, Gates GM. 2012. The Entolomataceae of Tasmania. Fungal Divers Res Ser 22:
1-400.

Noordeloos ME, Hausknecht A. 2007. The genus Entoloma (Basidiomycetes, Agaricales) of the
Mascarenes and Seychelles. Fungal Divers 27: 111-144.

Noordeloos ME, Polemis E. 2008. Studies in the genus Entoloma (Basidiomycota, Agaricales)
from the Kiklades (C. Aegean, Greece). Mycotaxon 105: 301-312.

Peck CH. 1874. Report of the Botanist. Rep NY St Mus 26: 35-91.

Pegler DN. 1977. A revision of Entolomataceae (Agaricales) from India and Sri Lanka. Kew Bull
32: 189-220. https://doi-org/10.2307/4117266

Pegler DN. 1983. Agaric flora of the Lesser Antilles. Kew Bull Addit Ser 9: 1-668.

Pegler DN. 1997. The Agarics of Sao Paulo, Brazil: an account of the agaricoid fungi
(Holobasidiomycetes) of Sao Paulo State, Brazil. Royal Botanic Gardens, Kew. 68 p.

Putzke MTL, Cavalcanti MA. 1997. O género Entoloma (Fr.) P. Kumm. (Entolomataceae,
Agaricales, Basidiomycota) no Rio Grande do Sul. Caderno de Pesquisa Sér Bot 9: 3-65.

Raj KNA, Manimohan P. 2016. Three new species of Entoloma subgenus Nolanea from
India based on morphology and molecular phylogeny. Phytotaxa 286(4): 232-244.
https://doi.org/10.11646/phytotaxa.286.4.2

Raj KNA, Latha KPD, Kumar TKA, Manimohan P. 2014. A new species of Entoloma from India.
Mycoscience 55: 400-404. https://doi.org/10.1016/j.myc.2014.01.003

Rick J. 1919. Contributio II ad monographiam Agaricinorum Brasiliensium. Brotéria 17:
101-111.

Rick J. 1920. Contributio III ad monographiam Agaricacearum Brasiliensium. Brotéria 18:
48-63.

Rick J. 1930. Contributio IV ad monographiam Agaricacearum Brasiliensium. Brotéria 24:
97-118.

Rick J. 1961. Basidiomycetes eubasidii in Rio Grande do Sul - Brasilia. 5. Agaricaceae. Iheringia
Sér Bot 8: 296-450.

Romagnesi H, Gilles G. 1979. Les Rhodophylles des foréts coti¢res du Gabon et de la Cote
d'Ivoire. Beih Nova Hedwigia 59: 1-649.

Ronquist F, Huelsenbeck JP. 2003. MrBayes 3: Bayesian phylogenetic inference under mixed
models. Bioinformatics 19: 1572-1574. https://doi.org/10.1093/bioinformatics/btg180

Rosa LH. 2002. Diversidade de fungos Agaricales (Basidiomycota) em dois fragmentos de
mata atlantica do estado de Minas Gerais [| Master’s thesis]. Belo horizonte: Universidade
Federal de Minas Gerais. 199 p.

Singer R. 1954 [1953]. Type studies on Basidiomycetes. VI. Lilloa 26: 57-159.

Singer R. 1969. Mycoflora australis. Beih Nova Hedwigia 29: 1-405.

Stanke M, Diekhans M, Baertsch R, Haussler D. 2008. Using native and synthetically
mapped cDNA alignments to improve de novo gene finding. Bioinformatics 24: 637-644.
https://doi.org/10.1093/bioinformatics/btn013

Stamatakis A. 2006. RAxML-VI-HPC: Maximum likelihood-based phylogenetic
analyses with thousands of taxa and mixed models. Bioinformatics 22: 2688-2690.
https://doi.org/10.1093/bioinformatics/btl446

Stamatakis A, Hoover P, Rougemont J. 2008. A rapid bootstrap algorithm for the RAxML Web-

Servers. Systematic Biology 75: 758-771. https://doi.org/10.1080/10635 150802429642

612 ... Karstedt, Bergemann, Capelari

Vila J, Carbo J, Caballero F, Catala S, Llimona X, Noordeloos ME. 2013. A first approach to the
study of the genus Entoloma subgenus Nolanea s.]. using molecular and morphological
data. Fungi non Delineati 66 (Studies on Entoloma): 3-62 + 93-135 (iconography).

White T, Bruns, T, Lee S, Taylor JW. 1990. Amplification and direct sequencing of fungal
ribosomal RNA genes for phylogenetics. 315-322, in: MA Innis & al. (eds). PCR
Protocols: a Guide to Methods and Applications. Academic Press, Inc., New York.
https://doi.org/10.1016/B978-0- 12-372180-8.50042-1

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 613-616
https://doi.org/10.5248/135.613

First record of Trappea darkeri from Turkey

YASIN UZUN', OSMAN BERBER’, ABDULLAH KAYA?

2 Department of Biology, Science Faculty, Karamanoglu Mehmetbey University,
70100, Karaman, Turkey
* Department of Biology, Science Faculty, Gazi University, 06560, Ankara, Turkey

“ CORRESPONDENCE TO: kayaabd@hotmail.com

ABSTRACT—The truffle-like basidiomycete genus Trappea is reported as a new record from
Turkey and western Asia, based on a collection of T: darkeri from Nigde province. This
is also the first record of the family Trappeaceae for the country. A brief description and
photographs of the collection is provided.

Key worps—Basidiomycota, biodiversity, Hysterangiales, taxonomy

Introduction

Trappea Castellano is a truffle-like fungi genus in the family Trappeaceae
(Kirk & al. 2008). The genus was proposed by Castellano (1990), who
segregated T: darkeri and T: phillipsii from Hysterangium Vittad. based on
their smooth bacilloid basidiospores and layer of sterile locules below the
peridium. Trappea species are characterized by subglobose to irregularly lobed
fruit bodies with one or more rhizomorphs emerging from the base; a thin
white peridium covering a zone of sterile chambers; an olive- brown to bright
olive-green gleba with small empty chambers and a dendroid, gelatinous to
cartilaginous columella; and ellipsoid to oblong basidiospores.

Index Fungorum (www.indexfungorum.org accessed 25 June 2019) lists
four Trappea species, none of which has been reported from Turkey (Acar
& al. 2019, Sesli & Denchev 2014, Solak & al. 2015, Turkekul 2017). Here
we contribute to the Turkish mycobiota and report T: darkeri as the first
representative of the genus and family in Turkey.

614 ... Uzun, Berber, Kaya

Materials & methods

The Trappea specimen was collected from Ulukisla district, Nigde province, in
2019. The basidiomata were photographed in their natural habitat, where ecological
and morphological observations were taken. Dried material was examined and
photographed microscopically in the fungarium using a Nikon Eclipse Ci-S
trinocular compound microscope with Nikon DS-Fi2 camera and a Hitachi
SU5000 scanning electron microscope. The specimen was identified by consulting
the literature (Castellano 1990, Desjardin & al. 2014, Gémez-Reyes & al. 2014,
Montecchi & Sarasini 2000, Ruini 1990, Zeller 1939). The collection is preserved in
the fungarium of Department of Biology, Science Faculty, Karamanoglu Mehmetbey
University, Karaman, Turkey (KMU).

Taxonomy

Trappea darkeri (Zeller) Castellano, Mycotaxon 38: 3 (1990) FIG. 1
BasIDIOMA 40 mm in diam, hypogeous to semi-hypogeous, globose,

surface glabrous, with basal rhizomorphs at the base, whitish, light brownish
when rubbed. PERIpIUM whitish in section, not separable, membranous-
leathery. GLEBA firm, bright olive-green, olive gray to light olive-brown,
white near the peridium, spongy gelatinous. COLUMELLA distinct, gelatinous,
translucent, typically dendroid and reaching almost throughout the
sporocarp. Odor unpleasant. Basip1A 19-25 x 5-8 um, irregularly cylindrical
to clavate, (4-)6(-8)-spored, clamp connections present. CysTipIA not
observed. BASIDIOSPORES 4-5 x 2-3 um, ellipsoid to cylindrical, smooth,
hyaline, sessile or with a short pedicel.

SPECIMEN EXAMINED—TURKEY, NiGDE: Ulukisla, Ciftehan village, 37°30’N 34°47’E,

930 m, in soil among needle-litter in pine-oak mixed forest, 23.03.2019, O.Ber 342

(KMU).
CoMMENTS— Trappea darkeri has a hypogeous to semi-hypogeous habit with
long rhizomorphs at the base and is distributed in high altitudes of 1000-
3000 m (Castellano 1990, Desjardin & al. 2015, Gomez-Reyes & al. 2014).
It is distinguished by a layer of sterile locules just under the peridium, and
small, cylindrical spores (G6mez-Reyes & al. 2014). Morphologically it may
be confused with Hysterangium species with rubbery-gelatinous olive-green
gleba, which differ in their easily separable peridia, absence of sterile locules
next to the peridium and larger, spindle-shaped spores (Desjardin & al.
2015, Siegel & al. 2019). Ecologically and morphologically similar, Trappea
pinyonensis States can easily be distinguished from T. darkeri by the staining
reactions of the peridium and rhizomorphs and its longer (5-6.2 x 2-2.5 um)
spores (States 1991).

Trappeaceae newly recorded for Turkey... 615

. ow ;
Fic. 1. Trappea darkeri (KMU - Ber 342). a. Basidiomata; b. Basidia and basidiospores;
c-e. Basidiospores (SEM). Scale bars: b = 10 um; c-e = 3 um.

Although our specimen was collected at a slightly lower elevation
(930 m) than cited elsewhere, its morphological characters agree with those
cited in the literature (Castellano 1990, Desjardin & al. 2015, Gomez-Reyes
& al. 2014, Montecchi & Sarasini 2000, Ruini 1990, Zeller 1939).

Acknowledgments

The authors would like to thank Dr. Ali Keles (Yuziincti Yil University, Van,
Turkey), Prof. Dr. [brahim Tiirkekul (Gaziosmanpasa University, Tokat, Turkey)
and Nomenclature Editor Dr. Shaun Pennycook for their helpful comments and
careful review.

Literature cited

Acar I, Uzun Y, Keles A, Dizkirci A. 2019. Suillellus amygdalinus, a new species record
for Turkey from Hakkari Province. Anatolian Journal of Botany 3(1): 25-27.
https://doi.org/10.30616/ajb.514778

616 ... Uzun, Berber, Kaya

Castellano MA. 1990. The new genus Trappea (Basidiomycotina, Hysterangiaceae), a segregate
from Hysterangium. Mycotaxon 38: 1-9.

Desjardin DE, Wood MG, Stevens FA. 2014. California mushrooms, the comprehensive
identification guide. London: Timber Press.

Gomez-Reyes VM, Gomez-Peralta M, Terrén-Alfonso A, Guevara-Guerrero G. 2014.
Description of Trappea darkeri (Trappeaceae: Hysterangiales) from Mexico. Revista
Mexicana de Biodiversidad 85: 1265-1268. https://doi.org/10.7550/rmb.43995

Kirk PM, Cannon PF, Minter DW, Stalpers JA. 2008. Dictionary of the fungi. 10th ed.
Wallingford, UK: CAB International.

Montecchi A, Sarasini M. 2000. Fungi ipogei d’ Europa. Vicenza: Centro Studi Micologici.

Ruini S. 1990. Un nuovo gasteromicete ipogeo: Trappea darkeri (Zeller) Castellano var. lazzarii
Ruini v. nov. Rivista di Micologia 33(3): 322-330.

Sesli E, Denchev CM. 2014. Checklists of the myxomycetes, larger ascomycetes, and
larger basidiomycetes in Turkey. 6th ed. Mycotaxon Checklists Online. 136 p.
http://www.mycotaxon.com/resources/checklists/sesli-v106-checklist.pdf

Siegel N, Vellinga EC, Schwarz C, Castellano MA, Ikeda D. 2019. A field guide to the rare fungi
of California’s National Forests. Bookmobile: Minneapolis, MN. 313 p.

Solak MH, Isiloglu M, Kalmus E, Alli H. 2015. Macrofungi of Turkey, checklist, vol. 2. Izmir,
Turkey: Universiteliler Ofset [in Turkish].

States JS. 1991. A new false truffle in the genus Trappea (Hysterangiaceae). Mycotaxon 41(1):
127-133.

Trappe M, Evans E Trappe J. 2007. Field guide to North American truffles. Berkeley:
Ten Speed Press.

Tirkekul I. 2017. New Calbovista, Mycena, Rhizopogon, Stictis, and Symphyosirinia records
from Turkey. Mycotaxon 132: 503-512. https://doi.org/10.5248/132.503

Zeller SM. 1939. New and noteworthy gasteromycetes. Mycologia 31(1): 1-32.
https://doi.org/10.2307/3754429

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 617-622
https://doi.org/10.5248/135.617

Mesocorynespora sinensis gen. & sp. nov.
from southern China

ZHAO-HUAN XU’, KAI ZHANG’, YOU-QIANG LUO’,
Xi1u-Guo ZHANG?, RAFAEL F. CASTANEDA-RuiIz‘, JIAN Ma‘*

' College of Agronomy, Jiangxi Agricultural University, Nanchang, Jiangxi 330045, China
? Department of Landscaping, Shandong Yingcai University, Jinan, Shandong 250104, China
> Shandong Provincial Key Laboratory for Biology of Vegetable Diseases and Insect Pests,
College of Plant Protection, Shandong Agricultural University,
Taian, Shandong 271018, China
‘Instituto de Investigaciones Fundamentales en Agricultura Tropical Alejandro de Humboldt
(INIFAT), Académico Titular de la Academia de Ciencias de Cuba,
Calle 1 Esq. 2, Santiago de Las Vegas, C. Habana, Cuba, C.P. 17200

* CORRESPONDENCE TO: majian821210@163.com; jxaumj@126.com

ABSTRACT—A new anamorphic genus and species, Mesocorynespora sinensis collected on
decaying culms of bamboo in China, is described and illustrated. The fungus is distinguished
by short, unbranched, clavate conidiophores with monotretic, conidiogenous cells that
produce solitary, acrogenous, obclavate, euseptate conidia. A key to Mesocorynespora and
morphologically similar genera is provided.

KEY worps—asexual fungi, hyphomycetes, taxonomy

Introduction

Lushan Mountain, located in the northern part of Jiangxi Province, China,
covers approximately 302 km’ and exhibits a unique geography with complex
terrains and unusual climate. The mountain's distinctive vegetation has favored
the survival and multiplication of various microbial species, yet only relatively
little information has been published on saprobic hyphomycetes recorded in
China (e.g., Ma & Zhang 2015, Ma 2016, Ma & al. 2016, Xu & al. 2017, Ai &
al. 2019). During our continuing surveys of asexual fungi in this region, an

618 ... Xu &al.

interesting fungus was collected that differed remarkably from all previously
described hyphomycetes (Seifert & al. 2011). Thus, it is described here as a new
genus and species.

Taxonomy

Mesocorynespora Jian Ma, X.G. Zhang & R.F. Castaneda, gen. nov.
MB 836511

Differs from Solicorynespora by its short, determinate, clavate conidiophores and multi-
euseptate conidia; and from Corynespora by its euseptate conidia.

TYPE SPECIES: Mesocorynespora sinensis Jian Ma & al.

ErymMo.Loey: Greek, meso- meaning middle- + Latin, -corynespora, referring to the

genus Corynespora.
CONIDIOPHORES short, single or in groups, clavate, unbranched, brown.
CONIDIOGENOUS CELLS monotretic, integrated, terminal, clavate, determinate.
Conidial secession schizolytic. Conrp1A solitary, acrogenous, dry, obclavate,
multi-euseptate.

Mesocorynespora sinensis Jian Ma, X.G. Zhang & R.F. Castafieda, sp. nov. Fics 1, 2
MB 836512

Differs from Solicorynespora spp. by its short, determinate conidiophores with multi-
euseptate conidia, and from Corynespora spp. by its euseptate conidia.

Type: China, Jiangxi Province: Lushan Mountain, on decaying culms of bamboo,
9 November 2014, J. Ma (holotype, HJAUP M0296).

ETyMoOLoGy: refers to China where the fungus was collected.

COLONIES on natural substrate effuse, brown to dark brown. Mycelium
superficial and immersed, composed of branched, septate, pale brown to
brown, smooth-walled hyphae. ConipiopHorgs short, single or in groups,
erect, straight or flexuous, clavate, unbranched, brown, smooth, 1-3-septate,
25-40 x 3.5-5 um. CONIDIOGENOUS CELLS monotretic, integrated, terminal,
determinate, clavate, brown, smooth, 9-14.5 x 5-6.5 um. Conidial secession
schizolytic. Conrp14 solitary, dry, acrogenous, obclavate, smooth, brown
to dark brown, rounded and golden yellow at the apex, truncate at the base,
20-35-euseptate, 72-171 x13.5-16 um, tapering to 7-10.5 um diam. at the
apex, 4-5 um diam. at the base.

Discussion
Mesocorynespora sinensis is unique in having short, clavate, unbranched
conidiophores, and solitary, acrogenous, obclavate, multi-euseptate conidia

Mesocorynespora sinensis gen. & sp. nov. (China) ... 619

B

wig]

Fic. 1. Mesocorynespora sinensis (holotype, HJAUP M0296).
A. Developing conidia; B. Conidiophores with developing conidia;
C. Conidiophores, and conidiogenous cells.

620 ... Xu &al.

B

20um

20um

20um

Fic. 2. Mesocorynespora sinensis (holotype, HJAUP M0296).
A-C. Conidiophores, conidiogenous cells, and conidia; D. Conidia.

that secede schizolytically from the monotretic, integrated, terminal,
determinate conidiogenous cells. We initially thought of assigning it to the
genus Solicorynespora R.F. Castafteda & W.B. Kendr. (Castafeda-Ruiz &
Kendrick 1990), but Solicorynespora species have long, cylindrical to obclavate
conidiophores with percurrently extending conidiogenous cells and conidia
with fewer septa.

Several other genera including Corynespora Giissow, Corynesporella Munjal
& H.S. Gill, Hemicorynespora M.B. Ellis, Corynesporopsis P.M. Kirk, and
Corynesporina Subram. (Giissow 1905, Munjal & Gill 1961, Ellis 1972, Kirk
1981, Gams & al. 2009) have the same conidiogenesis as Mesocorynespora, but
Mesocorynespora differs in having clavate, determinate conidiogenous cells

Mesocorynespora sinensis gen. & sp. nov. (China) ... 621

formed from short, clavate, unbranched conidiophores; and differs further
from Corynespora, Corynesporella, and Corynesporina by its euseptate conidia
and from Corynesporopsis by its solitary conidia. Conidia in Hemicorynespora
are 0-1-septate, an obvious difference from Mesocorynespora.

Key to Mesocorynespora and morphologically similar genera

1. Conidiophores short, conidiogenous cells

Wwithoutpercurtent extension § 2.25. 51.5 aed ng ee eee Mesocorynespora
1. Conidiophores long, conidiogenous cells with percurrent extension............ 2
2sConidig-aseptate oreuseptate 6 hic. wie tae ok ete whom ce ery ee pA eg 3
DAG QIN IC AGH SEOSCDLALEY tsi age ber sel gia cite ages ses soneet vara a wtbeneed ac seet astt 9 wiica byeUe Ey arise AAs ae 5
8 Conidia-catenates si 4 ous. trons Hd nh Fed Wee Ek ee OREO Corynesporopsis
SiS onidia-solitaryes tan te shaes bot atethe ue ae kone ane tena ee ec eaece 4
4. Conidia aseptate or with a single septum ..................... Hemicorynespora
A ONIdia tWO*.t6-pIMPISeptaler sce. anesthe a ants cs Ee oh Solicorynespora
5. Conidiogenous cells formed as terminal and lateral branchlets

On The CONIMIGPROTES srecse.t, sto. ste str somese neat ob Hen ge ae eeaE ste taba cae Corynesporella
5. Conidiogenous cells integrated, terminal on the conidiophores ................ 6
6. Gonidia formed'singlé or in.acropetal chains’ 2: ..0.25 4.5 orc mesees Corynespora
6. Conidia solitary and in basipetal chains .....................4.. Corynesporina

Acknowledgments

The authors express gratitude to Dr. Patricia Oliveira Fiuza (Programa de Pos-
graduacao em Sistematica e Evolu¢gao, Universidade Federal do Rio Grande do
Norte, Brazil) and Dr. De-Wei Li (The Connecticut Agricultural Experiment Station
Valley Laboratory, USA) for serving as pre-submission reviewers and to Dr. Shaun
Pennycook for nomenclatural review and Dr. Lorelei L. Norvell for editorial review.
This project was supported by the National Natural Science Foundation of China
(Nos. 31970018, 31360011, 31870016), and the Education Department of Jiangxi
Province of China (No. GJJ160357).

Literature cited

Ai CC, Ma J, Zhang K, Castaneda-Ruiz RF, Zhang XG. 2019. Cordana meilingensis and
C. lushanensis spp. nov. from Jiangxi, China. Mycotaxon 134: 329-334.
https://doi.org/10.5248/134.329

Castafieda-Ruiz RE, Kendrick B. 1990. Conidial fungi from Cuba: II. Univ. University of
Waterloo Biology Series 33. 61 p.

Ellis MB. 1972. Dematiaceous hyphomycetes. XI. Mycological Papers 131. 25 p.

Gams W, Seifert KA, Morgan-Jones G. 2009. New and validated hyphomycete taxa to resolve
nomenclatural and taxonomic issues. Mycotaxon 110: 89-108. https://doi-org/10.5248/110.89

Giissow HT. 1905 [”1904”]. Notes on a disease of cucumbers, II. Journal of the Royal Agricultural
Society of England 65: 271-272.

622 ... Xu &al.

Kirk PM. 1981. New or interesting microfungi IH. Dematiaceous hyphomycetes from
Esher Common, Surrey. Transactions of the British Mycological Society 77: 279-297.
https://doi.org/10.1016/S0007-1536(81)80031-9

Ma J. 2016. Corynesporopsis obclavata and Stanjehughesia jiangxiensis spp. nov. from Lushan
Mountain, China. Mycotaxon 131: 583-588. https://doi.org/10.5248/131.583

Ma J, Zhang XG. 2015. A preliminary report of dematiaceous hyphomycetes from
dead branches in Jiangxi Province. Biological Disaster Science 38(4): 290-293.
https://doi.org/10.3969/j.issn.20953704.2015.04.003

Ma J, Zhang XG, Castafieda-Ruiz RE 2016. Podosporiopsis, a new genus of synnematous
hyphomycetes from China. Mycotaxon 131: 773-780. https://doi.org/10.5248/131.773

Munjal RL, Gill HS. 1961. Corynesporella: a new genus of hyphomycetes. Indian Phytopathology
14(1): 6-9.

Seifert K, Morgan-Jones G, Gams W, Kendrick B. 2011. The genera of hyphomycetes. CBS
Biodiversity Series 9. 997 p.

Xu ZH, Hu DM, Luo YQ, Ma J. 2017. Three species of Linkosia and Spadicoides new to China.
Mycotaxon 132: 243-250. https://doi.org/10.5248/132.243

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 623-630
https://doi.org/10.5248/135.623

Corynesporopsis hainanensis sp. nov.,
a bambusicolous fungus from southern China

ZHAO-HUAN Xu’, XU-GEN SHI’, WEI-GANG KUANG’,
X1u-Guo ZHANG’, RAFAEL F. CASTANEDA-RuiIz}, JIAN Ma'*

' College of Agronomy, Jiangxi Agricultural University, Nanchang, Jiangxi 330045, China

? Department of Plant Pathology, Shandong Agricultural University,
Taian, Shandong 271018, China

3 Instituto de Investigaciones Fundamentales en Agricultura Tropical Alejandro de Humboldt
(INIFAT), Académico Titular de la Academia de Ciencias de Cuba,
Calle 1 Esq. 2, Santiago de Las Vegas, C. Habana, Cuba, C.P. 17200

* CORRESPONDENCE TO: majian821210@163.com jxaumj@126.com

ABSTRACT—A new anamorphic species, Corynesporopsis hainanensis, is described and
illustrated from dead bamboo culms collected in the tropical mountain rainforest of
Jianfengling, Hainan, China. The fungus is characterized by its terminal monotretic
conidiogenous cells with catenate, obclavate, brown to pale brown, smooth,
(3-)5-6(-10)-euseptate conidia. A dichotomous key and a synoptic table to Corynesporopsis
species are provided.

KEY worps—asexual fungi, hyphomycetes, saprobes, taxonomy, Xylariales

Introduction

Taking into account its large area, varied geographical conditions and
advantageous natural environments, China is considered an important
reservoir of the original bamboo diversity (Yang & Xue 1998). Its bamboo
forest ecosystems offer favorable habitats for survival and multiplication of
bambusicolous fungi. However, our knowledge of bambusicolous fungi is
scant, and relatively little information about their taxonomy has been published
in China (e.g. Zhou & al. 2001, Xu & al. 2006, 2007, Ma 2016). During our
ongoing surveys of saprobic microfungi associated with plant debris, we

624 ... Xu &al.

collected on dead bamboo culms an interesting hyphomycete with the typical
morphological features of Corynesporopsis P.M. Kirk (Kirk 1981a). The fungus,
significantly different from previously described taxa, is proposed here as new
to science.

Materials & methods

Samples of litter were placed in paper and plastic bags, taken to the laboratory, and
prepared according to Castafeda-Ruiz & al. (2016). Mounts were prepared in PVL
(polyvinyl alcohol and lactic acid) and measurements were made at a magnification
of x1000. Micrographs were obtained with a Nikon Eclipse 80i microscope equipped
with bright field and Nomarski interference optics. The type specimen was deposited in
the Herbarium of Jiangxi Agricultural University, Nanchang, Jiangxi, China (HJAUP).

Taxonomy

Corynesporopsis hainanensis Z.H. Xu, Jian Ma, X.G. Zhang &
R.F. Castafieda, sp. nov. Fig. 1
MB 836568

Differs from Corynesporopsis curvularioides, C. iberica, and C. rionensis by its
(3-)5-6(-10)-euseptate obclavate conidia; from C. iberica by its wider conidia; and from
C. curvularioides and C. rionensis by its longer and narrower conidia.

Type: China, Hainan Province, Jianfengling National Nature Reserve, on dead culms of
bamboo, 18 April 2014, J. Ma (Holotype, HJAUP M0377).

EryMo.oey: refers to the province where the type was collected.

CoLonigs on dead wood effuse, dark brown to black, hairy. Mycelium partly
superficial, partly immersed in the substratum, composed of branched, septate,
pale brown to brown, smooth hyphae. ConrpiopHor:s differentiated, single,
erect, unbranched, straight or slightly flexuous, brown to dark brown, smooth,
septate, 45-62 x 5.5-6.5 um, thick-walled. CONIDIOGENOUS CELLS monotretic,
integrated, terminal, determinate, cylindrical, brown, smooth, 10-13 um long,
4.5-5.5 um wide. Conidial secession schizolytic. CONIDIA acrogenous, catenate,
in unbranched, acropetal chains, obclavate, straight or curved, brown to pale
brown, smooth, (3-)5-6(-10)-euseptate, 17-48 um long, 6.5-8 um diam. in the
broadest part, 2-3 um diam. at the truncate base.

Dissussion

Corynesporopsis was established by Kirk (198la) with Corynespora
quercicola Borowska [= Corynesporopsis quercicola (Borowska) P.M. Kirk]
as the type species, and was mainly characterized by acrogenous, catenate,
euseptate conidia seceding schizolytically from monotretic, integrated,

Corynesporopsis hainanensis sp. nov. (China) ... 625

20 pm

Fic. 1. Corynesporopsis hainanensis (holotype, HHAUP M0377).
A, B. Conidiophores, conidiogenous cells, and conidia; C. Conidiophores; D. Conidia.

terminal, determinate or rarely percurrently extending conidiogenous cells.
It is similar to Corynespora Giissow, Corynesporella Munjal & H.S. Gill,
Hemicorynespora M.B. Ellis, Solicorynespora R.F. Castaheda & W.B. Kendr.,
and Corynesporina Subram. in having monotretic conidiogenous cells (Giissow
1905, Munjal & Gill 1961, Ellis 1972, Castafeda-Ruiz & Kendrick 1990, Gams
& al. 2009). However, Corynesporopsis differs from Hemicorynespora and
Solicorynespora by its catenate conidia and from Corynespora, Corynesporella,

626 ... Xu &al.

uteds
10

eqny
puryod
Pury
Pury

eqn)
eIpul
niog
yesnji0g
euryO
euly
elperjsny
euly
0

eqn)

Pury

KLITVOOT
AdA,

poom
peep pesiourqns

SARI] Ped

saypouRig Us}}0yY
poom 8utde0q
sayoueig peaq
sayoueiq peag

gjoned ured u3}0y
SIM] prod

gjoned ured u9}}0y
yred

soyourig prog
sayoueig prod
Ppoom prog
sayoueig prod
poom prog

SARI] Peo

poom prog

IVLIGV]

gqeize,,

UIIOFIU)

WIIOJIUL)
aiqeise,,
wWIIOJIUL)

UIIOFIU)

wWIIOJIUL)
wWIIOFIUL)
aiqerse,,

UWIIOFIU)

UWLIOJIUL)
UWIIOFIU)
UIIOFIU)

UIIOFIU)

UIIOFIU)

gqeise,,

UIIOFIU)

AOTOD)

aye}dasna-| ‘Teao 0} urro0zrAd

-qns eoripurAo “suopqo-qns ‘a}eaepoqo “prosdiyy[q

ayeydasnoa-T| ‘prosdiyytq

ayeydasna-(¢-)p—-¢
‘Teplosdiyjo Jo WUIIOFIsn} peosq “WIOFISN,]

ayejdasna-z ‘festpulpAd 0} prosdiyyja ATpeorg
ayejdasna-6-¢ ‘ayearpqo
ayeydasna-| ‘prosdiyja 0} waospNITAeN

ajeydasna-|
“WIIOJIPNITALU 9}eBUOTE IO UTIOFISHy ayesuoyy

aye}dasna-T| ‘proaogo ATpeosgq 0} prosdiyyyq
ayejdasna-| ‘a}earpyqO
ayeydasna-/-¢(-Z) ‘yestupulyAD
a}eydasna-(QT-)9-G(—-¢) ‘ayVARPGOC
ayejdasno-¢-] qeopurpé+
ayeydasna-(7-)T qeorpurpA)
ayejdasna-¢-]| ‘eprosdiyja 0} ayearppqo
ayejdasno-z Apsour JeorpurpAy

ayejdasna-(9-)s(-¢) Jeprosdiyq

aye}dasno-| ‘spua

94} Je popunos ATpeosg ‘fedtpuTfAd 0} Teprosdiy[q

NOLLVLdadS GNV dd VHS

VIGINO‘)

‘PLOT Te 29 Odessay-zopueusIey
or II86T HM cr ‘986T PATAIS Opeozay 2B PAOYAL-PAOGNTOH y “VTSGT ATEN er ‘9TOT PW cr ‘ZTOT Te 28 PN 11 *Z86T PAOYDA[-PAOGNIOH 0; ‘E861 YEA « ‘E66T PUMTYSNSIeYY
¢ ILOT [P29 ZINY-epourysey , ‘POT [E28 PIX, “6861 UOUNS . ‘E10T Te LIX, ‘8S6T SAUO{-URSIOW , ‘0661 YUIPUSY 2 ZIMY-epourysey ; ‘G{OZ IOUYSsITY , ‘Woy VIE

8-S x OI-TI
L£-G X 9I-CI

(01-6 Apsour)
II-8 X 9€-¥7

(6-)8-9 X 8I-F1(-Z1)
ZI-9 X 19-LZ
S°S-S'€ X S‘9I-OT

V9-F X SEP-LU(-¥7)
(PI-)ZI-8 x (LZ7-)P7-L1(-¥1)
S'S-P X S7-LI

D-€ X (65-)8P-ST

8-S'°9 X SP-LI

S'0I-S'L X OF-ST

S°L-9 X S07-S°7I

LI-Z X S€-ST

6-L X €€-8T

8-S X (€€-)8T-1Z

(S°S-)S(-S'F) X €T-II(-OT)
(um) azIs

or SI[IQUIADA “2

<p DIDIdasIUN *D

71 SISUUOLL *D)
ep bjoot4anb “4
2, VIVAVIIGO *D

11 SHvquippinby “D

or 2VINJAQUSI *D)

« PIIPUL “D
bIvidasinbavut *D
, botdagt “2D
sisuauvurvy *D

9 91409909 *D)

¢ DILApurfAd “D

, SOPIOLADINAAN *F+)

€ vjvjdasiq 0)

- BUDyyIUD “D

7 PVIIVDID *)

SaIOddS

‘JUOJ PJOq UT Jas st satdads Mau ay], ‘sodeds sisdosodsaud10+ Jo saye1jsqns pure eIpruod Jo suostieduroy 1 ATAVI,

Corynesporopsis hainanensis sp. nov. (China) ... 627

and Corynesporina by its euseptate conidia. Corynesporopsis is also similar to
Heteroconium Petr. (Petrak, 1949) in having catenate, euseptate conidia, but
Heteroconium is separated by monoblastic conidiogenesis.

Although Corynesporopsis was placed in Xylariales (Sordariomycetes) based
on ITS and LSU rDNA based phylogenetic studies of C. acaciae R. Kirschner,
its family remains incertae sedis due to its tretic conidiogenesis, previously
unrecorded for Xylariales (Kirschner 2015). Teleomorphs and phylogenetic
affinities with other Corynesporopsis species are not yet known.

Among the known species of Corynesporopsis, only C. curvularioides J.W.
Xia & X.G. Zhang (Xia & al. 2013), C. iberica R.F. Castafieda & al. (Castaneda-
Ruiz & al. 2011), and C. rionensis Hol.-Jech. (Holubova-Jechova & Mercado
Sierra 1986) are comparable to C. hainanensis. However, C. curvularioides
differs in its obclavate to ellipsoidal, shorter and wider conidia with 1-5
eusepta; C. iberica differs in its cylindrical, narrower conidia with (2-)3-7
eusepta; while C. rionensis differs in its wider fusiform, broadly fusiform, or
ellipsoidal conidia with 3—4(-5) eusepta.

With the addition of C. hainanensis, Corynesporopsis currently contains 17
species. A synopsis for comparisons of conidia and substrates of these accepted
species is presented in TABLE 1. The conidia of these 17 Corynesporopsis
species are mostly ellipsoidal, cylindrical, obclavate, or fusiform, but conidia
may also be obovoid, naviculiform, sub-oblong, sub-pyriform, or oval. The
conidia are mostly unicolored, but C. antillana R.F. Castaheda & W.B. Kendr.,
C. inaequiseptata Matsush., C. quercicola, and C. variabilis R.F. Castaneda & al.
produce versicolored conidia. Eight species produce predominately 1-septate
conidia, usually thickened and darkened at the septa—C. acacia, C. cylindrica
B. Sutton, C. indica P.M. Kirk, C. isabelicae Hol.-Jech., C. liquidambaris Jian Ma
& X.G. Zhang, C. uniseptata P.M. Kirk, C. inaequiseptata, and C. variabilis—
while the other Corynesporopsis species produce conidia with more septa.
All species were found as saprobes on bark, decaying leaves, rotten wood,
or dead palm rachides in terrestrial environments, except for C. variabilis on
submerged dead wood. Fourteen species definitely produce smooth-walled
conidia; the conidial ornamentation of the other three species (C. uniseptata,
C. curvularioides and C. excoecariae J.W. Xia & X.G. Zhang) is inexplicably
omitted in their original descriptions (Kirk 1981b, Xia & al. 2013, 2014).

Keys to species of Corynesporopsis have been provided by Castafieda-
Ruiz & al. (2011) and Hernandez-Restrepo & al. (2014), based on conidial
morphology. The following expanded key includes all 17 accepted
Corynesporopsis species.

628 ... Xu &al.

Key to Corynesporopsis species

lConidiazpredomirianthyslvetiseptat]e mo icnst etree Bl Me inte ge Pee ls kos 2
t.. Conidia: predominantly 2 or more septas a... nx esses eu ekg Adages aed wits 9
2. Conidia versicoloraus 1... benaeahoaceles dee hee bodes ee Se ee oe 3
ae Conidia cOnCOlOKOUS *. dasisrect othe eristhy tds oryp raat agrees: Setincapeds So aghast 4
3. Conidia obclavate, 17-25 x 4-5.5 um ....... eee eee eee C. inaequiseptata
3. Conidia variable ellipsoid, obclavate, sub-oblong, cylindrical,

sub-pyriform to-ovakl 1-16 x 5-8-2 ets 2 sages Ae C. variabilis
4, Conidia (14—)17-24(-27) x 8-12(-14) um ..... eee eee C. indica
4, COnidia-Mot.exceecin et: Ziaafltiy CIA. 04,5 ween Ra thane Game cae ee Re ees 5
5. Conidia (24-)27-43.5 x 4-6.4 um,

elongate fusiform or elongate naviculiform ....................-. C. isabelicae
5; Gonidia net exceedine 20%s:1itin lone: 8:2 534/22 Renee a Ss ee Age Soe Feasts St 6
6; Gonidia stricthreyiindnicaltorcellipsoidal *: .e Sacg td non pate ae Ad «oes 7
6. Conidia ellipsoidal to cylindrical, or naviculiform to ellipsoid .................. 8
7: Gonidia.cylindrical, 12-5520. 56 —Z, Sat eects ag cess ata PAS Coane C. cylindrica
7. Gonidiaellipsoidal, 12-16 537M «bso ot ox eels fee eae C. uniseptata
8. Conidia ellipsoidal to cylindrical, (10-)11-13 x (4.5-)5(-5.5) um ...... C. acaciae
8. Conidia naviculiform to ellipsoid, 10-16.5 x 3.5-5.5 um ......... C. liquidambaris
OF OMIA VEESICOlOTOUS Ss. bet oc. 2 percus dete cee P es oe oa scene eee SC Pu, ye 2 es. AR 10
9 Conidia concolorous. .4)..2 je eres eget epee beg ee ee ee 11
10. Conidia ellipsoidal, 21-28(-33) x 5-8 um, (3-)5(-6)-euseptate ...... C. antillana
10. Conidia broadly ellipsoid to cylindrical,

(12-)14-18 x 6-8(-9) um, 2-euseptate ............... 0... eee C. quercicola
WiGonidiacylindri¢al™ 2.52.6. hae tse ee tae twee He ee ee crows es 12
11. Conidia fusiform, ellipsoidal, obclavate, or obclavate to ellipsoidal ............ 14
12. Conidia 15-48(-59) x 3-4 um, (2-)3-7-euseptate ................00.. C. iberica
2 Conidia-aVleastfpmiewide, 2.2 Filet ce feta en hse ide, Wet eh Pane ence ik eee 13
13. Conidia 18-33 x 7-9 um, mostly 2-euseptate ...................0.. C. biseptata
13. Conidia 15-40 x 7.5-10.5 um, 1-3-euseptate .................... C. excoecariae
14:-Conidia strictly obclavate: «+3 tesco nay thtmadia ds apie angccedempa eae ghneme 4 15
14. Conidia fusiform, ellipsoidal, or obclavate to ellipsoidal ..................... 16
15. Conidia 17-48 x 6.5-8 um, (3-)5-6 (-10)-euseptate .............. C. hainanensis
15. Conidia 27-61 x 6-12 um, 5-9-euseptate .......... eee ee eee C. obclavata

16. Conidia obclavate to ellipsoidal,

1539: 7511 um, J SFetseptate: 8.6 era ee Fa thane vale ones C. curvularioides
16. Conidia fusiform or ellipsoidal,

24-36 x 8-11 (mostly 9-10) um, 3-4(-5)-euseptate .............. C. rionensis

Corynesporopsis hainanensis sp. nov. (China) ... 629

Acknowledgments

The authors express gratitude to Dr. De-Wei Li (The Connecticut Agricultural
Experiment Station Valley Laboratory, USA) and Dr. Silvana Santos Da Silva
(Departamento de Ciéncias Bioldgicas, Laboratério de Micologia, Universidade
Estadual de Feira de Santana, Brazil) for serving as pre-submission reviewers and
to Dr. Lorelei L. Norvell for final editorial review and Dr. Shaun Pennycook for
nomenclatural review. This project was supported by the National Natural Science
Foundation of China (Nos. 31970018, 31760513, 31360011) and the Education
Department of Jiangxi Province of China (No. GJJ160357).

Literature cited

Castafieda-Ruiz RE, Kendrick B. 1990. Conidial fungi from Cuba: II. University of Waterloo
Biology Series 33. 61 p.

Castafieda-Ruiz RF, Silvera-Sim6n C, Gené J, Guarro J, Minter DM, Stadler M, Saikawa M.
2011 [“2010”] A new species of Corynesporopsis from Portugal. Mycotaxon 114: 407-415.
https://doi.org/10.5248/114.407

Castaneda-Ruiz RF, Heredia G, Gusmao LFP, Li DW. 2016. Fungal diversity of Central and
South America. 197-217, in: DW Li (ed.). Biology of Microfungi. Springer International
Publishing. https://doi.org/10.1007/978-3-319-29137-6_9

Ellis MB. 1972. Dematiaceous hyphomycetes. XI. Mycological Papers 131. 25 p.

Giissow HT. 1905 [“1904”]. Notes on a disease of cucumbers, II. Journal of the Royal
Agricultural Society of England 65: 271-272.

Gams W, Seifert KA, Morgan-Jones G. 2009. New and validated hyphomycete
taxa to resolve nomenclatural and taxonomic issues. Mycotaxon 110: 89-108.
https://doi.org/10.5248/110.89

Hernandez-Restrepo M, Gené J, Castafieda-Ruiz RF, Kirk PM, Guarro J. 2014. A new species
of Corynesporopsis from Spain. Mycotaxon 127: 155-160. https://doi.org/10.5248/127.15

Holubova-Jechova V. 1987. Studies on hyphomycetes from Cuba VI. New and rare species with
tretic and phialidic conidiogenous cells. Ceska Mykologie 41(2): 107-114.

Holubova-Jechova V, Mercado Sierra A. 1986. Studies on hyphomycetes from Cuba IV.
Dematiaceous hyphomycetes from the Province Pinar del Rio. Ceska Mykologie 40(3):
142-164.

Kirk PM. 1981la. New or interesting microfungi II. Dematiaceous hyphomycetes from
Esher Common, Surrey. Transactions of the British Mycological Society 77: 279-297.
https://doi.org/10.1016/S0007-1536(81)80031-9

Kirk PM. 1981b. New or interesting microfungi III. A preliminary account of microfungi
colonizing Laurus nobilis leaf litter. Transactions of the British Mycological Society 77:
457-473. https://doi.org/10.1016/S0007-1536(81)80093-9

Kirk PM. 1983. New or interesting microfungi VII. Corynesporopsis indica sp. nov. Mycotaxon
17: 405-408.

Kirschner R. 2015. Phylogenetic placement of a new species of Corynesporopsis from dead
acacia wood indicates occurrence of tretic conidiogenesis within Xylariales. Phytotaxa 192
(1): 24-34. https://doi.org/10.11646/phytotaxa.192.1.3

Ma J. 2016. Corynesporopsis obclavata and Stanjehughesia jiangxiensis spp. nov. from Lushan
Mountain, China. Mycotaxon 131(3): 583-588. https://doi.org/10.5248/131.583

630 ... Xu & al.

Ma J, Ma LG, Zhang YD, Castafieda-Ruiz RE, Zhang XG. 2012. New species and record of
Corynesporopsis and Hemicorynespora from southern China. Nova Hedwigia 95(1-2):
233-241. https://doi.org/10.1127/0029-5035/2012/0030

Matsushima T. 1993. Matsushima Mycological Memoirs No. 7. Published by the author, Kobe,
Japan.

Morgan-Jones G. 1988. Notes on hyphomycetes. LVII. Corynespora biseptata, reclassified in
Corynesporopsis. Mycotaxon 31(2): 511-515.

Munjal RL, Gill HS. 1961. Corynesporella: a new genus of hyphomycetes. Indian Phytopathology
14: 6-9.

Petrak F. 1949. Neue hyphomyzeten-gattungen aus Ekuador. Sydowia 3: 259-266.

Sutton BC. 1989. Notes on deuteromycetes. II. Sydowia 41: 330-343.

Xia JW, Ma LG, Ma YR, Castafieda-Ruiz RF, Zhang XG. 2013. Corynesporopsis curvularioides
sp. nov. and new records of microfungi from southern China. Cryptogamie, Mycologie
34(3): 281-288. https://doi.org/10.7872/crym.v34.iss3.2013.281

Xia JW, Ma YR, Zhang XG. 2014. New species of Corynesporopsis and Lylea from China.
Sydowia 66 (2): 241-248. https://doi.org/10.12905/0380.sydowia66(2)2014-0241

Xu MQ, Dai YC, Fan SH, Jin LX, Lu Q, Tian GZ, Wang LF. 2006. Records of bamboo diseases
and the taxonomy of their pathogens in China (I). Forest Research 19(6): 692-699.

Xu MQ, Dai YC, Fan SH, Jin LX, Lu Q, Tian GZ, Wang LF. 2007. Records of bamboo diseases
and the taxonomy of their pathogens in China (II). Forest Research 20(1): 45-52.

Yang YM, Xue JR. 1998. Bamboo resources and their utilization in China. In: Proceedings
of the Workshop Bamboo Conservation, Diversity, Ecogeography, Germplasm, Resource
Utilization and Taxonomy. Kunming and Xishuangbanna, Yunnan, China.

Zhou DQ, Hyde KD, Wu XL. 2001. New records of Ellisembia, Penzigomyces, Sporidesmium and
Repetophragma species on bamboo from China. Acta Botanica Yunnanica 23(1): 45-51.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 631-635
https://doi.org/10.5248/135.631

Hymenochaete longisterigmata sp. nov. from India

NAVPREET KAUR, AVNEET PAL SINGH*, GURPAUL SINGH DHINGRA

Department of Botany, Punjabi University, Patiala-147002, Punjab, India.

*CORRESPONDENCE TO: avneetbot@gmail.com

ABSTRACT—A new hymenochaetoid species, Hymenochaete longisterigmata, is described
from Himachal Pradesh, India.

Keyworps—Basidiomycota, Hymenochaetales, Hymenochaetaceae, Himalaya

Introduction

During the 2014 fungal forays conducted in the Narkanda area of district
Shimla, Himachal Pradesh, India, Navpreet & Dhingra collected a fungal
specimen on the branch of a living tree of Picea smithiana. This fungus was
again collected (2016) in the Jalori Pass area of district Kullu, Himachal Pradesh,
India, by Navpreet & Avneet on the branch of a living Quercus semecarpifolia.
Based on the comparison of morphological characters (Cunningham 1963,
Sharma 1995 & 2012, Natarajan & Kolandavelu 1998, Bernicchia & Gorjon
2010, Dai 2010, Kaur & al. 2015, Sharma & Mishra, 2015, Mycobank 2019), we
referred the specimens to Hymenochaete Lév. (Hymenochaetaceae) and close
to H. corrugata (Fr.) Lév. based on its resupinate, adnate basidiomata, heavily
cracked hymenial surface, and presence of abundant setae with encrusted
apices. We now propose the fungus as a new species H. longisterigmata, named
in reference to its exceptionally long sterigmata.

Materials & methods

The present study is based on fungal samples collected during the field trips
conducted in Narkanda (District Shimla) and Jalori Pass (District Kullu) forest areas of
Himachal Pradesh during September 2014 and 2016. Colours terms follow Kornerup

632 ... Kaur, Singh, Dhingra

& Wanscher (1978). After removing any extraneous matter, we dried the specimens
in the sun or with a portable electric drier. The dried specimens were deposited at the
internationally recognized herbarium of Department of Botany, Punjabi University,
Patiala, India (PUN). The arrangement, size and shape of hyphae, sterile structures,
basidia, and basidiospores were studied by making crush mounts and free hand
sections in water, KOH (3%/5%/10%), 1% Congo red, 1% phloxine, cotton blue (15
in Lactophenol), and Melzer’s reagent. We examined the material microscopically
at 100x, 400x and 1000x magnifications using a compound microscope and drew
structural line diagrams on white paper sheets with the aid of a camera lucida.
Photomicrographs of important structures were taken using a Nikon 80i Eclipse
microscope.

Taxonomy

Hymenochaete longisterigmata Nav. Kaur, Avn.P. Singh &
Dhingra, sp. nov. PLATE 1
MB 832678
Differs from Hymenochaete corrugata by its thick-walled hyphidia, its larger basidia
with long sterigmata, and its broadly ellipsoid basidiospores.

Type: India, Himachal Pradesh, Shimla, Narkanda, about 3 Km from Narkanda towards
Baghi, on branch of living tree of Picea smithiana (Wall.) Boiss., 4 September 2014,
Navpreet & Dhingra 9689 (Holotype, PUN).

Etrymo.oey: The specific epithet refers to the long sterigmata.

Basidiomata annual, resupinate, <2 mm thick in section, adnate, soft and
corky when collected, hard and corky after drying; hymenial surface smooth
to somewhat aculeate under lens, cracked, greyish orange to greyish brown
when collected, no significant change after drying; margins thinning,
indeterminate, paler concolorous, sterile portion <0.5 mm. Hyphal system
monomitic. Subicular hyphae brown, heavily encrusted, up to 6.3 um wide;
subhymenial hyphae subhyaline to yellowish brown, up to 3.4 um diam.
Setae subulate, apices straight with crystalline encrustation, dark brown,
abundant, thick-walled, 68-92 x 11.4-20 um; arising from the subhymenium,
extending through hymenium, projecting <52 um above the hymenium.
Hyphidia subfusiform with moniliform apices, yellowish brown, abundant,
thick-walled, 20-34 x 4.2-5.2 um; arising from the top of subhymenium and
base of hymenium. Basidia narrowly clavate to subcylindrical, subhyaline,
thin-walled, tetrasterigmate, 22-30 x 2.8-4.6 um; sterigmata <17.2 um long.
PLATE 1. Hymenochaete longisterigmata (holotype, PUN - Navpreet & Dhingra 9689).
1. Basidiocarp showing hymenial surface; 2. Basidiospores; 3. Vertical section through

basidiocarp showing: a. basidia; b. hyphidia; c. setae; d. subhymenial hyphae; 4. Subicular hyphae;
5. Basidium; 6. Setae.

Hymenochaete longisterigmata sp. nov. (India) ... 633

~S

el [p> ow
ty NX Ey. xX) [=
S
N/Zty
YP
“9

634 ... Kaur, Singh, Dhingra

Basidiospores broadly ellipsoid, subhyaline, smooth, thin-walled, 4-5.1 x 2.8-
3.4 um, inamyloid, acyanophilous.

ADDITIONAL SPECIMEN EXAMINED: INDIA, HIMACHAL PRADESH, Kullu, about 3 km
from Jalori Pass towards Shoja, on branch of living tree of Quercus semecarpifolia Sm., 3
September 2016, Navpreet & Avneet 9688 (PUN).

Discussion

Hymenochaete (Hymenochaetaceae) is a widespread genus with c. 350
published species names and c. 150 currently accepted species (Kirk & al.
2008, Index Fungorum 2019, MycoBank 2019). The earliest record of this
genus from India was by Montagne (1842), who described Stereum rheicolor
[= H. rheicolor| from Gudalur, Nilgiri Hills, Tamil Nadu. Until our report,
40 Hymenochaete taxa were reported from India.

Wagner & Fischer (2002) inferred phylogenetic relationships from DNA
sequence data for several Hymenochaete species. Their phylogeny supporting
traditional Hymenochaete species in two genera, they described the new genus
Pseudochaete T. Wagner & M. Fisch. The two genera are not easily distinguished
by morphology alone. The new species described here has not been sequenced
and is therefore referred to Hymenochaete s.1.

Acknowledgments

Thanks are due to Head, Department of Botany, Punjabi University, Patiala,
for providing research facilities and University Grants Commission, New Delhi,
for financial support under UGC DRS-SAP, DSA-I programme. We also thank
Dr. Nils Hallenberg (Professor Emeritus, University of Gothenberg) for expert
comments and peer review and Prof. B.M. Sharma (Department of Plant Pathology,
COA, CSKHPAU, Palampur, India) for peer review.

Literature cited

Bernicchia A, Gorjoén SP. 2010. Corticiaceae s.l. Fungi Europaei 12. Edizioni Candusso.
Alassio, Italia. 1008 p.

Cunningham GH. 1963. The Thelephoraceae of Australia & New Zealand. Bulletin of the New
Zealand Department of Scientific and Industrial Research 145. 359 p.

Dai YC. 2010. Hymenochaetaceae (Basidiomycota) in China. Fungal diversity 45: 131-343.
https://doi.org/10.1007/s13225-010-0066-9

Index Fungorum. 2019. Search Index Fungorum. Accessed September, 2019:
http://www.indexfungorum.org/names/Names.asp

Kaur N, Sharma J, Singh AP, Dhingra GS. 2015. Additions to genus Hymenochaete Lév. from
Himachal Pradesh. International Journal of Advanced Research 3(5): 836-843.

Kirk PM, Cannon PEF, Minter DW, Stalpers JA. 2008. Ainsworth & Bisby’s
dictionary of the fungi, 10" ed. CAB International, Wallingford, UK. 770 p.
https://doi.org/10.1079/978085 1998268.0000

Hymenochaete longisterigmata sp. nov. (India) ... 635

Kornerup A,Wanscher JH. 1978. Methuen’s handbook of colour, 3rd ed. Methuen & Co. Ltd.
London. 252p.

Montagne JPFC. 1842. Cryptogamae Nilgherienses. Annales des Sciences Naturelles, Botanique
sér., 18: 12-23.

Mycobank. 2019. Hymenochaete. Website accessed 11/03/2019:
http://www.mycobank.org/Biolomics.aspx? Table=Mycobank&Rec=56728&Fields=All

Natarajan K, Kolandavelu K. 1998. Resupinate Aphyllophorales of Tamil Nadu, India. Centre for
Advanced Study in Botany, University of Madras, Chennai. 133 p.

Sharma JR, Mishra D. 2015. A synoptic mycoflora of wood-rotting fungi of Andaman. Nelumbo.
57: 1-30.

Sharma JR. 1995. Hymenochaetaceae of India. Botanical Survey of India, Ministry of
Environment & Forests, Calcutta. 219 p.

Sharma JR. 2012. Aphyllophorales of Himalaya (Auriscalpiaceae - Tremellodendropsis).
Botanical Survey of India, Ministry of Environment & Forests, Kolkata. 590 p.
https://doi.org/10.20324/nelumbo/v57/2015/87118

Wagner T, Fischer M. 2002. Classification and phylogenetic relationships of Hymenochaete
and allied genera of the Hymenochaetales, inferred from rDNA sequence data and
nuclear behavior of the vegetative mycelium. Mycological Progress 1: 93-104.
https://doi.org/10.1007/s11557-006-0008-9

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 637-647
https://doi.org/10.5248/135.637

Entoloma conferendum, Hygrocybe coccineocrenata,
and Hypholoma ericaeum new to Montenegro

ILINKA CETKOVIG ', ZDENKO TKALGEC 2’, SNEZANA DRAGICEVIG *,
ANTUN ALEGRO 3, VEDRAN SEGOTA 3, MARGITA JADAN 2, NEVEN MATOCGEC ?,
IVANA KUSAN 2, ZELJKO ZGRABLIG 4, ARMIN MESIG 2

' Natural History Museum of Montenegro,
Trg Vojvode Becir bega Osmanagica 16, 81000 Podgorica, Montenegro

? Ruder Boskovicé Institute, Bijenicka cesta 54, 10000 Zagreb, Croatia

> Department of Botany, Faculty of Science, University of Zagreb,
Marulicev trg 20/II, 10000 Zagreb, Croatia

* Croatian Research Forest Institute, Research Centre for Forest Ecosystem Goods &
Services Josip Ressel, 154. brigade Hrvatske vojske 2, 52000 Pazin, Croatia

* CORRESPONDENCE TO: Ztkalcec@irb.hr

ABSTRACT—As a result of the first research on macrofungi on peat moss habitats
in Montenegro, three species new to the Montenegrin mycobiota are presented and
described: Entoloma conferendum, Hygrocybe coccineocrenata, and Hypholoma ericaeum.
The descriptions are accompanied by photographs of the basidiomata on site and some
microscopic characters. Additionally, the second Montenegrin record of Bovista paludosa
is presented and described, for the first time with locality and habitat data. Species
identifications were checked by comparing ITS rDNA sequences from samples with the
sequences in GenBank.

Key worps—Agaricales, Basidiomycota, biodiversity, taxonomy

Introduction

Sphagnum (peat moss) is a genus with several hundred species that live in
wet habitats and can store water in their cells. The most important habitats
are peat bogs, where due to constant water availability and oxygen reduction,
peat sediments form by the accumulation of the partially decomposed plant
remnants. Peat bogs are characterised by acidic soils, low nutrient content,

638 ... Cetkovié & al.

and dominance of peat mosses. These habitats, which form in humid and
cold climates, are widely distributed in northern parts of Asia, Europe, and
North America. However, despite a still favourable climate, natural peatlands
are vanishing from northern Europe due to human activities such as peat
extraction, drainage, and land development. In the western Balkans, primarily
due to unfavourable climate conditions, peat bogs are exceptionally rare and
relict habitats, occupying only small highly isolated areas. They are particularly
sensitive to climate changes, which can cause them to dry out and become
overgrown by other vegetation types. Therefore, peat bogs are one of the
most endangered ecosystems in Montenegro. Some macrofungal species live
exclusively in this type of habitat, but a certain number of fungi with a wider
habitat tolerance can also be found in peat bogs. Peat mosses can also live in
wet, acidic habitats without forming peat, mostly in coniferous forests.

Due to the small number of researchers, Montenegrin fungi, including
agarics, are rather poorly explored. Kasom (2013) lists 839 macro-basidiomycete
species for Montenegro, 444 of which belong to the Agaricales. Bubak (1915),
who conducted the first mycological research on Montenegrin peat bogs
in 1904, reported several microfungi from the Barno jezero peat bog (Mt.
Durmitor). However, until our research, no macrofungi had been reported in
peat bogs of Montenegro. During the summer and autumn of 2017 and 2018
we surveyed macrofungi of mountain peat bogs and peat moss carpets on Mt.
Sinjajevina, Mt. Durmitor, and Mt. Hajla. We describe three Agaricales species
new to Montenegrin mycobiota, as well as one previously reported rare species
with the first data on its locality and habitat in Montenegro.

Materials & methods

Collected basidiomata were photographed on the site, described, preserved by
drying and deposited in the mycological collections of Natural History Museum of
Montenegro, Podgorica (NHMP) and/or Croatian National Fungarium in Zagreb
(CNE).

The morphological descriptions are entirely based on the collected material.
Microscopic features are described from dried material mounted in 2.5% potassium
hydroxide (KOH) and observed with a light microscope under magnification up to
1500x. Basidiospore measurements were made by Motic Images Plus 2.0 software on
30 randomly chosen mature basidiospores from calibrated digital images. Arithmetic
means of basidiospore length and width are shown in italic font in the centre of the
measurements. The length/width ratio of all measured basidiospores is given as the
“Q” value (min. — av. — max.).

Genomic DNA was extracted from dried specimens using DNeasy Plant Mini
kit (Qiagen) according to the manufacturer’s instructions. PCR primers ITS1F and

Three agarics newly recorded for Montenegro ... 639

ITS4 (Gardes & Bruns 1993) were used for ITS region amplification and sequencing
purposes. The ITS rDNA regions were amplified in a thermocycler (Eppendorf) with
a final volume of 25 uL containing approximately 50 ng DNA template, 0.2 uM of
each primer, 0.2 mM dNTP, 1.5mM MgCl, 1x buffer, and 1 unit of Taq polymerase
(Invitrogen). The cycling protocol was: 94 °C for 5 min, 30 cycles (94 °C for 45,
60 °C for 45 s, 72 °C for 45 s), followed by a final extension of 72 °C for 10 min. The
PCR products were resolved on a 1% agarose gel stained with ethidium bromide
and viewed under ultraviolet light. PCR products were purified and sequenced by
Macrogen Inc. (The Netherlands). Sequences were aligned in both directions and
edited using Sequencher v.4.1.4 and submitted to GenBank.

Taxonomy

Hygrocybe coccineocrenata (P.D. Orton) M.M. Moser,
Rohrlinge & Blatterpilze, 3. Aufl.: 68 (1967). Fic. 1 A,B
PILEUS 6-23 mm broad, convex at first, later applanate to concave with a
depressed centre and mostly inflexed and somewhat crenate margin, scarlet
red, orange red or reddish orange, densely covered with small squamules or
tufts which are reddish brown to grey towards the centre and concolorous
towards the margin, not translucently striate, dry. LAMELLAE decurrent,
distant, broad, white when young, wax yellow at maturity. STIPE 25-70 x
2-5 mm, cylindrical or tapering downwards, scarlet red to orange red,
orange near the base, whitish in the base, glabrous, hollow, dry. CONTEXT
thin, pale orange red. SMELL and TASTE indistinct. SPORE-PRINT white.
BASIDIOSPORES 9.2-11-12.1 x 5.3-6.1-6.8 um, Q = 1.51-1.81-2.13,
ellipsoid to oblong, often slightly phaseoliform in side view, sometimes
with slight median constriction, thin-walled, hyaline. Basip1a 4-spored,
narrowly clavate. CysTIDIA absent. PILEIPELLIS at centre and in squamules a
trichoderm composed of ascending hyphae constricted at septa, with brown
intracellular pigment. CLAMP CONNECTIONS present.
SPECIMEN EXAMINED—MONTENEGRO, KOoLaSIN MUNICIPALITY, Mt. Sinjajevina,
Semolj saddle, 42.9092°N 19.2731°E, 1580 m as.l, in peat bog, among dense
Sphagnum subsecundum Nees peat moss with Carex lasiocarpa Ehrh. sedge, 18 July
2017, leg. S. Dragicevi¢ (NHMP 368/6986; GenBank MN082022).
ECOLOGY & DISTRIBUTION—his waxcap occurs mostly in peat bogs among
or near peat moss, but also in wet meadows. Widespread (but generally rare)
in Europe, known also from North America and Asia (Tkalc¢ec & al. 2008,
Boertmann 2010). In the surrounding countries, H. coccineocrenata is recorded
in Croatia and Serbia, and it is a strictly protected species in both countries.
New to Montenegro.

640 ... Cetkovié & al.

CoMMENTS—Hygrocybe coccineocrenata is characterised by decurrent
lamellae, predominantly red pileus and stipe (at least in young basidiomata),
darker small squamules on the pileal surface, and by living in open, wet
habitats (mostly peat bogs). It has often been confused with H. turunda
(Fr.) P. Karst., which also has darker squamules on pileus, but which differs
in its orange to orange yellow pileus and stipe ground colours and growth
in rather dry grasslands and heathlands (Boertmann 2010). Our material
fits well with the modern descriptions (e.g., Boertmann 2010, Ludwig
2012) of H. coccineocrenata. The GenBank BLAST analysis shows that our
ITS sequence is identical with one unpublished sequence (FM208899, as
“H. turunda;” Query Cover 87%), and very close to another sequence from
the same authors (FM208865, Identity > 99%, Query Cover 87%; deposited as
“H. cantharellus, but quite different from the other H. cantharellus (Schwein.)
Murrill sequences in the database). We assume that both sequences were
derived from misidentified samples. Our Montenegrin sequence is the only
GenBank entry deposited as H. coccineocrenata.

Hypholoma ericaeum (Pers.) Kihner,
Bull. Trimest. Soc. Mycol. Fr. 52: 23 (1936) FIG. 1 C-G
PiLEUs 17-60 mm broad, paraboloid to hemispherical at first, later
convex to plano-convex, often subumbonate or with central papilla,
hygrophanous, not translucently striate, brown to dark reddish brown
when moist, orange brown to ochre brown on drying, often paler near
margin in young basidiomata, surface dry to greasy, often with fine,
whitish, fibrillose veil remnants near margin in young basidiomata.
LAMELLAE narrowly adnate, subventricose to ventricose, moderately
crowded, broad, pale brownish grey when young, then mottled grey
brown, finally mottled dark purplish brown, edge whitish. STIPE 35-78 x
2-7 mm, subcylindrical, often with broadened base (up to 10 mm), solid
to fistulose, pale to medium brown, whitish at apex in young basidiomata,
surface dry, pruinose at apex, fibrillose-furfuraceous below, mostly with
white basal tomentum. CONTEXT brown in the narrow zone beneath the
pileus surface and above the lamellae, pale brown in the inner part of the
pileus, whitish to dark red brown in the stipe. SMELL fungoid. TasTE slightly
bitter. SPORE-PRINT violaceous brown. BASIDIOSPORES 12.7—13.7-15 x
7.5-8.2-8.9 um, Q = 1.56-1.67-1.83, ellipsoid, moderately thick-walled to
thick-walled, smooth, with distinct and central germ-pore, yellow brown
in KOH, light red brown in H,O. Basrp1a 4-spored, narrowly clavate or

Three agarics newly recorded for Montenegro ... 641

Fic. 1. Hygrocybe coccineocrenata (NHMP 368/6986). A. basidiomata; B. basidiospores.
Hypholoma ericaeum (NHMP 614/9034). C. basidiomata; D. basidiospores; E. cheilocystidia;
FE, G. pleurocystidia. Scale bars: A = 10 mm; C = 20 mm; B, D-G = 10 um.

642 ... Cetkovié & al.

with median constriction. CHEILOCYSTIDIA (leptocystidia type) densely
packed, forming a sterile lamellar edge, 20-45 x 5-12 um, lageniform,
narrowly utriform or subcylindrical (often with somewhat broadened
apex), sometimes forked, thin-walled, hyaline. PLEUROCYSTIDIA
(chrysocystidia type) abundant, 30-56 x 11-18 um, clavate, mostly with
mucronate apex, thin- to moderately thick-walled, hyaline with yellowish
amorphous body in alkali solution. PILEIPELLIS a cutis composed of thin-
walled, hyaline, repent hyphae. CLAMP CONNECTIONS present.

SPECIMENS EXAMINED—MONTENEGRO, KOLASIN MUNICIPALITY, Mt.

Sinjajevina, Semolj saddle, 42.9074°N 19.2758°E, 1572 ma.s.L, among Sphagnum

moss and grass on the edge of the peat bog, 15 September 2018, leg. Z. Tkaléec &
al. (CNF 1/7623, NHMP 614/9034; GenBank MN082025); (CNF 1/7628).

ECOLOGY & DISTRIBUTION— The species is saprotrophic and occurs on
peaty acid soil (mostly among mosses) and in wet poor grasslands and
moist heaths (Watling & Gregory 1987, Noordeloos 2011, Vesterholt &
Rald 2012). It is widespread all over the boreal and temperate regions of
Europe and North America (Noordeloos 2011), but usually (rather) rare.
In the surrounding countries, H. ericaeum is recorded only in Croatia
(Tkaléec & MeSi¢ 2003). New to Montenegro.

CoMMENTS—Hypholoma ericaeum is characterised by long basidiospores
(>13 um) and a hygrophanous pileus that is neither translucently striate nor
viscid. Only three other European Hypholoma species have similarly long
basidiospores (H. eximium (C. Laest.) Rald, H. myosotis (Fr.) M. Lange, and
H. udum (Pers.) Quél.), but their spore lengths reach at least 17 um and
their pilei are viscid or subviscid. Our collections correspond relatively well
with recent descriptions of H. ericaeum (Watling & Gregory 1987, Ludwig
2001, Noordeloos 2011, Vesterholt & Rald 2012). However, the maximum
stipe width of 7 mm exceeds the 4.5 mm maximum reported by Watling
& Gregory (1987), the maximum cheilocystidia width of 12 um exceeds
the 7.5 um maximum reported by Noordeloos (2011), and the maximum
pleurocystidia size of 56 x 18 um exceeds the 45 x 15 um maximum reported
by Noordeloos (2011). Moreover, Watling & Gregory (1987) described
distinctly narrower cheilocystidia (30-40 x 4-5.5 um) and pleurocystidia
(30-40 x 8-10 um). Noordeloos (2011) described somewhat flattened
basidiospores, but the spores in our collections and in the descriptions of
other cited authors are not flattened. According to the BLAST analysis,
our ITS sequence does not match any sequence in GenBank database.

Three agarics newly recorded for Montenegro ... 643

The closest sequence (96.91% identity) is derived from H. dispersum Quél.
(HQ604746). The only GenBank ITS sequence annotated as H. ericaeum
(MH856009) is genetically much more distant (84% identity). It is possible
that MH856009 was sequenced from a misidentified sample, but it is also
possible that two morphologically close species are not yet recognized as
different; further research is required.

Entoloma conferendum (Britzelm.) Noordel.,
Persoonia 10: 446 (1980) FIG. 2 A,B
= Entoloma nothofagi G. Stev., Kew. Bull. 16: 234 (1962)
= Entoloma staurosporum (Bres.) E. Horak, Sydowia 28: 222 (1976)

PiLEus 10-30 mm broad, paraboloid at first, expanding to plano-conical
or plano-convex with subumbonate centre, hygrophanous, brown with
black centre when young, later greyish brown at centre and gradually fading
to light brown towards the margin when moist, pale brownish when dry,
translucently striate up to 2/3 of the radius when moist, surface dry, glabrous.
LAMELLAE free, ventricose, broad, moderately crowded, white when
young, pink at maturity. StrpE 35-85 x 2-4 mm, cylindrical with slightly to
distinctly broadened base, densely silvery striate on pale to light grey brown
background, dry. CoNTExT thin and fragile, light grey brown. SMELL and
TASTE farinaceous. SPORE-PRINT dirty pink. BAsIDIosPORES 9.3-10.8-11.8 x
8.1-9.4-10.4 um, Q = 0.95-1.15-1.31, cruciform-stellate, thin-walled, hyaline
to pinkish. Basrp1A 4-spored, narrowly clavate. CysT1p1A absent. PILEIPELLIS
a cutis with transition to a trichoderm at centre, with intracellular brown
pigment. CLAMP CONNECTIONS absent.

SPECIMEN EXAMINED—MONTENEGRO, Rozaje MuNICcIPALITY, Mt. Hajla, right

bank of the Ibar river, 42.7981°N 20.1083°E, 1170 m a.s.l, on dense carpet of peat

moss Sphagnum quinquefarium (Lindb.) Warnst., on very steep (almost vertical)

siliceous rocks, surrounded by mixed forest of spruce (Picea abies), fir (Abies alba)

and beech (Fagus sylvatica), 7 September 2017, leg. A. Alegro (NHMP 426/7230;

GenBank MN082023).
ECOLOGY & DISTRIBUTION— This species occurs in various habitats from the
lowlands to arcto-alpine zone, including grasslands, marshes, peat bogs, damp
places in deciduous and coniferous forests. It is a very common saprotroph
with a wide distribution, including most temperate zones on both hemispheres
(Noordeloos 1992). In the surrounding countries, E. conferendum is recorded
only in Croatia (Mesi¢ & Tkaléec 2003). New to Montenegro.

CoMMENTS—Entoloma conferendum is characterised by a_ brown
translucently striate pileus, cruciform-stellate basidiospores (unique among

644. ... Cetkovié & al.

European Entoloma species), and absence of cystidia and clamp connections.
Noordeloos & Gates (2012) place it in E. sect. Staurospora in E. subg.
Nolanea with species having predominantly cuboid basidiospores. Entoloma
staurosporum is currently accepted as a synonym of E. conferendum. Horak
(1976, 1980) synonymised E. nothofagi, described from New Zealand, with
E. staurosporum, but subsequently reverted to his original opinion (Horak
1971, 1973), treating E. nothofagi as a separate species (Horak 2008).
Noordeloos & Gates (2012), who later revised the type of E. nothofagi,
found only minimal morphological differences from E. conferendum, and
therefore regarded the two species as probably conspecific. This conclusion
is supported by our GenBank BLAST analysis showing the RPB2 sequence of
Slovakian collection of E. conferendum (KC710191) as almost identical with
the RPB2 sequence of E. nothofagi from New Zealand (MH190134), with
only a single base pair difference between them. There is no ITS sequence
available for E. nothofagi. Another similar species is E. brevispermum G.M.
Gates & Noordel. from Australia, which differs by shorter (<9 um long)
basidiospores. Our material fits well with the modern descriptions of the
species (Noordeloos 1992, Ludwig 2007, Noordeloos & Gates 2012), and
our ITS sequence matched well (identity > 99%) with most E. conferendum
sequences in GenBank.

Bovista paludosa Lév., Ann. Sci. Nat., Bot., Sér. 3, 5: 163 (1846) FIG. 2 Cc, D

BASIDIOMATA pyriform, 23-48 mm high and 16-24 mm broad, sometimes
with white rhizoids. ExoPERIDIUM when young white and smooth or with
small, very thin, adherent, greyish, polygonal patches, later breaking up
into irregular, rather large plates. ENDOPERIDIUM smooth, white at first,
becoming brown to olivaceous. GLEBA white when young, then yellowish
brown, becoming olive brown at maturity. SUBGLEBA well developed,
<15 mm high, compact, white when young, olive to grey brown at maturity.
SPORE-PRINT Olive brown. BASIDIOSPORES 4.6-5.1-5.6 x 4.2-4.7-5.4 um,
Q = 1-1.07-1.19, globose to subglobose (rarely broadly ellipsoid), almost
smooth to asperulate, moderately thick-walled, pale yellow brown in KOH,
with sterigmal remnant <15 um long. CAPILLITIUM Bovista-type, non-
poroid, thick-walled, rarely septate.

SPECIMEN EXAMINED—MONTENEGRO, ZABLJAK MUNICIPALITY, Mt. Durmitor,
Barno jezero lake, 43.1582° N, 19.0932° E, 1495 m a.s.l, among Aulacomnium
palustre (Hedw.) Schwagr., Bryum pseudotriquetrum (Hedw.) P. Gaertn. & al., and
Campylium stellatum (Hedw.) C.E.O. Jensen mosses on the outer zone of the peat bog
(less acidic), 9 July 2017, leg. I. Cetkovié (NHMP 425/7229; GenBank MN082024).

Three agarics newly recorded for Montenegro ... 645

Fic. 2. Entoloma conferendum (NHMP 426/7230). A. basidiomata; B. basidiospores.
Bovista paludosa (NHMP 425/7229). C. basidiomata; D. basidiospores. Scale bars: A, C = 10 mm;
B, D= 10 um.

ECOLOGY & DISTRIBUTION— This puffball lives as a saprotroph in a rather
wide range of open wet mossy habitats, most often in alkaline to neutral fens,
bogs, mires, wet meadows, and heaths, but avoiding oligotrophic and strongly
acidic mires (Kaltucka 2019). The species is rather widespread but rare in Europe
(Red Listed in most countries where reported), known also from Asia (China,
Russia, India) and North America (Canada) (Jeppson 2018). The only earlier

646 ... Cetkovié & al.

Montenegrin record of B. paludosa from 1904 (Bubak 1915) was published
without locality and habitat data. In the surrounding countries, it is recorded
only in Serbia (Katucka 2019).

COMMENTS—Bovista paludosa is characterised by its occurrence on wet mossy
habitats and by the presence of a well-developed subgleba, long sterigmal
remnants on basidiospores, and a Bovista-type capillitium lacking pores. The
most similar species, B. cretacea T.C.E. Fr., differs in a very poorly developed
(<2 mm high) subgleba and regularly septate capillitium. Our material agrees
with the modern descriptions (Pegler & al. 1995, Sarasini 2005, Jeppson 2018).
According to the BLAST analysis, our ITS sequence matched well with all three
sequences of B. paludosa in GenBank database (Identity > 99%).

Acknowledgements

We are very grateful to Dr. André Fraiture (Botanic Garden Meise, Belgium)
and Dr. Vladimir Antonin (Moravian Museum, Brno, Czech Republic) for their
critical review of the manuscript. The research received financial support from the
Montenegrin Ministry of Science and Croatian Ministry of Science and Education
through the project “Inventory of biodiversity and conservation status of the
representative peat bogs on the area of Montenegro and Croatia.” Also, this work
has been partially supported by Croatian Science Foundation under the project
ForFungiDNA (IP-2018-01-1736).

Literature cited

Boertmann D. 2010. The genus Hygrocybe, 2nd revised edition. Fungi of Northern Europe 1.
Svampetryk, Tilst.

Bubak FE. 1915. Dritter Beitrag zur Pilzflora von Montenegro. Botanikai K6zlemények 14(3-4):
39-83.

Gardes M, Bruns TD. 1993. ITS primers with enhanced specificity for basidiomycetes —
application to the identification of mycorrhizae and rusts. Molecular Ecology 2: 113-118.
https://doi-org/10.1111/j.1365-294X.1993.tb00005.x

Horak E. 1971. A contribution towards the revision of the Agaricales (Fungi) from New Zealand.
New Zealand Journal of Botany 9: 403-462. https://doi.org/10.1080/0028825x.1971.10430193

Horak E. 1973. Fungi agaricini Novazelandiae I-V. Beihefte zur Nova Hedwigia 43. J. Cramer,
Lehre.

Horak E. 1976. On cuboid-spored species of Entoloma (Agaricales). Sydowia 28: 171-236.

Horak E. 1980. Entoloma (Agaricales) in Indomalaya and Australasia. Beihefte zur Nova
Hedwigia 65. J. Cramer, Vaduz.

Horak E. 2008. Agaricales of New Zealand 1: Pluteaceae - Entolomataceae. The fungi of New
Zealand 5. Fungal Diversity Research Series, vol. 19. Fungal Diversity Press, Hong Kong.

Jeppson M. 2018. Puffballs of northern and central Europe. SMF, Goteborg.

Katucka IL. 2019. Bovista paludosa Lév. The Global Fungal Red List. Viewed online on 22 May
2019: http://iucn.ekoo.se/iucn/species_view/209589/

Three agarics newly recorded for Montenegro ... 647

Kasom G. 2013. Basidiomycota macrofungi of Montenegro. PhD ‘Thesis, University of
Montenegro, Faculty of Science and Mathematics, Podgorica. (in Montenegrin).
https://fedora.ucg.ac.me/fedora/get/0:334/bdef:Content/get (viewed online on 22 May 2019)

Ludwig E. 2001. Pilzkompendium, Band 1. IHW-Verlag, Eching.

Ludwig E. 2007. Pilzkompendium, Band 2. Fungicon-Verlag, Berlin.

Ludwig E. 2012. Pilzkompendium, Band 3. Fungicon- Verlag, Berlin.

MeSi¢ A, Tkaléec Z. 2003. Preliminary checklist of Agaricales from Croatia IV: Families
Bolbitiaceae, Coprinaceae, Entolomataceae and Pluteaceae. Mycotaxon 87: 283-309.

Noordeloos ME. 1992. Entoloma s.l. Fungi Europaei 5. Libreria editrice Giovanna Biella,
Saronno.

Noordeloos ME. 2011. Strophariaceae s.1. Fungi Europaei 13. Edizioni Candusso, Alassio.

Noordeloos ME, Gates GM. 2012. The Entolomataceae of Tasmania. Springer, New York -
London. https://doi.org/10.1007/978-94-007-4679-4

Pegler DN, Lzessge T, Spooner BM. 1995. British puffballs, earthstars and stinkhorns. Royal
Botanic Gardens, Kew.

Sarasini M. 2005. Gasteromiceti epigei. A.M.B., Trento.

Tkaléec Z, Mesi¢ A. 2003. Preliminary checklist of Agaricales from Croatia V: Families
Crepidotaceae, Russulaceae and Strophariaceae. Mycotaxon 88, 279-314.

Tkaléec Z, MeSi¢ A, Matocéec N, KuSan I. 2008. Red book of Croatian fungi. Ministry of Culture
- State Directorate for Protection of Nature, Zagreb (in Croatian).

Vesterholt J, Rald E. 2012. Hypholoma (Fr.) P. Kumm. 942-946, in: H Knudsen, J Vesterholt
(eds). Funga Nordica, Nordsvamp, Copenhagen.

Watling R, Gregory NM. 1987. Strophariaceae & Coprinaceae p.p.: Hypholoma, Melanotus,
Psilocybe, Stropharia, Lacrymaria and Panaeolus. British Fungus Flora: Agarics and Boleti
5. Royal Botanic Garden, Edinburgh.

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 649-655
https://doi.org/10.5248/135.649

First Pakistani report of Erysiphe betae
on the invasive weed Chenopodium ambrosioides

AYESHA ANWAR™, NAJAM UL SEHAR AFSHAN’, AAMNA ISHAQ3,
MarRIA RIAz?, ABDUL NASIR KHALID’, SIRAJ UDDIN'

' Department of Botany, University of Peshawar, 25120, Pakistan

? Department of Botany, University of the Punjab,
Quaid-e-Azam Campus, Lahore, 54590, Pakistan

> Department of Botany, Faculty of Fisheries and Wildlife,
University of Veterinary and Animal Sciences-Lahore,
Ravi Campus, Pattoki, 55300, Pakistan

" CORRESPONDENCE TO: Ayeshaanwar556@gmail.com

AxssTRACT—During September-October 2017, powdery mildew symptoms were observed
on both surfaces of leaves of Chenopodium ambrosioides in Abbottabad, Malakand, and
Upper Dir districts of Pakistan. The causal agent was identified as Erysiphe betae, based on
its asexual morphology and chasmothecia, and its identity was confirmed by molecular data.
This is the first Pakistani report of Erysiphe betae on this host.

Key worps—Amaranthaceae, Erysiphaceae, mexican tea, new record

Introduction

Fungi belonging to Erysiphales are widely distributed all over the world
and cause serious economic damage on wild and cultivated plants. This order
comprises the single family Erysiphaceae (powdery mildews) represented by
17 genera and c. 820 species (Braun & Cook 2012). Powdery mildews infect
9839 angiosperm species in 1617 genera, 196 families, and 44 orders (Amano
1992, Takamatsu 2004), including numerous economically important plants.
Various powdery mildews may cause serious economic damage on wild
and cultivated plants in Pakistan (Burni & al. 2010, Mukhtar & al. 2012,

650 ... Anwar & al.

2013). Nineteen of the 56 powdery mildew species reported from Pakistan
represent the most common genus, Erysiphe, which infects 52 hosts in 19
plant families (Ahmad & al. 1997, Burni & al. 2010, Mukhtar & al. 2013). This
includes Erysiphe betae on Chenopodium botrys L. and Spinacia oleracea L.
(Amaranthaceae; Amano 1986).

In 2017, a powdery mildew appeared on the leaves of Chenopodium
ambrosioides in the districts Abbottabad, Malakand, and Upper Dir, Pakistan.
The infected leaf surfaces were fully covered with white powdery mycelial
masses, asexual conidia, and sexual chasmothecia indicating progressed
stages of infection and severity.

Materials & methods

Sample collection

During phytopathological surveys during September-October 2017, we observed
powdery mildew infections on leaves and stems of Chenopodium ambrosioides in the
districts Abbottabad, Malakand, and Upper Dir, Khyber Pakhtunkhwa, Pakistan. The
infected plants were shade dried on blotting paper and protected in brown envelopes
for future use. The specimens are deposited at the herbarium of the University of
Peshawar, Khyber Pakhtunkhwa, Pakistan (PUP) and Department of Botany,
University of the Punjab, Lahore, Punjab, Pakistan (LAH).

Morphology

We first examined infected leaves under a Labomed CSM2 stereomicroscope,
and then prepared using lactic acid. We examined the hyphae on the host; hyphal
appressoria; conidial, conidiophore, and chasmothecial shapes and sizes; and
ascospores and asci under a Nikon YS 100 microscope. Measurements (20 repetitions
per structure) were recorded using a Lomo Filar Eyepiece Micrometer AM9-2-15x on
a Zeiss microscope. Micrographs were made using a HDCE-5X digital camera.

DNA extraction, PCR amplification, phylogenetic analysis

Dried powdery mildew infections were scraped off from fresh fungal specimens
with sterile razor blades, ground in liquid nitrogen, and stored in Eppendorf tubes at
-18 °C. DNA was extracted using GeneJET Plant Genomic DNA Purification Mini
Kit #K0791 according to the manufacturer’s instructions. The Internal Transcribed
Spacer (ITS) region was amplified using PMITS1/PMITS2 primers (Cunnington
& al. 2003) and then commercially sequenced by Tsingke in China. Raw sequence
data were edited using BioEdit (Hall 1999). The ITS sequences were BLAST searched
against the GenBank database (www.ncbi.nlm.nih.gov) and aligned using Muscle
E multiple alignment tool within MEGA v. 7.0 (Kumar & al. 2016). Twenty ITS
sequences were analyzed using the maximum likelihood (ML) method based on the
Tamura 3-parameter model (Tamura 1992). The initial trees for the heuristic search
were obtained by applying the Neighbor-Joining method to a matrix of pairwise

Erysiphe betae new on Chenopodium ambrosioides in Pakistan ... 651

KY660905 Erysiphe ludens

35| KY660901 Erysiphe ludens
KY660739 Erysiphe trifoliorum
KY660903 Erysiphe trifoliorum
KJ845646 Erysiphe sp.

KJ845645 Erysiphe sp.

KY926844 Erysiphe castaneigena

59 89' KY926843 Erysiphe castaneigena
KY660931 Erysiphe cruciferarum
KY660884 Erysiphe cruciferarum
KY660750 Erysiphe pisi
LC270861 Erysiphe viciae-unijugae
79 KY660922 Erysiphe buhrii
KY660881 Erysiphe buhrii
82] | @ MN368297 Erysiphe betae

71'LC009946 Erysiphe betae
MG938639 Erysiphe berberidicola
MG938640 Erysiphe berberidicola
AB080464 Phyllactinia angulata
LC108847 Phyllactinia leveilluloides

67

0.05

Fic. 1. Phylogenetic analysis of the ITS region for 18 Erysiphe sequences, with Phyllactinia angulata
and P. leveilluloides as outgroup. The evolutionary history was inferred by using the Maximum
Likelihood method based on the Tamura 3-parameter model. The tree with the highest log
likelihood (-470.6292) is shown, and the amplified sequence from Pakistan is denoted by ¢.

distances estimated using the Maximum Composite Likelihood (MCL) approach.
Evolutionary analyses were conducted in MEGA6 (Tamura & al. 2013). in the
phylogenetic analyses. After elimination of gaps and missing data, the final dataset
comprised 134 positions, and Phyllactinia angulata (E.S. Salmon) S. Blumer and P
leveilluloides Moreno-Rico & U. Braun served as outgroup. All sequences were aligned
and trimmed at conserved sites from both 5’ and 3’ ends. The phylogenetic tree with
the highest log likelihood (-470.6292) is shown in Fic. 1; the percentage of trees in
which the associated taxa clustered together is shown next to the branches, and the
tree is drawn to scale, with branch lengths measured in the number of substitutions
per site.

652 ... Anwar & al.

Fic. 2. Erysiphe betae (PUP Bot.01). A. Infected plant, Chenopodium ambrosioides; B. Fungal
mycelium under stereomicroscope; C. Conidia; D. Conidiophore; E. Chasmothecium;
E Germinating Conidium; G. Asci with ascospores; H. Ascospores; I. Chasmothecial appendage.
Seale‘bars: A= 1 cm, B =2am,'C, D, BG= 15pm; EH, L = 10 pm.

Erysiphe betae new on Chenopodium ambrosioides in Pakistan ... 653

Taxonomy

Erysiphe betae (Vanha) Weltzien, Phytopathol. Z. 47: 127 (1963) BIG 72

Mycelium amphigenous, forming dense, thick, white patches; hyphae
hyaline, smooth, thin-walled; hyphal appressoria nipple-shaped to
somewhat lobed, 2-5 um diam. Conidiophores arising from the top of
mother cells, 43-87 x 3.5-7.5 um; foot cells cylindrical, straight or sometime
curved, 22-61 x 4.5-8 um, constricted at the basal septum, followed by 1-2
shorter cells; conidia formed singly, ellipsoid-ovoid to cylindrical-doliiform,
14.5-51 x 7-12 um; germ tubes arising from one end, tips slightly swollen;
Chasmothecia scattered to gregarious, globose to subglobose, light to dark
brown, 48.5-104 um diam.; peridium cells small, 12-27 um diam., irregularly
polygonal; appendages numerous, mycelioid, irregularly branched, septate,
thin-walled, at first hyaline but pigmented when chasmothecia mature,
29-119 x 2.5-4.5 um; asci 3-5, ellipsoid-obovoid, 28-49.5 x 19.5-29.5 um,
stalked, 4-5-spored; ascospores globose-ellipsoid to ovoid, 8.5-18.5 x
5.5-10.5 um, colorless.

SPECIMENS EXAMINED: PAKISTAN, KHYBER PAKHTUNKHWA, Malakand Division,
Malakand district, 844 ma.s.l., on Chenopodium ambrosioides L. (Amaranthaceae), 19
September 2017, asexual morph, A. Anwar AA#4 (PUP Bot.01; GenBank MN368297);
Upper Dir district, 844 m a.s.l., on C. ambrosioides, 29 October 2017, asexual and
sexual morphs, A. Anwar AA#5 (PUP Bot.02); Hazara Division, Abbottabad district,
Ayubia National Park, 2438 m a.s.l, on C. ambrosioides, 30 October 2017, asexual
morph, N.S. Afshan NSA#34 (LAH 35658).

Phylogenetic results

The NCBI BLASTn analysis showed that our ITS sequence (MN368297
Erysiphe betae) closely matched (99.54% identity) a sequence of E. betae
(LC009946) on Beta vulgaris from Japan (Takamatsu & al. 2015). The 20
nucleotide sequences used in the phylogenetic analysis included Phyllactinia
angulata (AB080464) and P leveilluloides (LC108847) as outgroup. The
final aligned data set contained 818 positions of which 567 were conserved,
202 variable and parsimony uninformative, and 49 parsimony informative
sites. Maximum likelihood (ML) analysis clustered the Pakistan E. betae
collection (MN368297) with the Japanese E. betae collection (LC009946)
with a 71 bootstrap value. Based on these results, we assigned the name
Erysiphe betae to the powdery mildew pathogen on Chenopodium
ambrosioides in Pakistan.

654 ... Anwar & al.

Discussion

Worldwide, three Erysiphe spp. (including E. betae), two Leveillula spp.,
and three anamorphic powdery mildew species have been reported on
Chenopodium ambrosioides (Fungus-Host Database https://nt.ars-grin.gov,
29 May, 2018, Braun & Cook 2012). From Pakistan, only “Erysiphe communis
(Wallr.) Schltdl.” (nom. rej.) on Chenopodium botrys and Spinacia oleracea
and Leveillula cylindrospora U. Braun and L. taurica (Lév.) G. Arnaud on
Chenopodium murale L. have been reported. Chenopodium ambrosioides is
reported here as a new host record for Erysiphe betae in Pakistan.

Previously, only asexual morphs of Erysiphe have been reported on
Chenopodium species from Asia and Europe, whereas sexual fruiting bodies
(chasmothecia) have been reported only from India and Japan (Braun & Cook
2012). We now report both asexual and sexual morphs of Erysiphe betae from
Pakistan. We found only the asexual morph in the Abbottabad and Malakand
districts, but additionally collected the chasmothecia in the Upper Dir
district. Previous reports from Pakistan of Erysiphe on Chenopodium botrys
(as “E. communis;” Amano 1986) is probably allocable to E. betae. Francis &
al. (2007), who analysed ITS rDNA sequences retrieved from European (UK)
and North American (USA) collections of E. betae on sugar beet, confirmed
the involvement of a single recognizable Erysiphe species more closely allied
to Erysiphe heraclei DC. than to E. polygoni DC. Takamatsu & al. (2015)
included in their phylogenetic analyses a sequence obtained from E. betae
on Beta vulgaris L. with corresponding results, but sequences retrieved from
E. betae on Chenopodium ambrosioides are not yet available and still in need
of molecular confirmation. Our research represents the first phylogenetic
analysis of E. betae on Chenopodium ambrosioides, which clusters our ITS
sequence in a strongly supported clade with a sequence of E. betae on
Beta vulgaris (Fic. 1).

Acknowledgements

We are really thankful to Prof. Dr. Uwe Braun (Martin-Luther-Universitat,
Institut fiir Biologie, Germany) for his help in the identification of Erysiphe betae
on Chenopodium ambrosioides and peer review of the manuscript. The authors are
also thankful to Dr. Abdul Rehman Khan Niazi, Department of botany, University of
Punjab, Lahore, for his valuable suggestions to improve this manuscript.

Literature cited

Ahmad §, Iqbal SH, Khalid AN. 1997. Fungi of Pakistan. Sultan Ahmad Mycological Society of
Pakistan, Lahore, PK.

Amano K. 1986. Host range and geographical distribution of the powdery mildew fungi. Japan
Scientific Societies Press, Tokyo.

Erysiphe betae new on Chenopodium ambrosioides in Pakistan ... 655

Amano K. 1992. Notes on the host range and geographical distribution of Podosphaera.
Transactions of the Mycological Society of Japan 33: 139-148.

Braun U, Cook RTA. 2012. Taxonomic manual of the Erysiphales (powdery mildew). CBS
Biodiversity Series 11. 707 p.

Burni T, Jamil F, Jabeen M. 2010. Erysiphales of Peshawar valley, Khyber Pakhtunkhwa, Pakistan.
Pakistan Journal of Plant Sciences 16(1): 11-14.

Cunnington JH, Takamatsu S, Lawrie AC, Pascoe IG. 2003. Molecular identification of
anamorphic powdery mildews (Erysiphales). Australasian Plant Pathology 32: 421-428.
https://doi.org/10.1071/AP03045

Francis SA, Roden BC, Adams MJ, Weiland J, Asher MJ. 2007. Comparison of ITS sequences
from UK and North American sugar-beet powdery mildews and the designation of Erysiphe
betae. Mycological Research 111(2): 204-212. https://doi.org/10.1016/j.mycres.2006.10.010

Hall TA. 1999. BioEdit: a user-friendly biological sequence alignment editor and analysis
program for Windows 95/98/NT. Nucleic Acids Symposium Series 41: 95-98.
https://doi.org/10.1017/S0953756203008517

Kumar S, Stecher G, Tamura K. 2016. MEGA7: Molecular Evolutionary Genetics Analysis
version 7.0 for bigger datasets. Molecular Biology and Evolution 33(7): 1870-1874
https://doi.org/10.1093/molbev/msw054.

Mukhtar I, Khurram R, Hannan A, Hayat Z. 2012. First report of powdery mildew of Cucurbita
moschata Duch. caused by Golovinomyces cichoracearum DC. in Neelum Valley, Azad
Kashmir. Plant Disease 96(6): 906. https://doi.org/10.1094/PDIS-08-11-0642-PDN

Mukhtar I, Mushtaq S, Khokhar I. 2013. First report of powdery mildew on Dahlia (Dahlia
variabilis) caused by Golovinomyces cichoracearum in Lahore, Pakistan. Australasian Plant
Disease Notes 8(1): 1-3. https://doi.org/10.1007/s13314-011-0025-7

Takamatsu S. 2004. Phylogeny and evolution of the powdery mildew fungi (Erysiphales,
Ascomycota) inferred from nuclear ribosomal DNA sequences. Mycoscience 45: 147-157.
https://doi.org/10.1007/s10267-003-0159-3

Takamatsu S, Ito H, Shiroya Y, Kiss L, Heluta V. 2015. First comprehensive phylogenetic
analysis of the genus Erysiphe (Erysiphales, Erysiphaceae) 1. The Microsphaera lineage.
Mycologia 107: 475-489. https://doi.org/10.3852/15-007

Tamura K. 1992. Estimation of the number of nucleotide substitutions when there are strong
transition-transversion and G + C-content biases. Molecular Biology and Evolution 9:
678-687. https://doi.org/10.1093/oxfordjournals.molbev.a040752

Tamura K, Stecher G, Peterson D, Filipski A, Kumar S. 2013. MEGA6: Molecular Evolutionary
Genetics Analysis version 6.0. Molecular Biology and Evolution 30: 2725-2729.
https://doi.org/10.1093/molbev/mst197

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 657-663
https://doi.org/10.5248/135.657

Crustose lichens new to India

RUPJYOTI GOGOT’, SILJO JOSEPH?, MANAS PRATIM CHOUDHURY’,
SANJEEVA NAYAKA’, FARISHTA YASMIN’*

' Department of Botany, Nowgong College,
Nagaon, Assam - 782001, India

? Lichenology Laboratory, CSIR-National Botanical Research Institute,
Rana Pratap Marg, Lucknow - 226001, India

* CORRESPONDENCE TO: farishtayasmin4rs@gmail.com

ABSTRACT—Bacidia pycnidiata (Ramalinaceae), Malmidea nigromarginata (Malmideaceae),
Porina malmei and P. nuculastrum (Porinaceae), and Pyrenula laetior and P. wrightii
(Pyrenulaceae) are reported for the first time from India. The specimens were collected
from the state of Assam. Taxonomic descriptions, distributions, and illustrations are
provided for each species.

Key worps—biodiversity, lichenized Ascomycota, Nagaon, taxonomy, Tezpur

Introduction

Lichens constitute a significant part of India’s biodiversity, and 2714

lichen species are known from the country (Sinha & al. 2018). Although

lichens occur everywhere in India, ecological studies reveal that Northeast
India, Western Ghats, Western Himalaya, and Andaman & Nicobar Islands
are the major centres of diversity (Nayaka & Asthana 2014). Assam, a state of

Northeast India, possesses the heterogeneous climatic conditions that make

it suitable for rich floral, faunal, and fungal diversity. Over 325 species (in

83 genera and 27 families) have been reported from Assam (Gupta & Sinha

2018, Gogoi & al. 2019). Here we record six additional lichen species (in

Malmideaceae, Porinaceae, Pyrenulaceae, and Ramalinaceae) new to Assam

and to India.

658 ... Gogoi & al.

Materials & methods

The present study is based on the freshly collected lichen samples from Assam.
The lichen specimens were dried, preserved, and deposited in the herbarium at CSIR-
National Botanical Research Institute, Lucknow, India (LWG). The lichen thallus
was morphologically examined under a Leica EZ4 stereo zoom microscope. Thin
hand-cut sections of ascus and thallus were mounted in distilled water, Lactophenol
Cotton Blue (LCB), 5% KOH, or Lugol’s iodine solution for observation under
a Leica DM 2500 compound microscope. The thallus and ascomatal tissue were
spot-tested with K (5% KOH aqueous solution), C (aqueous Ca(ClO)2 solution)
and P (0.5 g of para-phenylenediamine dissolved in 5 ml of ethanol) following
Orange & al. (2001). Thin Layer Chromatography was performed in solvent system
C (toluene: acetic acid; 85: 15 ml) following Orange & al. (2001).

Taxonomy

Bacidia pycnidiata Czarnota & Coppins, Lichenologist 38: 407. 2006 Pie ika

Thallus epilithic, pale yellowish to greenish, slightly granular, cracked.
Apothecia few, 0.2-0.4 mm diam. Excipulum prominent, colourless, 90-140
um wide. Hymenium hyaline, 40-55 um high, I+ blue. Asci cylindrical,
Bacidia-type, 35-41 x 4.5-5.8 um. Ascospores acicular, 3(-—7)-septate, 25-38 x
1.2-2.8 um. Pycnidia very few, having round flask shaped bottom with long
neck, 0.1-0.2 mm diam., constricted at base, concolorous with apothecia,
neck slightly paler than bottom, ostiole present at the tip of the beak; conidia
hyaline, 3-5-septate, straight to slightly curved, filiform, 37-62 x 0.4-1.0 um.

CHEMISTRY— Thallus K-, C-, P-, UV-; no chemicals detected in TLC.

SPECIMEN EXAMINED—INDIA, Assam, Tezpur, Ouguri Hills, 26°37’03”N 92°46'37”E,
elev. 113 m, on rock, 16 May 2015, Manas P. Choudhury 15027001 (LWG 35885).

REMARKS— The ascospore length of the Indian specimen is slightly shorter
than that given in the protologue of Bacidia pycnidiata (35-52 um; Czarnota
& Coppins 2006). Further, the Indian specimen had occasional 7-septate
ascospores rather than the usual 3-septate, which has not been reported
previously for B. pycnidiata. In all other aspects the Indian specimen agrees
with the published description of B. pycnidiata.

DISsTRIBUTION—Belgium, Czech Republic, Estonia, Finland, Lithuania,
Mordovia, North Caucasus, Poland, and Ukraine (Urbanavichene &
Urbanavichus 2014). This is a first report of B. pycnidiata for India.

Malmidea nigromarginata (Malme) Licking & Breuss,
Lichenologist 47: 19. 2015. Pr lb
Thallus crustose, epiphloeodal, smooth, grayish black, medulla
ochraceous, K+ yellow; borderline blackish. Apothecia mostly solitary,

Bacidia, Malmidea, Porina & Pyrenula spp. new for India ... 659

PLATE 1. Habit. a. Bacidia pycnidiata (LWG 35885); b. Malmidea nigromarginata (LWG 35887);
c. Porina malmei (LWG 35886); d. Porina nuculastrum (LWG 35888); e. Pyrenula laetior (LWG
35889); f. Pyrenula wrightii (LWG 35890). Scale bars = 1 mm.

660 ... Gogoi & al.

rarely 3—4 aggregated, margin black, disc flesh coloured. Excipulum without
algal cells, lacking medullary layer, hyphae radiating and conglutinated.
Hymenium hyaline, 70-90 um high, I+ blue. Hypothecium dark brownish to
brown black, 70-100 um thick. Asci 6-8-spored. Ascospores simple, hyaline,
8.9-13.4 x 4.5-5.4 um.

CHEMISTRY—Thallus K—, C—, P-, UV-; no lichen substances detected
im ELE.

SPECIMEN EXAMINED—INDIA, AssaM, Nagaon district, Samaguri, Chapanalla,
26°19'13”N 92°54’16’E, elev. 119 m, on bark, 18 February 2018, Rupjyoti Gogoi
NCLH 030 (LWG 35887).
REMARKS—The ascospore sizes of the Indian specimen fit well within the
range of Malmidea nigromarginata (10-14 x 4-6 um) as mentioned in the
world key to the genus by Breuss & Licking (2015).
DIsTRIBUTION—Nicaragua (Breuss & Liicking 2015) and Puerto Rico
(Mercado-Diaz & al. 2015). This is a first report of M. nigromarginata for India.

Porina malmei P.M. McCarthy, Biblioth. Lichenol. 52: 70. 1993. Baeale

Thallus saxicolous, medium to dark grey, areolate, ecorticate. Perithecia
emergent, hemispherical to subglobose, dull black, 0.1-0.3 mm diam.
Ostioles apical, conspicuous. Involucrellum brownish, continuous with the
exciple. Excipulum black, 20-50 um thick. Centrum 0.15-0.25 um wide.
Hymenium clear. Asci elongate-cylindrical. Ascospores hyaline, fusiform,
(3-)6-7-septate, 20-27 x 4-6 um. Pycnidia not seen.

CHEMISTRY— Thallus K-, C-, P-, UV-; no chemicals detected in TLC.

SPECIMEN EXAMINED—INDIA, Assam, Tezpur, Rudrapad Temple, bank of River
Brahmaputra, 26°36’55”N 92°46’10”E, elev. 65 m, on rock, 16 March 2015, Manas P.
Choudhury 15027003 (LWG 35886).
REMARKS— The Indian specimen agrees with the description of Australian
Porina malmei in most features, and ascospore lengths fit well within the
17-30 um range cited in the protologue (McCarthy 1993).
DisTRIBUTION—Brazil, north-eastern Australia (McCarthy 2000). This is
a first report of P malmei for India.

Porina nuculastrum (Mill. Arg.) R.C. Harris, More Florida Lichens,
incl. 10 Cent Tour Pyrenol. (New York): 174. 1995. Bred
Thallus crustose, epiphloeodal, olivaceous, slightly rimose, prothallus black.
Perithecia erumpent to + immersed, mostly solitary, rarely grouped into 2-3,
perithecia concolorous with the thallus except in the peri-ostiolar and ostiolar
regions, convex to sub-globose 0.4-0.65 mm diam.; ostiole inconspicuous or

Bacidia, Malmidea, Porina & Pyrenula spp. new for India ... 661

in a shallow depression; peri-ostiolar area 0.12-0.18 mm diam. Involucrellum
enclosing the exciple yellowish to blackish. Exciple ca. 30 um thick. Hymenium
clear. Asci elongate-cylindrical. Ascospores narrowly ellipsoidal to fusiform,
submuriform to muriform with 6-10 transverse septa and (0-)1(-3)
longitudinal septa, 49.8-67.6 x 13.5-22.2 um. Pycnidia not seen.

CuHEMISTRY— Thallus K-, C—, P-, UV-; no chemicals detected in TLC.

SPECIMEN EXAMINED—INDIA, Assam, Nagaon district, Samaguri, Suang Reserve
Forest, 26°19’20”N 92°54’18’E, elev. 142 m, on bark, 18 February 2018, Rupjyoti
Gogoi NCLH 031 (LWG 35888).
ReMARKS—'The Indian specimen closely matches the Australian and
Vietnamese descriptions of Porina nuculastrum (McCarthy 2001, Joshi & al.
2019), except that our ascospores have fewer transverse septa.
DIsTRIBUTION—Neotropics, Madagascar, the Philippines, Hong Kong
and neighbouring countries (McCarthy 2001), Vietnam (Joshi & al. 2019).
This is a first report of P nuculastrum for India.

Pyrenula laetior Mill. Arg., Bot. Jahrb. Syst. 6: 413. 1885. PL. le

Thallus crustose, corticate, epiphloeodal, yellow, without external
pigments. Perithecia black, solitary, 0.4-0.9 mm diam. Ostiole apical
without pigment. Hamathecium inspersed with oil droplets. Asci 8-spored.
Ascospores brown, 3-septate, eciliate, distoseptate, lumina in a straight line,
13.8-19.2 x 5.8-7.7 um, central lumina not strongly elongated, terminal
lumina separated from the exospore wall by endospore thickenings, old
ascospores without orange oil.

CHEMISTRY— Thallus K—, C—, P-, UV-; no chemicals detected in TLC.

SPECIMEN EXAMINED—INDIA, Assam, Nagaon district, Samaguri, Suang Reserve
Forest, 26°19’20”N 92°54’18’E, elev. 143 m, on bark, 18 February 2018, Rupjyoti
Gogoi NCLH 032 (LWG 35889).
REMARKS—Aptroot (2012) cites ascospores ranging from 13-18 um for
Pyrenula laetior, while those of the Indian specimen are slightly longer. The
Indian material agrees with P Jaetior in all other characters.
DISTRIBUTION—Neotropics (Aptroot 2012), Vietnam (Joshi & al. 2018).
This represents a first report of P laetior for India.

Pyrenula wrightii (Mill. Arg.) R.C. Harris,
More Florida Lichens, incl. 10 Cent Tour Pyrenol.: 111. 1995. Prt
Thallus corticolous, epiphloeodal, olive green with pseudocyphellae.
Perithecia black, without external pigments, solitary to mostly aggregated
with separated ostioles, 0.2-0.5 mm diam. Ostiole apical without pigment.

662 ... Gogoi & al.

Hamathecium not inspersed with oil droplets. Asci 8-spored. Ascospores
brown, 2-3-septate, 27.3-33.2 x 12.5-14.5 um, lumina in a straight
line, external lumina separated from the exospore wall by endospore
thickening.
CHEMISTRY— Thallus K—, C—, P-, UV-; no lichen substance detected

bia es bs oe

SPECIMEN EXAMINED—INDIA, Assam, Nagaon district, Doboka Circle, Jamunamukh,

26°05'54’"N 92°44’44”E, elev. 40 m, on bark, 5 February 2017, Rupjyoti Gogoi NCLH

033 (LWG 35890).

REMARKS— The Indian specimen agrees with the published description of
Pyrenula wrightii by having pseudocyphellae and in ascospore characteristics
(Aptroot 2012). The ascospores of the Indian specimen are slightly longer
than the measurements provided in the basionym protologue (27-30 um;
Miller 1885).

DisTRIBUTION—Cuba (Aptroot 2012). This represents a first report of
P. laetior for India and the first outside the type country.

Acknowledgments

The authors thankfully acknowledge the financial support of Department of
Biotechnology (DBT, Govt. of India) through Institutional Biotech Hub (No. BT/04/
NE/2009) for establishing the Lichenology Laboratory at Nowgong College, Assam,
to provide laboratory facilities for this study. The authors thank the Director of CSIR-
NBRI for providing the laboratory and herbarium facilities and Dr. D.K. Upreti for
his encouragement and help with the identification of the Pyrenula and Porina
specimens. We thank Drs. G.P. Sinha (Botanical Survey of India, Allahabad, India)
and Udeni Jayalal (Sabaragamuwa University of Sri Lanka, Belihuloya, Sri Lanka)
for reviewing the manuscript. One of the authors (SJ) is grateful to DST-SERB for
providing financial assistance under the NPDF scheme (PDF/2016/002054).

Literature cited

Aptroot A. 2012. A world key to the species of Anthracothecium and Pyrenula. Lichenologist
44(1): 5-33. https://doi.org/10.1017/s0024282911000624

Breuss O, Liicking R. 2015. Three new lichen species from Nicaragua, with keys to the known
species of Eugeniella and Malmidea. Lichenologist 47(1): 9-20.
https://doi.org/10.1017/S0024282914000565

Czarnota P, Coppins BJ. 2006. A new Bacidia with long-necked pycnidia from Central Europe.
Lichenologist 38(5): 407-410. https://doi.org/10.1017/s0024282906005986

Gogoi R, Joseph S, Nayaka S, Yasmin F. 2019. Additions to the lichen biota of Assam State,
India. Journal of Threatened Taxa 11(6): 13765-13781.
https://doi.org/10.11609/jott.4642.11.6.13765-13781

Gupta P, Sinha GP. 2018. Lichen flora of Assam. Bishen Singh Mahendra Pal Singh, Dehra
Dun, India.

Bacidia, Malmidea, Porina & Pyrenula spp. new for India ... 663

Joshi S, Upreti DK, Hur JS. 2018. Key to the lichen families Pyrenulaceae and Trypetheliaceae
in Vietnam, with eight new records. Mycotaxon 132(4): 957-969.
https://doi.org/10.5248/132.957

Joshi S, Upreti DK, Hur JS. 2019. Lichen genus Porina in Vietnam. Korean Journal of Mycology
47(4): 303-311. https://doi.org/10.4489/KJM.20190035

McCarthy PM. 1993. Saxicolous species of Porina Mull. Arg. (Trichotheliaceae) in the Southern
Hemisphere. Bibliotheca Lichenologica 52: 1-134.

McCarthy PM. 2000. Key to the saxicolous taxa of Porina. Lichenologist 32(1): 1-13.
https://doi.org/10.1006/lich.1999.0213

McCarthy PM. 2001. Trichotheliaceae. 105-157, in: PM McCarthy (ed.). Flora of Australia,
Volume 58A, Lichens 3. ABRS/CSIRO Australia, Melbourne.

Mercado-Diaz JA, Gould WA, Gonzalez G, Liicking R. 2015. Lichens in Puerto Rico:
an ecosystem approach. General Technical Report IITF-GTR-46. San Juan, PR: US.
Department of Agriculture, Forest Service, International Institute of Tropical Forestry.
https://doi.org/10.2737/iitf-gtr-46

Miller J. 1885. Pyrenocarpeae Cubenses a cl. C. Wright lectae. Botanische Jahrbiicher fiir
Systematik, Pflanzengeschichte und Pflanzengeographie 6: 375-421.

Nayaka S, Asthana S. 2014. Diversity and distribution of lichens in India vis a vis its
lichenogeographic regions. 79-96, in: T Marimuthu & al. (eds). Biodiversity Conservation
— Status, Future and Way Forward. National Academy of Biological Science, Chennai,
India.

Orange A, James PW, White FJ. 2001. Microchemical methods for the identification of lichens.
British Lichen Society, London.

Sinha GP, Nayaka S, Joseph S. 2018. Additions to the checklist of Indian lichens
after 2010. Cryptogam Biodiversity and Assessment, Special Volume: 197-206.
https://doi.org/10.21756/cab.esp16

Urbanavichene I, Urbanavichus G. 2014. Bacidia pycnidiata discovered in European Russia.
Folia Cryptogamica Estonica 51: 109-111. https://doi.org/10.12697/fce.2014.51.12

MYCOTAXON

ISSN (print) 0093-4666 (online) 2154-8889 Mycotaxon, Ltd. ©2020

July-September 2020—Volume 135, pp. 665-718
https://doi.org/10.5248/135.665

Chromelosporium re-evaluated, with
Chromelosporiopsis gen. nov. and Geohypha stat. nov.

GREGOIRE L. HENNEBERT

Rue de l'Elevage 32, B 1340 Ottignies-Louvain-la-Neuve, Belgium

CORRESPONDENCE TO: hennebertg@scarlet.be

ABSTRACT—Chromelosporium-like asexual morphs of the subterraneous Pezizaceae in
the /Pachyphlodes clade are not congeneric with the type of Chromelosporium. Some
Chromelosporium morphs are of species in the /Pezizaceae clade (the /Peziza clade), and
the genus Chromelosporium as it has been defined is polyphyletic. A diagnostic character
that distinguishes these two groups is the presence or absence of conidiophore fasciculation.
Mononematous conidiophores characterize Chromelosporium and species related to the
/Peziza clade. Synnematous conidiophores characterize Pachyphlodes and other asexual
species and define the new genus Chromelosporiopsis, to be excluded from Chromelosporium.
Hyphelia terrestris, long misapplied to Chromelosporium, is revaluated, lectotypified,
redescribed and recombined as Geohypha terrestris.

Keyworps—hyphomycete, nomenclature, taxonomy

Introduction

Collections of Chromelosporium-like hyphomycetes made by R.P. Korf
around Ithaca, NY, which he tentatively named Glischroderma because of
their production of gel (Korf 1994), were revaluated by Healy & al. (2015)
and identified as conidial morphs in the truffle genus Pachyphlodes. Fresh
Chromelosporium-like specimens collected on bare soil in woods in Belgium,
identified by DNA sequencing as Pachyphlodes nemoralis and P. citrina,
provided the necessary asexual material to compare with and segregate from
the asexually typified species, Chromelosporium ochraceum (Hennebert &
Decock 2020).

666 ... Hennebert

The main distinction that emerged between the asexual morphs in
C. ochraceum and the two Pachyphlodes species is conidiophore fasciculation.
This criterion, applied to species already named in Chromelosporium
(Hennebert 1973), segregates them into two genera. It seems generally
accepted that these fungi are asexual morphs of Pezizales. As long as their
type species are not known to be congeneric with species with a known
sexual morph, however, it seems sensible to keep these genera separate.

Mononematous species define Chromelosporium. Synnematous species
are excluded and are accommodated in the new genus Chromelosporiopsis.

Names such as Botrytis epigaea, Phymatotrichum species, and others are
discussed as doubtful taxa. The conidial ornamentation observed in the
numerous herbarium specimens that might contribute to the diagnosis of
unidentified Chromelosporiopsis species is also analysed.

Hyphelia terrestris, currently misclassified in Chromelosporium, is re-
evaluated and recombined as the type of Geohypha [= Hyphelia sect.
Geohypha elevated to generic rank].

The asexual morph of Plicaria endocarpoides, previously supposed to
show similarities with Chromelosporium, is described.

The illustrated descriptions of the asexual morphology of these taxa
provide the rationale for the present paper.

Materials & methods

Species descriptions are based on observations made on herbarium material
borrowed from many herbaria and some fresh collections made during 1960-62 while
working as a postdoctoral researcher under the late Dr S.J. Hughes at the Agriculture
& Agri-Food mycology group in Ottawa (DAOM). This material is complemented
with some contemporary collections from Europe. A 1960 Olympus FH microscope
equipped with Olympus positive low phase contrast objectives and an adapted
Wild drawing tube was used for the microscopic examinations. All samples were
mounted in lactic acid with Cotton blue. Slides made from the examined specimens
are preserved in the Canadian National Mycological Herbarium, Ottawa, Canada
(DAOM) and/or Mycotheque, Université Catholique de Louvain, Louvain-la-Neuve,
Belgium (MUCL), and accession numbers are listed for each specimen in square
brackets. Information provided in the Examined specimen sections duplicates the
herbarium labels with bold numbers separating each specimen.

Taxonomy

Chromelosporium
This section includes the mononematous species considered morphologically
congeneric with the type species Chromelosporium ochraceum, which currently

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 667

delimits the genus Chromelosporium. In addition, one Peziza and one Plicaria
species with similar asexual morphs are each described.

Chromelosporium Corda, in Sturm’s Deutschl. Fl., Abt. 3 (Pilze), 3(13): 81, 1833.

TYPE SPECIES: Chromelosporium ochraceum Corda??

Ascomycota, Pezizaceae, sexual morph unknown.

HyPHAE septate, creeping on the substratum.

CONIDIOPHORES mononematous, erect, septate, apically branching in
successive symmetrical dichotomies, septate, apically obsuse.

CONIDIOGENUS CELLS subterminal and terminal branches forming
synchronous conidia on denticles along their lengths, collapsing after
rhexolytic secession of conidia.

Conrp14_ holoblastic, one-celled, globose or subglobose, with wall
ornamented from finely to coarsely verrucose, colored in mass.

HasitTat: on plant fragments.

COMMENTS—Hennebert (1973) made a clear distinction between
Chromelosporium and Ostracoderma Fr., so Chromelosporium should not be
placed as a synonym of Ostracoderma as cited in the 10" edition of Ainsworth
& Bisby’s Dictionary of the Fungi (Kirk & al. 2008) and in Index Fungorum.
Chromelosporium is also incorrectly listed as a synonym of Peziza in Baral’s
contribution to Jaklitsch & al. (2016). Such synonymy is indeed impossible—
Peziza being clearly polyphyletic and Chromelosporium an “orphan” genus.
Pfister & al. (2016) did not mention the case when evaluating competing
sexually and asexually typified names. Indeed, as the type species is not
connected to any sexual morph, the generic name Chromelosporium cannot
be competing so far. Also, Chromelosporium should not have been ignored
in the recent “Outline” of fungal genera (Wijayawardene & al. 2020). It is
possible that the four species described in the genus below, beside the type
species, might also be revealed as polyphyletic.

Chromelosporium ochraceum Corda,

in Sturm’s Deutschl. Fl., Abt. 3 (Pilze), 3(13): 81, 1833. FIGS 1, 2
= Sporotrichum ochraceum (Corda) Sacc. Syll. Fung. 4: 105, 1886.
= Ostracoderma ochraceum (Corda) S. Hughes, Canad. J. Bot. 36: 792, 1958.

= Botrytis dichotoma Corda, Icon. Fung. 1: 18, 1837.
= Campsotrichum dichotomum (Corda) Bonord., Handb. Mykol.: 102, 1851.

= Botrytis isabellina Preuss, Linnaea 25: 75, 1852.
= Ostracoderma isabellinum (Preuss) S. Hughes, Canad. J. Bot. 36: 792, 1958.

668 ... Hennebert

Fig. 1. Chromelosporium ochraceum. A. Conidiophore with conidiogenous cells (drawing
by S.J. Hughes, DAOM 83330). B, D. Conidiophore and conidia (holotype, PRM 155414), C.
conidiophore after secession of the conidiogenous cells (DAOM74695, Mycoth. Ven. 1080).
Scale bar = 10 um.

= Polyactis crystallina Bonord., Abh. Naturf. Ges. Halle 8: 95, 1864.
= Botrytis crystallina (Bonord.) Sacc., Syll. Fung. 4: 135, 1886.
= Botrytis spectabilis Harz, Bull. Soc. Imp. Nauralistes Moscou 44(1): 144, 1871.
= Clonostachys spectabilis (Harz) Oudem. & Sacc., Ned. Kruid. Arch., 2. ser., 4: 539, 1886.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 669

Type: Chromelotrichtm [crossed out] sporium ochraceum Ca. ramulis furcis, Myrinema

generis” [scr. et del. A.C.J. Corda]. On Allium dead stem, Prague, Czechoslovakia.

Herb. Corda (Holotype: PRM 155414; isootypes: [DAOM 40946, MUCL.2895]
CoLonigs in small patches, <10 mm diam., velvety, at first white, then
ochraceous when mature.

HyPpHAE 3-5 um wide, creeping in the substratum.

CONIDIOPHORES mononematous, erect, emerging from hyphae in
substratum, with a bulbous basal cell, 28-35 x 12-15 um, ochraceous,
extending into a cylindrical, septate stipe, 100—400 um long, pale ochraceous,
the individual cells 40—95 x 10-14 um, terminally repeatedly branched with
up to five dichotomies, each branch with a basal septum and a second septum
before the subsequent dichotomy, the length of branch decreasing from one
dichotomy to the next, usually the first dichotomy 40-90 x 9-10 um, the
second 30—70 x 6-10 um, the third 30—50 x 6—9 um and so on, but in some
cases dichotomies being very short decreasing from 20 to 10 um, the angle of
the dichotomies ranging from 30° to 45°.

CONIDIOGENOUS CELLS comprising the last four and five terminal
dichotomies, together 70-100 x 6—9 um, apically clavate, <11 um, covered
with synchronous conidia borne on a denticle, and collapsing after conidial
release, seceding or (rarely) remaining as a frill on the last conidiophore cell.

Conrp1A holoblastic, borne simultaneously on denticles 2 x 1 um, one-
celled, globose or subglobose, ochraceous to salmon-colored in mass,
4—6.5 um, wall 0.5 um thick, cyanophilic, verrucose, warts prominent 0.3 um
high and blunt, with 12—14 warts in median view, seceding rhexolytically.

HasirtaT: on plant fragments.

DISTRIBUTION: Europe: Italy, France, Belgium, England, Africa: Maroc,
Uganda, Asia: Sumatra.

CoMMENTS— The name Chromelosporium remained unused until Hughes
(1958) brought the genus to light. Corda’s 1833 description of an overmature
collection was so unclear that even Corda (1837) himself did not recognize
the conspecificity of his later taxon, Botrytis dichotoma. His figure (Fic. 3A)
shows globose ochraceous conidia accumulated along the sides and the top
of the obtuse dichotomous branches.

Korf & Hennebert (1975) stated that Botrytis spectabilis was a synonym
of Chromelosporium ochraceum based on an original illustration from Harz
reproduced here (Fics. 3B-C) and preserved in MUCL 1072.

The names Botrytis spectabilis and Polyactis crystallina (another synonym
of Chromelosporium ochraceum) have been misapplied to the asexual morph

670 ... Hennebert

Fig. 2. Chromelosporium ochraceum (DAOM 46357). A. Conidiophores under low magnification.
B. Dichotomies of conidiophore. C-D. Conidiogenous dichotomies. E. Conidiophore after
secession of conidiogenous cells. F Verrucose conidia.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 671

=. —
i 2 ” * . i 7 b =

é _

4B. dicholemie. A Nes

Fig. 3. Illustrations of A. Botrytis dichotoma Corda, Icon. Fung. 1: 18, fig. 244, 1837.
B-C. Botrytis spectabilis Harz, original drawings (MUCL 1072).

of Peziza ostracoderma Korf (Hennebert & Korf 1975). For that reason, both
Botrytis spectabilis and Polyactis crystallina have been erroneously listed as
synonyms of Peziza ostracoderma in Index Fungorum. Chromelosporium
ochraceum is also erroneously cited as a synonym of C. fulvum (Link)
McGinty& al., typified by the asexual morph of Peziza ostracoderma in
Seifert & al. (2012, p. 139).

The lectotype collection of Botrytis isabellina and the authentic collection
distributed in Rabenhorst’s KLoTzscHi] HERBARIUM VIVUM MYCOLOGICUM
N° 1570, were described in sufficient detail by Preuss (1853) as “Floccis erectis
crassis repetito ramosis dichotomis vel trichotomis, apice verrucosis sporis
irregulariter accumulatis, globosis, hilo instructo, episporio verrucoso” to
confirm its synonymy with Chromelosporium ochraceum.

SPECIMENS EXAMINED

TYPE & AUTHENTIC MATERIAL. EUROPE: Czecuia: (2) Botrytis dichotoma,
Herb.Corda (PRM 155393 type), [DAOM 84706, MUCL 2896]. GERMANY: (3)
Botrytis isabellina Preuss 1850, auf [rotten] nadelholz, Herb Preuss 451 (B)
(designated here as lectotype MBT 392406) [MUCL 5999]. (4) Botrytis isabellina Pr.,
ad lignum abietinum humi jacentem, prope Hoyerswerda [Germany], Preuss [1851],

672 ... Hennebert

Rabenh., Klotzschii Herb. Viv. Mycol. 1570 (B, PR, BM, BR, PAV, L) (isolectotypes)
[DAOM 51762, MUCL 1810]. (5) Botrytis spectabilis Harz, original drawing by Harz
(isolectotype 1975) (MUCL 1072).

OTHER SPECIMENS. EUROPE: ITALY: (6) Botrytis epigaea Link f. ochracea Sacc,
ad terram argillosam in horto botanico, Padova. Aug. 1902. D. Saccardo, Mycotheca
italica Mucedinaceae. [1903, Cent. XII] n° 1178 (PR 184863, BM, L 910.224-158)
[DAOM 74898, MUCL 1803]. [The name has been listed in Michelia I :102, 1877].
(7) Botrytis dichotoma Corda, in sarmentis, foliis, capsulis putrescentibus, in Horto
botanico ticinensi. Autumno, coll. Cavara. Micol. Lomb. n° 137, tab. 1, fig. 20-24
[1894]. Cavara, Fungi Longobardiae exsiccate. 195, (PAD, BM, PAV, BPI, NY, B, L)
[DAOM 83330, MUCL 1801]. (8) Botrytis fulva Link. in scapis Allii cepae, Consiglio
(Treviso). Sept. 1897. D. Saccardo Mycotheca italica Mucedinaceae. Cent. II.186, (K-
M) [DAOM 74699, MUCL 1802]. (9) Botrytis fulva Lk. Polyactis fulva Bon. in truncis
putridis. Selva (Treviso) Oct. 1876. Saccardo PA. Mycotheca veneta. Cent. XI. 1897.
n°1080 (K-M) [DAOM 74695, MUCL 1812]. (10) Botrytis fulva Link, ad corticem
ramorum, Valtaro, Sept. 1923, coll. Renji, det. G. Bresadola, (BPI) [DAOM 83884,
MUCL 2413]. (11) Botrytis fulva Link f. argillacea, ad Salicem petandram, Eichler,
Polachia, 1894. [scr. Bresadola] Herb. Bresadola, [In Bresadola Fungi polonici a
cl. Viro B. Eichler lecti. Ann. Mycol. 1, 2: 97-131, p. 127(1903), forma argillacea of
Botrytis fulva Link is not described] (S) [MUCL2531]. UK: (16) Botrytis fulva Link.
Queen’s Cottage grounds, Kew, Nov. 1898. G.E. Massee. (K-M) [MUCL 2295]. (17)
Phymatotrichum, on Fagus sylvatica rotten wood, Sheepleas, Horsley, Surrey, R.W.G.
Dennis, March 2 1952. (K-M-IMI 49481) [MUCL 3547]. (18) Botrytis splendida
Schwein., on mossy Salix bark, Wheatfen Broad, Norfolk, E.A. Ellis , (K-M-IMI
26983) [MUCL 3568]. (16) Phymatotrichum, on Petasites ovalis, Forge Valley,
Yorkshire, coll. I.M.I., det. S.J. Hughes. (K-M-IMI 8160) [MUCL 3581]. (19) Botrytis
(Phymatotrichum), on Heracleum, Forge Valley, Yorkshire, Sept. 16 1946, coll. I.M.L.,
det. S.J. Hughes. (K-M-IMI 6851) [MUCL3592]. (20) Botrytis, Phymatotrichum, on
Petasites dead petioles, Forge Valley, Yorkshire, Oct. 1945, coll. I.M.L, det. S.J. Hughes,
(K-M-IMI 1586) [MUCL 3595]. (21) Phymatotrichum, on Eupatorium cannabinum,
Farwath, Newton Dale, Pikering, Yorkshire, Aug. 6 1960, W. Bramley. (K-M-IMI
83016a) [MUCL 3622]. (22) Phymatotrichum, on Heracleum, Forge Valley, Yorkshire,
Sept. 16 1946, coll. I.M.L., det. S.J. Hughes. (K-M-IMI 7341) [MUCL 3582]. FRANCE:
(12) Botrytis fulva Link, in ligno putrido, Céte d’Or, Sept. 1889, coll Fautrey n°9 (PC)
[DAOM 83390, MUCL 2378]. (13) Botrytis fulva Bon., sur tricot de coton pourri
pres dun lavoir, Lyon, coll. J.J. Therry. Cryptogames du Lyonnais. J.J. Therry n° 6474,
(G) [MUCL 2398]. (14) Botrytis carnea Schum., ad culmos Paludi, Meudon, Nov.
3 1893, coll. E. Roussel]. (PC) [MUCL 2706]. BELGrum: (23) Phymatotrichum, on
herbaceous stems and leaves of compositae, Forét de Soignes, Sept. 16 1956, coll. M.B.
Ellis. (K-M-IMI 69956) [MUCL 3542].

AFRICA: Morocco: (24) Phymatotrichum, sur souche de Quercus ilex, Forét
dAzrou, Moyen Atlas, Maroc, 17 Nov. 1965, G. Malencon. Herb. Cryptog. G.
Malencgon 5805, (PC) [MUCL 8041]. UGANDA: (25) Botrytis, on dead wood,
Kampala, 4000; May 1936, G. Hansford. Herb. Mycol. Dep. Agric. Uganda n° 1769
(K-M-IMI 7899) [MUCL 3613].

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 673

ASIA: INDONESIA: (26). Botrytis? op aarde, bladeren, takjes, Sumatra, Kampong
Baroe bij Medan, Juli 1927, K.B. Boedijn. n° 4619 (Bot. Museum Utrecht 179892)
[MUCL 5381].

Fig. 4. Chromelosporium herbicola (isotype NY, MUCL 5889). A-C. Conidiophores missing the
seceded conidiogenous cells. D. Verrucose conidia. Scale bar = 10 um.

Chromelosporium herbicola (Ellis & Dearn.) Hennebert, comb. nov. Fic. 4

MB 833990
= Rhinotrichum herbicola Ellis & Dearn., Proc. Canad.
Inst., n.s. 1: 90, 1897 [(as “herbicolum” |.
Type: Rhinotrichum herbicolum E|llis] & Dearness, on Solidago virga-aurea golden rod
stems, Aug. 13 1895, D.V.S. Valley, London, Canada, J. Dearness. Herb. Dearness 2314
(Holotype: DAOM [MUCL2321]; isotype NY [MUCL 5889]).

674 ... Hennebert

COLONIES in small patches, 3-5 mm wide, about 1 mm high, ochraceous.

HyPpHAE 5—15 um wide, creeping on the substratum.

CONIDIOPHORES mononematous, erect, emerging single from creeping
hyphae, as a stipe 100-150 um high, 9-15 um wide, ochraceous, slightly
constricted at septa in cells 25-35 um long, terminally branching in
successive dichotomies, at 10-45° angles, branches septate at the base and
sometimes over their length, first dichotomies 30-50 um long, second
dichotomies 20—25 um long,

CONIDIOGENUS CELLS presumably the third and fourth dichotomies
collapsed and fallen away, not observed in the material but similar to those
of Chromelosporium fulvum after Sumstine (1911).

Conip1a presumably holoblastic, borne simultaneously all along the
conidiogenous cell as described by the original authors, globose to obovate,
one-celled, (6—)7—9(—11) um, ochraceous, thick-walled and verrucose, with
18—20 warts in median view, seceding rhexolytically.

Hasirat: On decaying herbaceous plant stems, similar to Solidago.

DISTRIBUTION: Canada: Ontario.

CoMMENTS — The original description of Rhinotrichum herbicola by Ellis &
Dearness reads: “Effuse, light yellow, becoming brown in the center. Hyphae
coarse, septate, branched, nearly hyaline, 8—10 u, thick, Fertile hyphae sub-
undulate above, tips swollen and bearing the globose, sub-hyaline, finely
echinulate, 7—9 u, conidia. On dead stems of Solidago canadensis, London,
Can., Aug. 1895. Herb. Dearness n°2314

Sumstine (1911) examined the isotype specimen in NY and observed
that the “spores clustered at the apex of the fertile branches” Although
“the specimen proved to be poor’, he concluded that “it resembles in
many respects Botrytis fulva Link.’ This comment joined to the observed
dichotomous branching and the verrucose globose conidia leads to transfer
the species to Chromelosporium.

The species differs from Chromelosporium ochraceum by its shorter
conidiophores and conidial size and ornamentation.

Chromelosporium canadense Hennebert, Persoonia 7: 196, 1973. FIGS 5, 6
= Rhinotrichum carneum Ellis & Everh., J. Mycol. 1(7): 93, 1885
(non Chromelosporium carneum (Pers.) Hennebert

TyPE: Chromelosporium canadense Hennebert, on rotten wood in forest, Gatineau
Park, Gatineau, Quebec, Canada, 25.11.1960, leg. S.J. Hughes & G.L. Hennebert,
(Holotype: DAOM 71947; isotype: MUCL 1689).

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 675

Fig. 5. Chromelosporium canadense (holotype, DAOM 71947). A. Young conidiogenous cells
on terminal dichotomies. B. Primordia of the conidiogenous cells. C. Conidiogenous cells.
D. Dichotomous branching of the conidiophore. E. Mature conidia. Scale bar = 10 um.

676 ... Hennebert

COLONIES in patches <15 mm wide and <3 mm thick, effuse, loose, first
white, then tawny to cinnamon, composed of mixed hyphae and branched
conidiophores bearing clusters of conidia.

HypuHAe on substrate, thin, 4-7 um, evanescent.

CONIDIOPHORES mononematous, erect, single, tawny, stipes 100-300 x
6-10 um, then branching in regular and repeated dichotomies of different
lengths, branches divergent at 20—60° angle, the basal ones 160-200 um
long, the distal ones shorter (16—48 um), 10—12(—18) um wide, the stipe
and each branch septate at its base, the last dichotomy bearing two clusters
of 4—8 primordial conidiogenous cells.

CONIDIOGENUS CELLS formed as two groups of quadri-furcate terminal
primordia that elongate up to 30—45 x 12—22 um, slightly clavate, becoming
conidiogenous over their entire length.

Conip1A4 holoblastic, borne simultaneously on denticles, one-celled,
globose, (3.5—)4—5(—7) um, tawny, verrucose with 10-18 warts in median
view, seceding rhexolytically.

HABITAT: on rotten wood and bark, branches, mosses, plant stems and
herbs, in gardens and forests.

DISTRIBUTION: Canada and USA.

CoMMENTS—Growth on PDA was obtained from young conidiophore
hyphae taken after 3 days at 4°C from fresh material of four collections
(MUCL 1689 T, 1690, 1691, 1692) but not from conidia. Mycelium in
culture is effuse, ochre, forming dense dispersed patches; hyphae are regular,
septate, branching at an angle of c. 45°, or very irregular, closely septate in
swollen cells. In two cases, small clusters of dark brown cells were produced,
suggesting primordia of apothecia.

Herbarium specimens often lack the conidiogenous cells which are
collapsed or absent; their presence is inferred from the branching pattern
and the conidial characters.

SPECIMENS EXAMINED:

TYPE & AUTHENTIC MATERIAL: USA: OREGON: (2) Rhinotrichum carneum Ell. &
Ev., on bark, Oregon, 1885, W.S. Carpenter n° 125 [scr. Ellis] (NY).) [DAOM 84659,
MUCL 2694]. (holotype) NEw York: (3) Rhinotrichum carneum Ell. & Everh., on
rotten wood, Macoun [scr. Ellis]. Ellis Collection (NY) [DAOM 84677, MUCL 2839].
(4) Rhinotrichum carneum Ell. & Everh. [no substrate, no date], Macoun [scr. J.B.
Ellis]. Ellis Collection (NY) [MUCL 2840].

OTHER SPECIMENS: CANADA, Ontario (5) Hyphelia terrestris, on Tilia,

Nashville, York Co., Oct. 25 1953, coll. det. RF. Cain (TRT 30178) [DAOM 84684,
MUCL 2858]. (6) Hyphelia terrestris, on hardwood, Nashville, Nov. 14 1954, coll.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 677

Fig. 6. Chromelosporium canadense (holotype, DAOM 71947). A. Conidiophores at low
magnification. B-D. Young stages of conidiogenous cells. C. Half and fully mature conidioma. E.
Wide angle of the dichotomies. F. Terminal bunch of mature conidiogenous cells.

det. R.E. Cain (TRT 31311) [DAOM 84683, MUCL 2857]. (7) Hyphelia terrestris, on
Populus Nashville, Oct. 22 1955, coll. det. RE Cain (TRT 31699, BPI) [MUCL 2419].
(8) Hyphelia terrestris, on decayed log, New Durham, Brant Co., Oct. 14 1956 (TRT

678 ... Hennebert

32870) [DAOM 84688, MUCL 2862]. (9) Botrytis fulva Link, on dead wood, Oct.
20 1896, Macoun [Scr. J.B. Ellis]. Herb. Ellis (BPI) [DAOM 83886, MUCL 2415].
(10) Botrytis (Phymatotrichum) fulva Link, on decayed wood, N. Bathurst street
Toronto, Nov. 17 1934, H.S. Jackson, det. D.H. Linder, Herb. R.E Cain 8207 (TRT
8065, FH, DAOM 81409) [MUCL 2889)] (11) Botrytis (Phymatotrichum) fulva Link,
on rotten wood, S. Aurora, Oct. 23 1932, H.S. Jackson, det. D.H. Linder. Herb. R.E.
Cain 8210 (TRT 8060, DAOM 81410) [MUCL 2890]. (12) Ostracoderma, on soil
of lawn, North Toronto, June 17 1960, S.J. Hughes. (DAOM 83325) [MUCL 2255].
(13) Chromelosporium, on bark and plant decay, South March, April 10 1962, G.L.
Hennebert (MUCL 3067). QUEBEC (14) Ostracoderma on bark, Gatineau Park,
Nov. 25 1960, S.J.Hughes. (DAOM 71946) [MUCL 1688]. (15) Ostracoderma, on
wood, Gatineau Park, Nov. 25 1960, S.J.Hughes. (DAOM 71948) [MUCL 1690]. (16)
Ostracoderma, on wood, Gatineau Park, Nov. 2(5, 1960, S.J.Hughes. (DAOM 71949)
[MUCL 1691]. (17) Ostracoderma, on wood, Gatineau Park, Nov. 25, 1960, S.J. Hughes.
(DAOM 71950) [MUCL 1692]. (18) Ostracoderma, on wood and bark, Gatineau Park,
Oct. 31, 1960, S.J. Hughes. (DAOM 71399) [MUCL 1689]. (19) Ostracoderma, on stem
of Veratrum viride, Yoho Valley, Aug. 8 1960, S.J. Hughes. (DAOM71326) [MUCL
1513]. (20) Chromelosporium, on Betula papyrifera rotten wood, Gatineau Park, Oct.
31 1960, G.L.Hennebert. (DAOM 71545, MUCL 1590). (21) Chromelosporium, on
rotten wood, Gatineau Park, Oct. 7 1960, G.L.Hennebert. (DAOM 71419, MUCL
1505). MANITOBA (22) Botrytis near phymatotricha Sacc. prov. cfr. lateritia, C.E.
Fairman suggests Botrytis carnea Schum, on old board, Winnipeg, Sept. 16 1928,
G.R. Bisby 4140 [scr. Dearness]. Herb. Dearness 6732 (DAOM 84789) [MUCL 3070].
USA, OunI0 (23) Mycobiota of Ohio. Botrytis isabellina Preuss, on rotten wood, The
7 Caves, Highland Co., coll. det. D-H. Linder 2667, Sept. 6 1933, Herb. W. Bridge
Cooke (NY, FH, DAOM 84679) [MUCL 2847]. Iowa (24) Hyphelia laxa Schw., on
decorticated conifer wood. (IA) [DAOM 83317, MUCL 2260]. SouTH CAROLINA:
(25) Botrytis epigaea Link var. on clay surface after rain, Sept. 1883, H.W.R. [scr. H.W.
Ravenel]. Herb. U.W. Ravenel, (K-M, DAOM 83332) [MUCL 2281]. MASSACHUSETTS
(26) Botrytis? Hyphelia spectabilis Harz, on coniferous bark, York, Sept. 14 1891.
Herb. Thaxter 137 (FH) [DAOM 84702, MUCL 2886]. (27) Botrytis fulva Link, on
hardwood branches on the ground, Beaver Brook reserve, Belmont, Oct. 3 1937, coll.
G.D. Darker 64-90, det. D.H. Linder. (FH) [DAOM 84703, MUCL 2888]. NEw YorRK
(28) Ostracoderma canadense, on stem of fern in a pond, Forest Home, Ithaca, May 1
1962, G.L. Hennebert. (MUCL 3120). NEw JERSEY (29) Botrytis epigaea Pers., on old
pine boards partly buried in the ground, Newfield, N.J., Sept. 1881, Ellis. Ellis North
American Fungi 827 (WIS, CUP, K-M, B, G, L) [MUCL 1804].

Chromelosporium arenosum Hennebert, Persoonia 7: 196, 1973. FIG. 7

Type: Flora Venezuelae 2474, on rotten wood of Espeletia, 3550 m, alt., Mucudaji,
Sanide Santo Domingo, Estada Mesida, July 22 1958, coll. R.W.G. Dennis. (K-M)
(Holotype: MUCL 2298 [DAOM 83359]; isotype IMI 75582 [MUCL 5889]).

EryMo.Locy: from the Latin arenosus or sand-like, suggesting the spreading
granulose aspect of the sporulating conidiophores of ochraceous color seen under
low magnification.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 679

Fig. 7. Chromelosporium arenosum (holotype, DAOM 83359). A. Young conidiophore branching.
B. Erect conidiophore with conidiogenous cells. C. Mature conidiophore with conidia borne on
aerial hypha. D. Conidiophore after secession of conidiogenous cells. E. Conidia. Scale bar = 10 um.

COLONIES superficial, sparse, delicate, cobweb-like white mycelium, becoming
arenose ochraceous with mature conidiophores appearing like minute,
scattered grain.

Hypuae repent, hyaline, single, 7—9 um wide, regular, straight, branched,
thin-walled, smooth, septate with cells 7-12 um long, sometimes regenerating
after collapse from septum by internal narrow hyphal proliferations 3—4 um
wide.

CONIDIOPHORES arising singly, mononematous, as erect branches of the
repent hyphae, short, 70-100 um high, 8—9 um wide, stipes with the basal
cell bulbous 11—13 x 6—8 um,, constricted at septa, cells 15-50 um, apically
branching in dicho- or trichotomies forming 2—8 terminal cells 40-50 um
long, obtuse, clavate up to 13 um wide and conidiogenous.

680 ... Hennebert

Conip1a holoblastic, borne simultaneously on denticle 1 x 0.5 um, one-
celled, globose or ovoid, 3.5—5.5 x 3.5—6.5(—8.1) um, mostly 4.5 um wide,
0.5—1 um thick-walled, the outer wall hyaline, the inner wall subhyaline to
ochraceous and coarsely verrucose, with 6—10 globoid or elongate warts in
median view, seceding rhexolytically.

HABITAT: on rotten bark of Espeletia sp. in the Tropics.

DISTRIBUTION: Venezuela.

Chromelosporium macrospermum Hennebert, Persoonia 7: 197, 1973. Fic. 8
Type: living and dried cultures from Peziza sp. ind. on sterilized soil in greenhouse,
Heverlee, Belgium, 2.04.1960, leg. G.L. Hennebert (Holotype: MUCL 1116; isotype
DAOM 67492 = dried culture of MUCL 1116).

COLONIES on malt agar substrate thin, white to rust-color when sporulating,

comprising interwoven and prostrate hyphae, hyaline to subhyaline,

producing laterally large spherical cells, 40-50 um diam, thin-walled.

CONIDIOPHORES mononematous, erect, pale to rust-colored, septate,
stipes 400-600 x 15-18 um, apically bi- or quadri-furcate, branches 20 um
long, few septate, the distal ones erect, radiate, cylindrical to clavate 130-160
x 20-25 um, conidiogenous.

Conip1A holoblastic, borne on a denticle, more or less simultaneous,
globose, rust-colored, 15-23 (av. 19.7) um, thin-walled, finely punctate,
seceding rhexolytically.

Hapsirat: sterilized greenhouse or nature soil

DISTRIBUTION: Europe: Belgium, Oceania: Australia.

ComMENnts — This unique strain MUCL 1116 was found in one ascospore
germinating from several apothecia then identified as Peziza ostracoderma,
collected in a tropical greenhouse of the Faculty of Agronomy UCL in
Heverlee, Belgium in 1960. Korf differentiated the size and ornamentation of
the ascopores preserved in lactic acid mounted slides of the original Peziza
apothecia (Hennebert & Korf 1975) but in the absence of the single original
apothecium, he could not circumscribe the species. The same species has been
isolated from soil in South Australia by Dr. G.C. Hansford at the University
of Adelaide in 1953 and preserved as living culture IMI 54710 in the culture
collection at Egham and as dried culture in K-M—IMI 54710 under the name
Phymatotrichum tax. sp. 7. The culture is C. macrospermum mixed with
conidia of P. ostracoderma and unidentified hyaline chlamydospores.

The species might be a mutant Peziza ostracoderma or a distinct
undetermined species of Peziza.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 681

Fig. 8. Chromelosporium macrospermum (ex holotype, MUCL 1116). A-B. Conidiophores at
diverse stages. B. Punctate conidia. D. Swollen cells in culture. Scale bar = 10 um.

682 ... Hennebert

Species of Pezizaceae with known sexual morphs and
similar mononematous conidiophores and conidiogenesis

Peziza ostracoderma Korf, Mycologia 52: 650, 1961 [“1960”]. Fic. 9
= Plicaria fulva R. Schneid., Zentralbl. Bakteriol. Parasitenk. Infektionskrankh.
Hyg., 2. Abt., 108: 147, 1954 [non Peziza fulva Pers. 1822, nom. sanct.].
= Dematium ollare Pers., Syn. Meth. Fung. 2: 697, 1801.
= Botrytis fulva Link, Spec. Plant., ed. 4, 6(1): 58, 1824, nom. illeg. [superfluous].
= Sporotrichum fulvum Fr., Syst. Mycol. 3: 418, 1832, nom.
sanct. [not “(Link) Fr’; non Link 1809].
= Trichosporum fulvum (Fr.) Fr., Summa Veg. Scand. 2: 492, 1849.
= Polyactis fulva (Fr.) Bonord., Handb. Mykol.: 115, 1851 [not “(Link) Bonord.”].
= Chromelosporium fulvum (Fr.) McGinty, Hennebert & Korf,
Mycologia 67: 216, 1975 [not “(Link) McGinty et al.”].
= Chromelosporium ollare (Pers.) Hennebert, Persoonia 7: 197, 1973.
= Haplaria nitens Delacr., Bull. Soc. Mycol. France 6: 140, 1890.
= Botrytis luteobrunnea Krzemien. & Badura, Acta Soc. Bot. Poloniae 23: 727, 1955 (1954).
= Mycotypha dichotoma F.A. Wolf, J. Elisha Mitchell Sci. Soc. 71: 217, 1955.
= Ostracoderma dichotomum (F.A. Wolf) Matsush., Icon.
Microfung. Matsush. Lect.: 103, 1975.
Types: Plicaria fulva R. Schneid., on damp sterilized soil in greenhouse, Berlin-
Dahlem, Germany, 25.3.1953 (Holotype: B; authentic material in CUP R.P.K. 4114).
Dematium ollare Pers.: dried culture from living culture of Plicaria fulva R.
Schneider, on damp sterilized soil, greenhouse, Berlin-Dahlem, Germany, March
1953, received in Febr. 1954 from R. Schneider (Neotype: MUCL 1112, designated
in Hennebert 1973; isoneotypes: dried culture DAOM 81809, living cultures CBS
382.54, CCRC 36608, IMI 059206).

COLONIES velvety to floccose, white when young, yellow to fulvous or
cinnamon when sporulating, rapidly growing.

HypHAE mostly prostrate, interwoven, branched, septate, anastomosing,
hyaline to pale fulvous.

CONIDIOPHORES mononematous, solitary or gregarious, erect and
divergent, arising from prostrate or aerial hyphae; stipe 130-600 x 8-17 um,
hyaline to fulvous, sparsely septate, attenuate at the base, apically 1-3 times
dichotomously branched, dichotomies short, 10—25 x 5-13 um, septate at
the base, the terminal ones clavate, slightly inflated <15 um, conidiogenous.

CONIDIOGENUS CELLS producing conidia along their length, collapsing
after release and seceding away at basal septa, leaving the stipe or the lowest
dichotomies as a stump.

Conip1a holoblastic, borne simultaneously on a denticle 3 x 1 um, densely
and irregularly spaced, globose or napiform, 5—9(—14) um (mean = 7.5 um),
fulvous, wall thin, finely punctate, seceding rhexolytically. Conidia

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 683

Fig. 9. Peziza ostracoderma (neotype MUCL 1112). A-C. Conidiophores at diverse stages.
D. Punctate conidia. Scale bar = 10 um. The magnification of the line-drawings of conidia in
figures 8 and 9 is half that in other figures.

germinate and colonies sporulate profusely on malt agar and diverse organic
poor culture media.

Hasitat: On sterilized soil in greenhouses, on mushroom beds, on
cardboard, paper pots, paper, and old textiles in moist chambers, on humid
plaster walls in houses, on moist hay, on dung of rodents, and on forest soil.

DISTRIBUTION: Europe, North America, Asia.

ComMMENTs—Korf (1961) knew the species in both its asexual and sexual
morphs in the greenhouses at Cornell when he received the type and a living
culture of Plicaria fulva. The species has elliptical ascospores like most Peziza
species. Seeing the sanctioned name Peziza fulva Pers., he created the new

684 ... Hennebert

name Peziza ostracoderma, referring to Hughes’ opinion that the conidial
morph could be referred to Ostracoderma. Hennebert (1960) reported and
described the same fungus observed in a tropical greenhouse of the Faculty
of Agronomy UCL in Heverlee, Belgium, in 1960.

Hennebert (1973) segregated Chromelosporium from Ostracoderma,
which Hughes (1958) had considered synonymous. He named the conidial
morph of P. ostracoderma, Chromelosporium ollare,, with Dematium ollare
as basionym, which he neotypified with GLH 1112 (MUCL 1112) in the
absence of an original authentic specimen from Persoon.

Hennebert & Korf (1975) cited Dematium ollare as the earliest post-
Linnean name for the conidial morph common in greenhouses. Link (1824)
transferred the species to Botrytis as Botrytis fulva, an illegitimate name with
Dematium ollare cited as its unique synonym. Fries (1932a) excluded D. ollare
from his genus Dematium, treating it, after Link, as a synonym of B. fulva,
both of which he transferred into Sporotrichum as S. fulvum, a sanctioned
name.

Searching for the earliest possible name to combine in Peziza in
accordance with the 2017 Shenzhen ICN, it is apparent that the earliest name
of the fungus, Dematium ollare, cannot be used, because of Peziza ollaris Fr.
(Fries 1822), a different species, the name of which is sanctioned over Peziza
ollaris Schaeff. (Fungorum in Bavaria et Palatinatu circa Ratisbonam Icones
4:126, 1774) and Peziza ollaris Pers. (Mycol. Eur. 1: 299, 1822), which might
be the present species.

Despite what is posted on Index Fungorum, the names Alytosporium
fulvum (Link) Link and Nodulisporium fulvum S. Hughes, being based on
Sporotrichum fulvum Link, are synonymous with neither Dematium ollare
nor Botrytis fulva.

Haplaria nitens, added here as a synonym, was collected on sterilized oak
barks from a tannery used as mulch in a warm glasshouse of the Laboratoire
de Pathologie végétale de l'Institut national Agronomique in Paris. Its conidia
are minutely verrucose.

The variable conidiophore length and variable number and length of
the dichotomies of the species might explain its frequent confusion with
Chromelosporium ochraceum. ‘The primary diagnostic differences reside in
conidial size and ornamentation and the ecological habitat.

In an attempt to clarify the relationship with Chromelosporium
macrospermum, the variability of conidial size in monoascospore strains
of Peziza ostracoderma was studied on different culture media (malt-agar,

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 685

potato-dextrose-agar, carrot-agar, and jiffy-agar, a mixture of soil and peat).
Although conidial size varied between 5-9 um and one strain produced
conidia <12 um and a different strain produced conidia <14 um, none
reached 15—23 um, the conidial size reported for C. macrospermum of.

TYPE SPECIMEN EXAMINED. EUROPE: FRANCE: (2). Haplaria nitens Del. n. sp. Paris
(scr. Delacroix). (holotype, PC) [isotypes, DAOM 59453, MUCL2700]

OTHER SPECIMENS EXAMINED See Hennebert & Korf (1975).

Plicaria trachycarpa (Curr.) Boud.,

Hist. Class. Discom. Eur. 50, 1907, var. trachycarpa Figs 10, 11
= Peziza trachycarpa Curr., Trans. Linn. Soc. London 24: 493, 1864.
= Discina trachycarpa (Curr.) P. Karst., Acta Soc. Fauna Fl. Fenn. 2(6): 113, 1885.
= Detonia trachycarpa (Curr.) Sacc., Syll. Fung. 8: 105, 1889.
= Curreyella trachycarpa (Curr.) Massee, Brit. Fung.-Fl. 4: 401, 1895.
= Lamprospora trachycarpa (Curr.) Seaver, Mycologia 6: 19, 1914.
= Plicariella trachycarpa (Curr.) Velen., Monogr. Discomyc. Bohem.: 342, 1934.
= Galactinia trachycarpa (Curr.) Le Gal, Bull. Trimestriel
Soc. Mycol. France 78: 212, 1962.
= Rhinotrichum trachycarpum F.A. Wolf, J. Elisha Mitchell Sci. Soc. 74: 166, 1958.

= Chromelosporium trachycarpum Hennebert, Persoonia 7: 197, 1973.

Types: Peziza trachycarpa Curr., supra solum deustum, Ascot com. Surrey, Nov. 1862
(Holotype: K(M) 29980).

Chromelosporium trachycarpum Hennebert, asexual morph of Peziza
trachycarpa, on burned area, Camp II, Allegany State Park, USA: June 11, 1961, coll. &
isol. G.L. Hennebert, det. R.P. Korf (Holotype, DAOM 83324; isotype, MUCL 2197).

CoLonigs fast growing on malt agar medium, pellicular, white to pale
ochraceous.

Hypuas thin, hyaline, interwoven and prostrate.

CONIDIOPHORES mononematous, erect, very short, 50-100 x 8-10 um,
repeatedly dichotomously or assymetrically branched, irregularly septate,
branches cylindrical, short, 20-35 x 8—10 um, widely divaricate, becoming
totally conidiogenous, forming compact globose conidial heads.

Conrp1A holoblastic, borne simultaneously on denticle, yellow-ocher,
one-celled, globose or shortly ovate, 5—7 x 5—9 um, wall finely verrucose,
with 10—15 warts in median view, seceding rhexolytically.

Hasirat: in moist burned area in forests.

DISTRIBUTION: Northern Hemisphere.

CoMMENTS— The drawings were made while I was in Canada from an
ascospore culture of the species collected in Ontario (MUCL 23339) identified

686 ... Hennebert

Fig. 10. Plicaria trachycarpa. A-B. Branched conidiophore. C. Terminal conidiogenous cells.
D. Much septate conidiophore on porcupine dung (MUCL 2933). E. Punctate conidia.
(A-C and E on malt agar MUCL 2339). Scale bar = 10 um.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 687

Fig. 11. Peziza trachycarpa. A. Initiation of conidiophores. B-D. Globular branched conidiophores
showing the dichotomies. E. Initiation of conidia. (A-E, MUCL 2339). E Mature conidiogenous
cells (DAOMC 199631 = MUCL 57201 on malt-agar).

688 ... Hennebert

as identical to DAOM 83324 but not after examination of K(M) 29980.
A living strain labelled as Plicaria trachyspora var. muricata (= Plicaria
carbonaria (Fuckel) Fuckel 1870) was recently received as DAOMC 199631
that, on 2 % malt agar, developed similar clusters of dichotomous branches
close to the substrate and bearing mature conidia.
SPECIMENS EXAMINED;
NORTH AMERICA: USA, New York (2) Peziza trachycarpa Currey, on burned
area, State Line Run, near Onoville, Cattarangu Co., June 10 1961, coll. Kumi T Korf, det.
R.P. Korf (MUCL 2198). (3) Chromelosporium, on porcupine dung (in moist chamber)
from Stoddard Brook Road, Allegany State Park, June 11 1961, coll. & isol. G.L.
Hennebert. (DAOM 89363, MUCL 2933). CANADA, Ontario (4) Peziza trachycarpa
Currey, on moist clay soil in mixed woods, Bell’s Corners, July 31 1961, coll. & isol.
G.L. Hennebert 2339. (DAOM 83382, MUCL 2339). (5) Plicaria trachycarpa (Currey)
Boudier var. muricata Grelet on burned litter in burned mixed forest, Renfrew Co., Ont.,
Sept. 2 1979, K.N. Egger 0281, dried and culture (CCF 6918, DAOMC 199631, MUCL
57201).
EUROPE: UK (6) Peziza trachycarpa (Curr.) Boud., conidia on cardboard flower
pot., Evesham, Worcs., March 25 1955, col. R.E. Taylor, det. R.W.G. Dennis. Dried
culture IMI 59800) [MUCL 3514].

Chromelosporiopsis

Chromelosporium-like species with synnematous conidiomata resemble
mononematous Chromelosporium species in having the same conidiogenesis
and ornamented globose conidia but differ in the conidiophore
fasciculation and asymmetric sparsely septate dichotomous branching (a
branching pattern described here as coralloid). This concerns two asexual
species named by Hennebert (1973)—Chromelosporium carneum and
C. coerulescens—both with sexual morph unknown. For these species, the
new generic name Chromelosporiopsis is proposed. Similar asexual morphs
have also been described in some Pachyphlodes species of the Pezizaceae.

Chromelosporiopsis Hennebert, gen. nov.
MB 835622

Differs from Chromelosporium by its synnematous conidiophores and irregular
successive bifurcate branching.

TYPE SPECIES: Chromelosporiopsis carnea (Schumach.) Hennebert
EryMo.ocy: Chromelosporium + -opsis, similar to.
Ascomycota, Pezizaceae, sexual morph unknown.
HyPHAE septate, branched and anastomosed, fasciculating in synnemata,
forming defined or effuse cushions, diversely colored (white, ochre, yellow,
rose, flesh red, blue, or violet).

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 689

CONIDIOPHORES synnematous, laterally and/or apically branching in
irregular successive dichotomies called here a coralloid pattern, sparsely
septate, apically slightly inflated.

CONIDIOGENUS CELLS subterminal and terminal branches forming
synchronously along their lengths holoblastic conidia, each on a denticle;
secession rhexolytic.

Conip1A one-celled, globose or subglobose, with thick ornamented
(finely to coarsely verrucose) wall, colored in mass. seceding rhexolytically.

HABITAT: on organic soil.

Chromelosporiopsis carnea (Schumach.) Hennebert, comb. nov. _ FIGS 12-14, 15A
MB 835623
= Botrytis carnea Schumach., Enum. Pl. 2: 238, 1803, nom. sanct.
= Isaria carnea Pers., Ann. Bot. (Usteri) 15: 13, 1795; Syn. Meth. Fung. 2: 689, 1801.
= Chromelosporium carneum (Pers.) Hennebert, Persoonia 7: 196, 1973.
= Polyactis carnea Ehrenb., Sylv. Mycol. Berol. 25, 1818.
= Mucor carneus (Ehrenb.) Link, Spec. Plant., ed. 4, 6(1):
88, 1824, nom. illeg., non Schaeff. 1774
= Botrytis carnea (Ehrenb.) Spreng., Syst. Veg., ed. 16, 4(1):
551, 1827, nom. illeg., non Schumach. 1803.
= Sporodinia carnea (Ehrenb.) Wallr., Fl. Crypt. Germ. 2: 317, 1833.
= Ostracoderma carneum (Ehrenb.) S. Hughes, Canad. J. Bot. 36: 792, 1958.
= Botrytis rosea Link, Mag. Ges. Naturf. Freunde Berlin
7: 36, 1815, nom. illeg., non DC. 1805.
= Botrytis linkii Duby, Bot. Gall, 2: 919, 1830 [as “linckii”].
= Ostracoderma linkii (Duby) S. Hughes, Canad. J. Bot. 36; 792, 1958.
= Campsotrichum splendidum Schwein.,Trans. Amer. Philos. Soc., n.s. 4: 283, 1832.
= Botrytis splendida (Schwein.) Sacc., Syll. Fung. 4: 123, 1886.
= Rhinotrichum opuntia Berk. & Broome, Ann. Mag. Nat. Hist., ser. 2, 13: 462, 1854.
= Botrytis carnea f. foliicola Roum., Fungi. Sel. Gall. Exs., Cent. 14: no. 1367, 1881.

Types—Polyactis carnea Ehrbg.[scr. Ehrenberg] on leaves of Fagus sylvatica, Herb.
Schwaeningrichen (STR) (MBT 392408, here designated as lectotype [DAOM
83897, MUCL 2440]). Polyactis carnea Ehrbg. [scr. Ehrenberg] on leaves of Fagus
sylvatica, Herb. Nees (STR) (Isolectotypes: DAOM 83896, [MUCL 2439]; Herb.
Persoon (L 910-262-747) [MUCL 2464]).

Chromelosporium carneum (Pers.) Hennebert on leaves of Quercus pedunculata
and Fagus sylvatica, Forest de Soignes, Tervueren, Belgium, Aug. 18 1960, leg. G.L.
Hennebert (Epitype: MUCL 1208, designated as “neotype” by Hennebert, 1973;
isoepitype: DAOM 74697).

CoLonligs superficial, fast growing and evanescent, in scattered tufts of hyphae,
3-15 mm wide, 15-2 mm high, comprising <15 erect divergent synnemata

690 ... Hennebert

Fig. 12. Chromelosporiopsis carnea. A Synnemata (MUCL 1806) .B. Coralloid branching of the
conidiophores. C. Conidiogenous cells. D. Verrucose conidia (B-D, isolectotype MUCL 2464).
Scale bar = 10 um.

bearing conidia in their upper half, white when young, flesh-colored when
mature on the field, ochraceous salmon when dried.

HypHae repent, sparse, delicate, hyaline to ochraceous, single or aggregated,
(9—)12—15(—23) um wide, thin-walled, smooth, septate, branched, often
anastomosing, with short cells.

SYNNEMATA arising from the basal mat of hyphae, erect columnar, <1.5 mm
high, 50 um wide, composed of <30 growing conidiophores.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 691

Fig. 13. Chromelosporiopsis carnea, cluster of synnemata with isarioid conidial head (MUCL 6278).

CONIDIOPHORES stipes contiguous, 11-17 um wide, anastomosing, septate
at 50—80-um intervals, thin-walled, smooth, slightly bent outwards laterally
and apically in the upper half of the synnemata and branching in a coralloid
pattern of asymmetric dichotomies, one branch of each dichotomy developing
first and sometimes becoming septate at the base,

CONIDIOGENOUS HEAD formed of 4—9 last successive bifurcations, the
branches being 15-50 x 6-10 um, apically obtuse, slightly clavate, 7-12 um
wide and often bent, all branches conidiogenous, forming an isarioid head.

Conip1A holoblastic, borne simultaneously on denticle 1 x 0.5 um, 5-11
um distant from each other, one-celled, globose, occasionally subglobose,
4.8-6.6(—7.8) um (most 5.4-6 um), walls 1-1.5 um thick, the inner wall
ochraceous, the outer wall cyanophilic and coarsely verrucose, bearing 8-12
rounded warts in median view, seceding rhexolytically.

HasiTaT: on dead leaves of Fagus sylvatica and Quercus pedunculata,
also on other leaves, bark, mosses, and organic debris on soil, in forests, from
August to October.

DISTRIBUTION: Europe: Austria, Belgium, France, Denmark, Germany,
Great Britain, Netherlands, Sweden.

CoMMENTS— The earliest description and illustration of Chromelosporiopsis
carnea is by Persoon (1795) under the name Isaria carnea, with conidiophores
sticking together (“conferta’), at first white, then flesh-colored (“primo albida
dein carnea’) and evanescent (“evanescens”), illustrated in Persoon (1796:
Observ. Mycol. 1, tab. 2 figs 6-7) by fine color paintings (Fic. 15A). The

692 ... Hennebert

Fig. 14. Authentic specimens of Isaria carnea Pers. A-C. Isaria carnea [written by Persoon].
A. Isaria carnea [written by Persoon]. A. Three pieces of Fagus leaves. B. Enlarged immature
colony. C. Enlarged collapsed synnemata. D-E Isaria carnea var? [written by Persoon].
D. Patch of moss. E-F. Enlargements of a small patch of the fungus showing young white isarioid
synnemata. (Photos J. Nuytinck and Dr M. Scherrenberg, Naturalis Museum, Leiden).

authentic specimens of Isaria carnea in Persoon's herbarium, signed by Persoon
but with no date, are here documented by the excellent photographs made
by Dr Nuytinck and M. Scherrenberg in Leiden (Fic. 14). Schweinitz (1832)
showed that Isaria carnea has fascicles of hyphae (synnemata) diverging from
a shared base, pale brown, apically floccose and bearing abundant fleshy-red
spores (‘sporulis carneo-rubris’) spread along the hyphae. Isaria carnea was
treated by Fries (1832a,b) as a synonym of Dactylium macrosporum Fr., nom.
sanct. [= Botrytis macrospora Ditmar, nom. illeg.], but it is really a different
fungus, and and its epithet is therefore potentially available for use.

However the epithet is not truly available, as Fries (1832a) accepted and
sanctioned the species under the name Botrytis carnea based on Schumacher’s
description and his examination of Ehrenberg’s specimens of Polyactis carnea.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 693

Botrytis carnea is described as “cespitosa, stipitibus brevissimis, dichotomis,
ramosissimis, albidis, sporulis congestis spicatis carneis; in lingo putrido
Betulae albae, Septembr,’ while Polyactis carnea shows “floccis suberectis
dichotomis capitatis albis, sporidiolis primum albis, dein carneis, globosis. In
foliis pinorum. Pluvio freq. In fossis. Septembr.’ As neither Schumacher nor
Ehrenberg cited Persoon, they are two distinct names for the same species,
not obligate synonyms. As the name Botrytis carnea is sanctioned it must
serve as the basionym for the species as understood here.

No original material of Botrytis carnea is available, but three good
specimens collected by Ehrenberg and preserved in STR and L under the
name Polyactis carnea contain synnemata, bifurcate branching hyphae, and
verrucose conidia.

Campsotrichum splendidum Schwein. n° 2695 is described with synnemata
(“coalitis floccis”), furcate branches emerging along the upper half, and
bearing reddish orange verrucose conidia (“pulcherrime decorate”). This is a
possible synonym of C. carneum.

3

accarde | Fungi alates

Huphomycetene

th bey li CQ ebiiaeas
Costa, /Hettorie) on Rene

Sut. WPL.

788. Jon 1881 683. Jan. 1881

Fig. 15. A. Persoon’s illustration of Isaria carnea in Observ. Mycol. 1: tab. II, fig. 6-7, 1796.
B-C. Saccardo Fungi Autografice Delineati (1881), fig. 688: Botrytis carnea Schum. and fig. 689:
Botrytis epigaea var. rosea Sacc.

Saccardo (1881) illustrated Botrytis carnea (Fic. 15B) as mononematous
and dichotomous with verruculose, rose-isabella conidia without indication
of synnemata. However, he drew synnemata and asymmetric bifurcations
in Botrytis epigaea var. rosea, another synnematous Chromelosporium-like
taxon (Fic. 15C). Saccardo (1886) also described B. carnea var. quercina
with smaller conidia, 4.5—5 um, asperulate and rose-colored. Both of these
varieties show characters of C. coerulescens.

694 ... Hennebert

SPECIMENS EXAMINED.

AUTHENTIC SPECIMENS: EUROPE: (5), Isaria carnea [scr. Persoon] on leaves of
Fagus leaves, Herb. Persoon (L 910-258-645). (6) Isaria carnea var? [scr. Persoon]
on a patch of moss. Herb. Persoon (L 910-258-663) [the specimen bears immature
smooth conidia]. GERMANY, (7) Botrytis rosea Link, on small pieces of leaves of Fagus
sylvatica, Rostock. Herb. Link (B) [DAOM 51764, MUCL2451]. UK, (8) Rhinotrichum
decolorans Forden, on cupules of Fagus sylvatica, Forden 312. Herb. M.C. Cooke 1885
(K-M) [MUCL 3495].

OTHER SPECIMENS: EUROPE, UK (9) Phymatotrichum, on bare soil and dead
leaves, Ashridge, Herts., England, July 17 1955, D.A. Reid (K-M) [MUCL 2304]. (10)
Phymatotrichum sp. on soil and vegetable debris, Windsor Great Park, Windsor, Oct.
3 1962, D.A. Reid & R. McNabb (K-M) [MUCL 3133, MUCL 3494]. (11) Botrytis
carnea, on Epilobium hirsutum, Witham Park, Oxfordshire, Sept. 17 1949, M.B. &
J.PEllis (K-M-—IMI60211) [MUCL 3517]. (12) Botrytis aff. splendida Schw., on mossy
Salix bark, Wheatfen Broad, Nrf., M.B. Ellis (K-M-IMI 26983) [MUCL 3568]. (13)
Phymatotrichum sp. on petioles of Petasites ovatis, Masham, Yorks., Oct. 13 1947, S.J.
Hughes (K-M-IMI 19231b) [MUCL 3572]. (14) Phymatotrichum, bark of Quercus,
Kinclaven, Perthshire, Sept. 1953, M.B. Ellis (K-M-—IMI63926) [MUCL 3505]. (15
Phymatotrichum sp., on bark and earth ina deep hole, Ashridge, Hertford. July 17 1956,
D.A. Reid, det. M.B. Ellis (K-M-—IMI 60584) [MUCL 3520]. (16) Phymatotrichum
sp., on rotten wood, Ruislip Woods, Oct.14 1955, C. Booth, det. A.H.S.. Brown.
Herb.(K-M-IMI 61356) [MUCL 3523]. (17) Phymatotrichum, on moss on beach,
Burnham, Beeches, Oct. 20 1956, A.H.S. Brown. (K-M-IMI 69690) [MUCL 3541].
(18) Phymatotrichum., oak and hazel leaf litter, Park Wood, Ruislip, Oct. 15 1949,
P.K.C. Austwick (K-M-IMI 37957) [MUCL 3559]. (19) Chromelosporium carneum,
decaying Quercus wood, Pett near Hastings, Sussex, Aug. 29 1965, P.C. Holland,
det. W. Gams (MUCL 7929). (20) Chromelosporium carneum, on stem debris,
Ashdown Forest, Forest Row, Sussex, Oct. 1 1967, D. Mitchell & P.C. Holland (MUCL
11290). NETHERLANDS (21) Botrytis fulva Link ex Fr. on herbaceous stems under
Fagus sylvatica. Bussum, Oct. 24 1929, WJ. Liittjeharms (L) [DAOM 83937, MUCL
2515]. AUSTRIA (22) Botrytis carnea Schum. ad folia et cortices putridos, sylvis
umbrosis, autumno, L. Fuckel.. Fuckel Fungi. Rhen. Exs. 146 (G, K-M, GRO, NY)
[DAOM 74694, MUCL 1808]. DENMARK (23) Phymatotrichum, on leaves, wood
and cupules of Fagus sylvatica, Gris Skov, Sealand, Oct. 2 1955, S.J. Hughes (DAOM
51702). (24) Phymatotrichum, on wood chips of Fagus sylvatica, Gris Skov, Sealand,
Oct. 2 1955, S.J. Hughes (DAOM 51690). PoLAND:(25) Botrytis carnea Schum., in
trunco Juniperi, Eichler, in herb. Bresadola 184 (S) [DAOM 83948, MUCL 2532].
(26) Chromelosporium carneum, on rotten wood, Biatowiesga forest, Pologne, Sept.5
1966, W. Gams (MUCL 9298). (27) Chromelosporium carneum, on rotten wood,
Augustow Reserve, Starozym, Pologne, Sept.3 1966, W. Gams (MUCL 9299). FRANCE
(28) Botrytis fulva Link écorce de Quercus et Corylus, Lyon, Sept. 1879, J. Therry. C.
Roumeguere Fungi Gall. Exs. (BR) [DAOM74695, MUCL 1809]. (29) Botrytis carnea.
feuilles de chéne [Quercus] pourrissantes, Tassin, Lyon. Sept. 1880, Cryptogames du
Lyonnais, J.J. Therry. 5092 (PAD) [MUCL 1870]. (30) Phymatotrichum, on mossy
bark of Quercus, Forét de Jupilles, France, Sept.15 1952, E.M. Wakefield, det. M.B.
Ellis (K-M-—IMI 50643) [MUCL 3598]. BELG1um (31) Botrytis rosea Link, in foliis

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 695

Quercus robur, coll. Libert (BR) [DAOM 74693, MUCL 1806]. (32) Chromelosporium
carneum, on dead leaves of Fagus sylvatica and Quercus pedunculata in woods, Parc
d'Arenberg, Hevelee, Sept. 1 1960, G.L. Hennebert (MUCL 1218, DAOM 74698). (33)
Chromelosporium carneum, on twig of Fagus sylvatica, Parc d’Arenberg, Hevelee, Aott
21 1964, G.L. Hennebert (MUCL 6278). (34) Chromelosporium carneum, on bare
humid soil under Fagus sylvatica, in Lauzelle forest, Louvain-la-Neuve, Oct. 2017,
G.L. Hennebert (MUCL 56651).

Chromelosporiopsis coerulescens (Bonord.) Hennebert, comb. nov. _— Fics 16-18
MB 835625
= Polyactis coerulescens Bonord., in Fresenius, Beitr. Mykol. 1: 14, 1850.
= Botrytis coerulescens (Bonord.) Sacc., Syll. Fung. 4: 132, 1886.
= Chromelosporium coerulescens (Bonord.) Hennebert, Persoonia 7:197, 1873.
= Hyphelia purpureospadicea Fuckel, Jahrb. Nassauischen. Vereins Naturk. 23-24: 363, 1870.
= Botrytis purpureospadicea (Fuckel) Sacc., Syll. Fung. 4: 121, 1886.
= Botrytis epigaea subsp. rosea Sacc., Michelia 2(8): 544, 1882.
= Botrytis epigaea var. rosea (Sacc.) Sacc., Syll. Fung. 4: 136, 1886.
= Botrytis carnea var. quercina Sacc. Syll. Fung. 4: 119, 1886.

Types: C.[Chromelosporium] rhodianthinum n.sp.-[prov.name] on rotting leaves and
humic debris of Acer saccharum, Betula lutea and Tsuga canadensis in mixed woods,
Bell’s Corners, Ontario, Canada, 18.07.1961, leg. G.L. Hennebert (Neotype: DAOM
83371, designated in Hennebert 1973; Isoneotype: MUCL 2323).
COLONIES in tufts, appearing and rapidly evanescent, with <20 synnemata
arising from a basal mat of hyphae, at first white to bluish, sky-blue turning
to rose-lilac, finally vinaceous ocher at maturity in fresh conditions and
vinaceous brown when dried.

HypHAE superficial, sparse, delicate, hyaline, thin-walled, smooth,
forming mats 1-5 mm wide, 1 mm high, hyphae interwoven 11-29 um wide,
septate into 32—46 um long cells.

SYNNEMATA erect, divergent, composed of <25 hyphae, septate and
anastomosing, the central hyphae growing first <800 um high, the outermost
ones shorter, each hyphae serving as a conidiophore stipe.

CONIDIOPHORES stipes hyaline, 6—9 um wide, septate, with 36—54 um long
cells, thin-walled, smooth, all branching at the top, in successive, asymmetric
dichotomies in a coralloid pattern, forming a globose or somewhat conical
conidial head.

CONIDIOGENOUS HEAD comprising all branches of the conidiophore except
the first ones, 15—75 (mostly 30-60 um) um long, 9-12 um wide, the distal
cells clavate <15 um wide, obtuse, forming conidia almost simultaneously.

ConipiA holoblastic, on denticle 1 x 0.5 um, 4—9 um spaced, one celled,
globose, 4.2—6.6 um, most 5.4 um, walls 1 um thick, subhyaline, the outer

696 ... Hennebert

Fig. 16. Chromelosporiopsis coerulescens (neotype DAOM 83371).
A. Synnemata B. Asymmetric dichotomies or coralloid branching. C. Conidiation.
D. Finely verrucose conidia. Scale bar = 10 um.

wall finely punctate (‘minutissime asperulis, Saccardo 1886 p. 132), with
12-18 small warts in median view, seceding rhexolytically.

HABITAT: on mosses, rotten wood debris, tree leaves, conifer needles in
humid forest.

DISTRIBUTION: North America: Canada, USA, Europe: France, Belgium.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 697

Fig. 17. Chromelosporiopsis coerulescens (neotype DAOM 83371). A. Fungus mat with
emerging young synnemata. B. Top of growing synnema. C. Head of branches. D. Asymmetric
dichotomous branching. E. Conidial head.

COMMENTS—Fresenius (1852: 74), who received a specimen and a description
of the species from Bonorden, noticed that “die sporen sind rund, feinwarzig,
nicht glatt wie Bonorden angibt”. Indeed Bonorden (1851) described the spores
as “glatt”. Fresenius also illustrated the conidiogenesis of the species.

Chromelosporiopsis coerulescens differs mainly from C. carnea by the
colour when young, the synnematal development, the narrower conidiophore
hyphae, and the smaller, punctate conidia.

Bonorden (1851) described Polyactis coerulescens as “zuerst weisse, dann
hellblau, zuletzt duch die Sporen braunlich” The pale blue (hellblau) young

698 ... Hennebert

Fig. 18. Chromelosporiopsis coerulescens. A. Young blue cushions and white young synnemata.
B. Rose-lilac nearly mature synnemata (specimens collected and photographed on rotting
trunk on the ground, A. 14.06.2014, Sainte-Cécile-de-Masham, QC and B. 19.08.2018, Orleans,
Ont, Canada, by Jonathan Mack, Mycoquebec.org).

stage of the colonies changes during maturation to rose-lilac-mauve and
then vinaceous ochre-brown.

Fuckel (1870) described under Hyphelia the new species H. purpureo-
spadicea. It is here a synonym of C. coerulescens after examination of the
holotype.

Labbé (2015) describes the species as “remarquable par ses colorations
bleu cristal puis rose-violet et ressemblant presque a des cristaux en
forme daiguilles.” The species is illustrated in its change of colour in the
photographs by Jonathan Mack (Fig. 16) in J. Landry on mycoquebec.org
and in photographs by Cornell Mycology (Hodge 2017).

SPECIMENS EXAMINED

TYPE & AUTHENTIC SPECIMENS EUROPE: GERMANY (2) Hyphelia purpureospadicea
Fuckel, ad terram arenosam humidam in sylvis acerosis, raro, Autumno, circa
Budenheim, Fuckel. Fungi Rhen. Exs. 2214 (G, holotype; BR, GRO, PAV, FH, isotypes)
[DAOM 83395, MUCL 2396].

OTHER SPECIMENS. NORTH AMERICA: CaAnapa (3) Botrytis ?, on humus,
Morgan's woods, MacDonald College, near Montreal, Qué., Aug. 27 1941, R.E Cain
12979 (DAOM 80136) [MUCL 2276]. USA (4) Botrytis dichotoma, on ground and
rotting wood, Fall Creek, Ithaca, N.Y., June 18 1894, G.E Atkinson. Herb. Atkinson
1153 (CUP) [DAOM 84693, MUCL 2876]. (5) Botrytis terrestris, on humic ground
under conifers, Shelburne, New Hampshire, Sept. 1891, W.G. Farlow (FH) [DAOM
84699, MUCL 2883]. (6) Botrytis terrestris, on dead leaves, trunks, dungs, etc. in
conifer woods, Shelburne, W.G. Farlow (FH) [DAOM 84700, MUCL 2884]. (7) Botrytis
epigaea, on rotten wood and mosses, Hadley Lake, Machias, Sept. 21 1898, W.G.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 699

Farlow 36 (FH) [DAOM 84698, MUCL 2882]. (8) Botrytis epigaea Link, on mosses,
Magnolia, Mass. July, W.G. Farlow (FH, UPS, CUP) [DAOM 84912, MUCL2484].
(9) Botrytis epigaea, on Hydnum, Gerrish Island, Kittery Pt., Maine, R. Thaxter (FH)
[MUCL 2892]. (10) Botrytis (Polyactis) coerulescens (Bon.) Sacc., on bare soil in forest,
Lingle Valley, Mifflin Co., Pa., July 3 1938, L.O. Overholts 21176, D.H. Linder (FH)
[MUCL 2891]. (11) Hyphelia terrestris, on decaying leaves, Ringwoods, N.Y., Sept. 6
1952, R.E Cain (TRT 24143) [MUCL 2863]. (12) Ostracoderma, on Quercus rotten
wood, Pennsylvania state, July 4 1957, E.A. Atwell n° 5779 (DAOM 59233). (14)
Ostracoderma, on lawn, College Park, Maryland, Sept. 15 1961, A.M. Golden, C.R.
Benjamin (BPI) [MUCL 2957].

EUROPE: Beteium (15) Hyphomycete n° 517, sur sol de jardin, Rue Berchmans,
Bruxelles, June 21 1917, M. P. C. Beeli (BR). (16) Botrytis violacea/lilacina Schw, sur
argile, Forét de Soignes, Sept. 23 1933, Bommer (BR).

Species of Pezizaceae with known sexual morphs and similar synnematous
conidiophores and conidiogenesis

A similar Chromelosporiopsis asexual morphology was found in
specimens collected by Korf (1994) and identified by Healy & al. (2015)
as Pachyphlodes pfisteri Tocci & al. (Pezizaceae), and briefly described by
Hennebert (2017).

In October 2017, some samples of synnematous Chromelosporiopsis
conidial mats were collected on bare soil in forests around Louvain-la-
Neuve in Belgium. The DNA sequencing in MUCL identified three samples
as Pachyphlodes nemoralis Hobart & al., and one sample as P. citrina (Berk.
& Broome) Doweld. Their conidial morphs are clearly distinguished by the
synnematal structure and hyphal width, the hyphal length and width of the
conidiophore coralloid branches, and particularly by the conidial size and
the conidial wall ornamentation (Hennebert & Decock 2020).

Pachyphlodes nemoralis has globose conidia, 4—6.5 um wide, with 0.5 um
thick walls covered with <0.3 um high tuberculate warts (12-14 in median
view).

Pachyphlodes citrina has globose conidia, 4.5—7 um wide, with 0.5 um
thick walls covered with <0.8 um high baculate warts (12-14 in median
view).

3. Doubtful and excluded taxa

Most synnematous Chromemosporium-like herbarium specimens
examined were labeled as Botrytis epigaea, Polyactis epigaea, Hyphelia
terrestris, or Phymatotrichum, among others. These names are considered
below.

700 ... Hennebert

Botrytis epigaea Link, Spec. Plant., ed. 4, 6(1): 52, 1824.
= Polyactis epigaea (Link) Bonord., Handb. Mykol.: 115, 1851.
= Phymatotrichum epigaeum (Link) Vasyag., in Shvartsman &
al., Flora Sporov.. Rast. Kazakhst. 8: 263, 1973.

No authentic material of Botrytis epigaea or Polyactis epigaea was retrieved
from relevant herbaria. Link (1824) originally described Botrytis epigaea as:
“Botrytis epigaea, thallo effuso, floccis sporodiferis subramosis brevibus,
sporidiis globosis minutis. Habitat in terra humida sylvarum Germaniae.
Lecta Berolini im Thiergarten (Lk.) (v.v.)” This nine-word description being
applicable to a number of fungi, the name is doubtful in absence of authentic
specimen. Fries (1832a,b) did not accept the species in Sporotrichum because
he considered it as only mycelium.

Bonorden (1851) interpreted Link’s species under Polyactis epigaea in his
Fig. 161 as a fungus showing bifurcate conidiophores covered with conidia,
adding that the colour of the mature mass of spores is gray or greyish yellow
(“grauen oder graugelben Pulver”). This might suggest a Chromelosporium-like
species, but no authentic material is extant.

The earliest specimen received as Botrytis epigaea was collected by Fuckel in
1861. This synnematous Chromelosporium-like fungus with punctate conidia
does not possess enough for identification.

Saccardo (1886) considered Botrytis epigaea similar to Hyphelia terrestris
sensu auct.

Phymatotrichum Bonord., Handb. Mykol.: 116 (1851).

Bonorden, who defined his genus with conidiophores branched tree
or shrub-like, not umbellate, bearing on their distal swollen branches
pecidellate conidia (“gestielte Sporen”), described three species:
P. gemellum, P. pyramidale, and P. laneum (Fie. 19).

While P pyramidale Bonord. was transferred to Botryosporium,
Saccardo interpreted P laneum as Botrytis laneus (Bonord.) Sacc. and
P. gemellum as B. gemella (Bonord.) Sacc.; Hennebert (1973), who
interpreted P gemellum as Botrytis cinerea Pers., deduced that
Phymatotrichum was a synonym of Botrytis.

But none of the researchers considered the pedicellate conidia (“gestielte
Sporen”) mentioned by Bonorden as a diagnostic generic criterion, which
is neither a character of Botrytis nor of Phymatotrichopsis (Fic. 20).
Phymatotrichum gemellum is described with some fasciculate superficial
hyphae (“verbundenen hypha”) bearing short tufts ending in unequal

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 70.1

182

138

000
00

Fhymatotrichum gemellurm Frymatotrichum pyramidale

Fiymato trichum laneum

Fig. 19. Copy of the Bonordens illustrations of the species of Phymatotrichum.

bifurcate apical swollen fertile cells (“Endaste erweitern zich zu zwei
ungleich grossen Basidien”), characters that possibly suggest species of
Chromelosporiopsis. But Bonorden commented that the species possessed
characters of both Polyactis and Botrytis, but absent any authentic material,
the genus remains doubtful.

Fig. 20. Conidiogenesis of Phymatotrichopsis omnivora (Shear) Hennebert from dried sporemat
on soil in cotton field, Paris, Texas, Sept. 18, 1915, BMD, received from Missouri Bot. Garden
June 1916 (FH) [MUCL 2868] (Marek et al. 2009).

702 ... Hennebert

Phymatotrichum silvicola Taubenh. & G.M. Watkins,
Amer. J. Bot. 24: 390, 1937 [as “silvicolum”].

SPECIMENS EXAMINED: (1) Phymatotrichum silvicolum Taubenhaus and Watkins, on post

oak wood on sandy soil near Bryan, Brazos Co, Texas, November 1936 (NY) [DAOM

84656, MUCL 2690]. (2) Phymatotrichum silvicolum Taubenhaus and Watkins, on post

oak wood on sandy soil near Bryan, Brazos Co, Texas, Sept.8, 1937 (BPI) [DAOM 84657,

MUCL 2691].
Two authentic specimens of Phymatotrichum silvicola were received. The
fungus is described from Texas on sandy soil in forest, as “hyphal mats
more or less circular, 0.5-4 cm wide, white becoming greyish yellow, with
synnemata of conidiophores arising from them, with bifurcate branching,
the apical branches clavate, 5-8 um wide and covered with subglobose one-
celled conidia 2-4.6 um wide on denticles”. The specimens are ambiguous,
containing globose (3.5-5.2 um) punctate conidia mixed with napiform to
globose (6.5-8.7 um) verrucose conidia.

Rhinotrichum thwaitesii Berk. & Broome, Ann. Mag. Nat. Hist., ser. 2, 7: 177, 1851.
SPECIMEN: Rhinotrichum thwaitesii Berk. & Broome, Clifton, Berkeley. Herb. Berk. (K-
M), holotype, with included watercolour plate by Berkeley [MUCL 2952].
The specimen contains conidiophores branched in dichotomies bearing
globose conidia on denticules with very verrucose walls, but no synnemata
have been seen. Rhinotrichum thwaitesii remains a doutful species in view of the
discrepancies between the fungus and Berkeley's accompanying watercolour
plate and the published diagnosis of the name with ovoid and larger spores.

Isaria thyrsoidea Penz. & Sacc., Malpighia 15: 251, 1902.

Isaria thyrsoidea, found on rotting leaves,
insects and dung, in Tjibodas, Java, 1897, is : ; |
described as white tufts of erect cylindrical |. \ is alt ZG .- BE
synnemata 1.5 mm high, 40-50 um wide, made rAd
of septate hyphae that emerge laterally and
apically from the upper half of the synnemata

SN

as bi- and tri-furcated conidiogenous branches,

saat ae

5.5—6 um wide, sparsely septate and covered
on denticle (“subsessile”) with smooth globose
conidia 3.5-4 um wide (Fic. 21), The fungus
is turns ash-grey at maturity. Are the conidia

really smooth? Despite the colour of the Fig. 21. Isaria thyrsoidea Penzig &
Sacc., Malpighia 15: 251, 1902

SS
H)
ee

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 703

fungus and the smooth conidia, the description suggests a Chromelosporiopsis
species. The original material needs to be located and re-studied.

Chromelosporium terrestre (Fr.) M.B. Ellis, More Demat. Hyphom.: 154, 1976.
= Hyphelia terrestris Fr., Syst. Mycol. 3(1): 213, 1829, nom. sanct.

Ellis (1976) proposed the combination Chromelosporium terrestre for
the basionym H. terrestris in order to correct the then illegitimate name
Chromelosporium tuberculatum (Hennebert 1973). But Hyphelia terrestris
is not a Chromelosporium-like species as shown below. The fungus
described and illustrated by Ellis under that name is an unidentified species
of Chromelosporiopsis and belongs to the set of collections considered
hereunder.

Unidentified herbarium material with features of Chromelosporiopsis

Beside the presence of synnemata, a generic character, the specific
microscopic characters of Chromelosporiopsis (observed when possible in the
following material) are the hyphal widths (diameters), the branching patterns,
the condial size, and the ornamentation of the conidial wall. The conidial
wall ornamentation serves as an important criterion distinguishing between
asexual morphs of Pachyphlodes species (Hennebert & Decock 2020) and is
used here as a basis for a preliminary grouping of the specimens. But a good
characterization of the wall ornamentation requires high quality equipment
without which the present groups are based only on the number of warts
visible on median view of the conidia and not on the wall morphologies. The
specimens are classified according to the conidial wall surfaces ranging from
punctate to coarsely warty. To be diagnostic, the number of median warts
must be combined with wart morphology.

SPECIMENS EXAMINED
CONIDIA PUNCTATE (218 WARTS, MEDIAN VIEW)

AUTHENTIC SPECIMEN EUROPE: (3) Trichoderma laeve ? Pers., frequens in
sylvulis prope Parisios [scr. Pers.] Herb. Pers. (L 910.267.31) The fungus is immature
and fragmentary. [DAOM 83899, MUCL 2461].

OTHER SPECIMENS. EUROPE: GERMANY (4) Botrytis epigaea Link, Polyactis
epigaea Bon., Giesen, Oct. 22.1861, Herb. Fuckel in herb. Barbey-Boissier (G 005439)
MUCL 2400)]. (5) Botrytis epigaea Link, ad terram Bavaria, Killermann. Herb.
Bresadola (BPI) [DAOM 83891, MUCL 2428]. SWEDEN (6) Hyphelia terrestris, ad
terram nudam, Stollsbachen, Uppsala, Aug. 7 1932, Seth Lundell. Flora Suecica (UPS)
[DAOM 83921, MUCL 2494]. (7) Hyphelia terrestris, at the lower course of the rivulet
Skytebacken, Halsungland, Farila parish, Skyte, Aug. 2 1956, J.A. Nannfeldt. Flora
Suecica 14770 (UPS) [DAOM83905, MUCL 2770]. (8) Hyphelia terrestris, Zogenern
Wald, b. Liindensitz, Aug. 1844 (PR 181907) [DAOM 84707, MUCL 2907]. UK (9)

704 ... Hennebert

Ostracoderma, on wet soil, Wotten under Edge, Gloucestershire, Aug. 1961, R.W.G.
Dennis (K-M-IMI 89255) [DAOM 83951, MUCL 2541]. (10) Botrytis splendida
Schw., on soil, Skircoat Green, Halifax, Yorkshire, Nov. 1955, R.Watling, det. M.B.Ellis
(K(-M-IMI 61440) [MUCL 3524]. FINLAND (11) Hyphelia terrestris = Botrytis epigaea
Link var. rosea Sacc. on soil, Mustiala, Aug. 25 1869, P.A. Karsten, W Nylanders,
Herb. P.A. Karsten (H) [DAOM 83903, MUCL 2470]. (12) Hyphelia terrestris, supra
terram, Mustiala, Aug. 1865, P.A.Karsten. Flora Fennica (UPS) [DAOM 83913,
MUCL 2485]. NETHERLANDS (13) Ostracoderma (? Tomentella granulata Bref.), op
naakte bodem in loofbos lenig humensegrond, Ulvenhout, Ulvenhoutse bos, Sept. 29
1959, R.A. Maas Geesteranus 13006 (L) [DAOM 83935, MUCL 2513]. PoRTUGAL
(14) Botrytis carnea Schum., ad terram, Portugal, Torrend 21, Herb. Bresadola (S)
[DAOM 83946, MUCL 2528]. BELGruM (15) Hyphelia, on bare soil, Forét de Soignes,
Tervueren, Aug. 16 1960, G.L. Hennebert (MUCL 1214) [DAOM 83904]. DENMARK
(16) Ostracoderma, ad terram in sylva faginea, Sjaelland, Sonnerup sogn., Ovdrup
skov, Sept. 13 1952, Mykologisk Kongres, J.A. Nannfeldt. Flora Danica 12552 (UPS)
[DAOM 83915, MUCL 2488].

NORTH AMERICA: CANADA (17) Ostracoderma, on garden soil, in gras,
Ottawa, Oct.15 1960, V.J. (MUCL 1534). (18) Botrytis epigaea, on soil in barley field,
Glen Williams, Halton Co., Ont., Sept. 9 1956, R.F. Cain (TRT 32547) [DAOM 84686,
MUCL 2860]. USA (19) Rhinotrichum thwaitesii B. & Br., on ground in woods, south
side of Fall Creek, Ithaca, June 25 1959, G.F. Atkinson, Herb Atkinson 22860 (CUP)
[DAOM 84695, MUCL 2878]. (20) Hyphelia terrestris on ground, Nashville, York Co,
Ont. Sept. 29 1956, R.E Cain (TRT 32443) [DAOM 84685, MUCL 2859]. USA (21)
Botrytis isabellina Pr., on bark of Pinus sylvestris, Juamby Lawn, Boston, Nov. 1906,
H.C. Hawley (BM) [MUCL 2280]. (22) Hyphelia terrestris, on damp ground in woods,
Bois Mallet, West La. May 23 1886, A.B. Langlois 412 (BPI) [DAOM 83892, MUCL
2429]. (23) Hyphelia terrestris, on sandy soil in field, Nashville, York. Co. Ont. Oct. 9
1955, R.E Cain, Herb. RFC 31601 (WU) [MUCL 2408]. (24) Botrytis epigaea Link,
on moist humus and soil, Altamonte, Florida, Aug. 1 1957, P.O. Schalbert, P.L. Lentz
(BPI) [MUCL 2960].

AUSTRALASIA: AusTRALIA (25) Phymatotrichum, on dead leaves, twigs and
woody fruits, Brisbane, Australia, June 1951, R.E Langdon 817 (K-M-IMI 54841)
[MUCL 3504]. NEw ZEALAND (26) Botrytis terrestris, snow white patch on soil, New
Zealand, W. Odenso. Herb. J.B. Ellis (NY) [DAOM 84680, MUCL 2851].

CONIDIA VERRUCOSE (12-16 WARTS, MEDIAN VIEW)

EUROPE: Austria (1) Hyphelia terrestris var. flava, ad terram humidam in
dumestis, non raro, Autumno, Oestrich, Fuckel. Fuckel Fungi Rhen. Exs. Supp.
1641 (Symb. Mycol.: 363 1869) (G, GRO, BM, FH) [DAOM 83327, MUCL 2258].
Irauy: (2) Botrytis epigaea Link. Padova, ad terram udam umbrosam, December.
1874. Saccardo P.A. Mycotheca veneta [Cent. IV, 1876] 360. [MUCL 2283] (3)
Botrytis epigaea Link, a) ad terram nudam in Horto Botanica Ticinensi, b) ad terram
herbosam sub cupuliferis, ibidem. Ipse lege. Autumno. Forma b rubella ad var.
roseam Sacc. ferendo mihi videtur, quamvis conidia paulum majora sint. Cavara F.
Fungi Longobard. Exs. 145 (B, K-M, S, L 910.224-184) [DAOM 83335, MUCL 1805
= 2285]. (3) (4) Botrytis epigaea Link, ad terram, Florentiae, June 1891, N. Martely,
Herb. Bresadola (S) [DAOM 83939, MUCL 2516]. GERMANY (5) Hyphelia terrestris
ad vias nemorum, Grossen Garten, prope Dresden. Rabenh. Klotzschii Herb. Viv.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 705

Mycol. I, 1846 (PR, PAV, BR) [DAOM 83895, MUCL 2432]. (6) Hyphelia terrestris,
in parnecio Tyrois, Aug. 29 1859, PA. Karsten (H) [DAOM 83902, MUCL 2469].
SWEDEN (7) Hyphelia pulvinata (Fr.) Juel, pa sandjord utmed en vag I baarskog,
Uppland, Uppsala, Stadsparken nara Norby, Oct. 1933, Seth Lundell. Flora Suecica
1068 (UPS) [DAOM 83910, MUCL 2482]. (8) Hyphelia pulvinata (Fr.) Juel, pa
naken jord I vagkant, Upplannd, Estuna, Ljushammaren, Malmé, Sept. 27 1955,
Seth Lundell. Fungi Suecici (UP) [DAOM 83917, MUCL 2490]. (9) sine nomine, auf
nackter Erde, in Park, Uppland, par. Solna, Aug. 1906, L. Romell, Herb. Mykol. Lars.
Romell 17715 (S) [DAOM 83944, MUCL 2523]. (10) Polyactis epigaea (Link) Bon,
?Hyphelia, auf nackter Erde auf einen Pfaden Upl. Stockholm: Ekbacken, Jul. 22 1894,
L. Romell. Herb. L Romell (S) [DAOM 83945, MUCL 2526]. NETHERLANDS (11)
Ostracoderma, op de gronde in loofbos, Ulvenhout, Ulvenhouter bos, Oct. 6 1959,
R.A. Maasgesteranus 13025 (L) [DAOM 83936, MUCL 2514]. FRANCE: (12) Hyphelia
terrestris, in umbrosis viis, Montmorency, St Germain, Fontainebleau Sept. 1842-
1848, Roussel, Herb. E Roussel (PC) [DAOM 84661, MUCL 2703]. BELGrum (13)
Chromelosporium, sur le sol dun chemin en forét, Bois de Hevelee, Heverlee, Brab.,
G.L. Hennebert (MUCL 6701). (14) Hyphelia?, sur soil humide, au bord dun chemin
ombragé, Forét de Soignes, Groenendael, Aug. 16 1960, G.L.H. (MUCL 1205, DAOM
74900).

NORTH AMERICA: CANADA: ONTARIO (15) Ostracoderma, Bells Corners,
Ont. Sept. 10 1961, G.L. Hennebert (DAOM 83922, MUCL 2496). USA: VIRGINIA
(16) Botrytis epigaea Lk. var. rosea Sacc., on dead leaves, Limberlost, Shenandoah
National Park, Va., Sept. 9 1937, J.A. Stevenson and V.K. Charles (BPI) [MUCL 2409].
(17) Botrytis epigaea Link, on soil under leaves, Arlington cementary, Virginia, May
22 1932, C.L. Shear (BPI) [DAOM 83870, MUCL 2427]. CONNECTICUT (18) Botrytis
fulva Link, near B. epigaea, on soil and grass, New Haven, Conn. July 6 1889, R.
Thaxter, Herb. Atkinson (CUP) [DAOM 84696, MUCL 2879]. MASSACHUSETTS (19)
Botrytis spectabilis, on rotten wood, Prospect Hill, Waltham, Oct. 1901, WG. Farlow
(FH) [DAOM 84701, MUCL 2885]. (20) Botrytis epigaea, near Hyphelia terrestris, on
rotten wood in humic litter, Bedford, Mass., Sept. 1901, W.G. Farlow (FH) [DAOM
84697, MUCL 2881]. NEw Mexico (21) Rhinotrichum roseum, on buried dead
leaves, Chirlehunt, Sept. 1854. Herb. Currey (K-M) [MUCL 2300].

CONIDIA VERY VERRUCOSE (6-12 WARTS, MEDIAN VIEW)

EUROPE: SwEDEN (2) Hyphelia terrestris, on soil, Kronoparken, Uppsala,
Uppland, Aug. 1916, H.O. Juel. Flora Suecica (UPS) [DAOM 83911, MUCL 2483].
(3) Hyphelia pulvinata (Fr.) Juel, pa naken jord I strandsnaret, Upland, Naturpark
Bondkyrka , Vardsiatra, Jul. 18 1930, Set Lundell. Flora Suecica 0798 (UPS) [DAOM
83909, MUCL 2481]. (4) Hyphelia, ad terram nudam sub Corylus, dland, Persmas
parish, Legends, Aug. 3 1953, J.A. Nannfeldt. Flora Suecica 13327 (UPS) [DAOM
83906, MUCL 2477]. DENMARK (5) Ostracoderma, ad terrram in fageto, Sjealland,
Hvaloo skov, Sept. 14 1952, Mykologisk Kongress, J.A. Nannfeldt. Flora Danica 12603
(UPS) [DAOM 83919, MUCL 2492]. UK (6) Ostracoderma pulvinatum Fr. Sibbertoft,
1873, Berkeley, Herb. Berk (K-M) (conidia with prominent blunt warts, drawn by
Berk.) [MUCL 3497]. (7) Phymatotrichum, on burn ground and wood, Ashridge,
Herts., England, Oct. 9 1955, D.A. Reid (K-M) [MUCL 2303]. Germany (8) Botrytis
epigaea Link., ad terram humidam, non frequens. Aestate. circa Schlangenbad. L.
Fuckel. Fuckel Fungi Rhen. Exs. 2301, 1871 (G, K-M, B, K, GRO) [MUCL 2282].

706 ... Hennebert

FRANCE (9) Hyphelia terrestris, ad vias in sylvis Fontainebleau, Aug. 4 1869, Roussel,
Herb. E. Russel (PC) [DAOM 84662, MUCL 2704]. BELG1um (10) Chromelosporium,
sur le sol en forét, Bois de Bonsecours, Blaton, Hainaut, G.L. Hennebert (MUCL
6332).

CONIDIA SMALL, COARSELY VERRUCOSE (4 —6 WARTS, MEDIAN VIEW)

EUROPE. SweEpDEN (1) Hyphelia, on bare soil under stormfelled spruce,
Gastrikland, Hills in Tolfforskogen, near Tolffors, Aug. 15 1954, J.A. Nannfeldt. Flora
Suecica 11065a (UPS) [DAOM 83908, MUCL 2480].

NORTH AMERICA: CANADA: QUEBEC (2) Botrytis?, on humus, Morgan’s
woods, MacDonald College, near Montreal, Qué. Aug. 27 1941, R.E Cain 12979
(DAOM 80136) [MUCL 2276]. USA: NEw York (3) Phymatotrichum, on soil, Lloyd
Cornell Preserve, Slatterville, NY, Sept. 6 1952, W.W. Diehl (BPI) [DAOM 83889,
MUCL 2426].

Re-evaluation of Hyphelia terrestris

Identification of the majority of the examined herbarium specimens
found to be synnematous Chromelosporium-like species as Hyphelia
terrestris is based only on the short macroscopical description and habitat
information by Fries (1829): “effuse, strigoso-tomentosa, candida, medio
evanescens, sporidiis subargillaceis ... in terra humosa, umbrosa, humida
and denudata” and ignores Fries’s synonymy.

‘The signed and dated specimens among the specimens examined show
that this interpretation was accepted as early as in 1842 by Roussel, 1846 by
Rabenhorst, 1861 by Fuckel, 1865 by Karsten, 1886 by Saccardo, 1901 by
Farlow, 1920 by Juel, and by many afterwards. Taking into account Fries’s
protologue for Hyphelia terrestris, this traditional interpretation is actually a
misapplication of the name.

Juel (1920) observed that the macroscopical description of Hyphelia
terrestris in Fries (1829) matched well the collection he made near Uppsala
in 1916 and a similar collection made in Mustiala, Finland in 1865 by
P.A. Karsten, who identified it as Hyphelia terrestris (UPS). Convinced that
the observed conidiogenesis in these specimens had to be that of Hyphelia
terrestris, Juel emended the genus Hyphelia (for the part regarding Hyphelia
terrestris) adding “rami conidiophori, apice non inflati, conidiis rotundis
brevissime pedicellatis undique tecti” to the Fries description.

Hennebert (1973) accepted Juel’s interpretation of Hyphelia terrestris
as a Chromelosporium-like species and interpreted (erroneously) Juel’s
publication as a lectotypification of Hyphelia terrestris. Actually Juel did
not typify the name from any authentic Friesian material or from the two
specimens that he cited. Hennebert named the fungus Chromelosporium

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 707

tuberculatum (Pers.) Hennebert, Trichoderma tuberculatum being the first
synonym cited by Fries but for which no type exists. As Hyphelia terrestris had
been sanctioned (Fries 1829), the name was corrected to Chromelosporium
terrestre (Fr.) M.B. Ellis.

Fries (1825) originally introduced the generic name Hyphelia for
Trichoderma roseum Pers. [= Trichothecium Link, fide Hughes 1958]. Fries
(1825) also added “Aliud genus, mucedineum, representat vulgatissimum
Trichoderma tuberculatum Pers. cui accedunt multae species novae.... Sed de
his plura in S. M. II” [a reference to the forthcoming Systema Mycologicum
3]. “Huic generi Trichodermatis nomen tribuerem, nisi T: viridi jam a Cel.
Linkio affixum, quod sancte servandum videtur.”

However, instead of creating his proposed new genus (‘aliud genus’),
Fries (1829) actually divided Hyphelia into two unranked infrageneric
parts: Thelephoroideae (for H. rosea, H. spadicea, H. fusca, and H. nigrescens)
and Hyphomycetoidea (for the new species H. terrestris, described only
macroscopically and with four synonyms).

Fries (1849) reduced his concept of Hyphelia by omitting the type,
H. rosea (Pers.) Fr. and chose section names (instead of adjectives) for the
subdivisions: Xylohypha for H. nigrescens and H. fusca; and Geohypha for
H. terrestris. The omission of the type, H. rosea, made Hyphelia Fr. 1849 an
illegitimate later homonym of Hyphelia Fr. 1825, nom. sanct. The names of
the subdivisions Geohypha Fr. and Xylohypha Fr. are legitimate and available
for elevation to generic rank.

Fries (1829) described Hyphelia terrestris only macroscopically, with four
synonyms: “Trichoderma tuberculatum Pers.; T: nemorosum Pers.; T. laeve
Schum. (dubitans ipse citat T: laeve Pers.); and T. varium Ehrenb.”

Searching for the type material of these names, I have been informed
that no authentic specimen exists for Hyphelia terrestris in UPS or S, and
no specimen of Trichoderma tuberculatum remains in L. Specimens of
Trichoderma laeve and of Trichoderma nemorosum are preserved in L. and
of T. varium in B and STR.

The examination of these authenticated specimens, one of Trichoderma
laeve, (not the one labelled “Trichoderma laeve?” by Persoon), one of
T; nemorosum, and three of T. varium revealed that they represent one
species distinguished from Chromelosporium-like species by conidiogenesis.

Persoon (1796) describes Trichoderma tuberculatum, with ash grey
conidia (“pulvere cinereo”), like the grayish conidia (“clair-cendré”) of
T. nemorosum, suggesting that T: tuberculatum was similar to T: nemorosum.

708 ... Hennebert

Persoon also described the conidia of T: laeve as yellow, as Schumacher
described his T: laeve. Ehrenberg described conidia of T: varium as variable
in colour, while Fries described them as “subargillaceis”.

The other specimen, labelled “Trichoderma laeve ?’ by Persoon, contains
pieces of young conidiogenous cells of a Chromelosporium-like fungus,
differing from his other labelled ‘Trichoderma laeve,’ thus explaining
Persoon’s question mark. Persoon’s doubt affected Fries (1829), who
wrote “dubitans ipse citat T: aeve Pers: and cited instead “T: laeve Schum.
! Saell. 2 p. 236”, a later homonym, of which Fries had seen a specimen.
This illuminates the subsequent confusion between Hyphelia terrestris
and the Chromelosporium-like fungi. This indicates also that the Friesian
concept of Hyphelia terrestris differed from its traditional interpretation as a
Chromelosporium-like fungus.

The most accurate interpretation of the nomenclature is to respect Fries’s
1829 protologue of Hyphelia terrestris (a sanctioned name) and lectotypify
the species by one synonym, of which material exists— Trichoderma varium
Ehrenb.—rather than T: tuberculatum Pers. and T: laeve Schumach., which
lack extant material.

With the generic name Hyphelia 1849 being illegitimate as a later
homonym, Hyphelia terrestris therefore has status of type species
of Geophypha Fr. which can be raised in rank to a genus. A parallel
nomenclatural interpretation was made for Hyphelia nigrescens (Pers.) Fr.,
now regarded as the type species of the genus Xylohypha (Fr.) E.W. Mason
by Deighton (1960).

Geohypha (Fr.) Hennebert, stat. nov.
MB 835628
= Hyphelia sect. Geohypha Fr., Summa Veg. Scand. 2: 447, 1849.

TYPE SPECIES: Geohypha terrestris (Fr.) Hennebert

= Hyphelia [unranked] Hyphomycetoidea Fr., Syst. Mycol. 3(1): 213, 1829, nom. sanct.
Ascomycota, ascomata unknown.

Hypuae septate, hyaline, intricate, irregular, branched.

CONIDIOPHORES short as lateral outgrowths from vegetatve hyphae
bearing one conidium or long narrow sinuous and self-ramified branch,
sparsely septate, bearing a conidium on each of the many lateral outgrowths
and terminal ends.

CONIDIOGENESIS thallic, solitary on hyphal outgrowths, secession
schizolytic.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 709

Conrpi1A one-celled, globose or subglobose, sometimes napiform, hyaline,
smooth to verrucose.
Hasitat on soil.

Geohypha terrestris (Fr.) Hennebert, comb. nov. Figs 22, 23
MB 835629
= Hyphelia terrestris Fr., Syst. Mycol. 3(1): 213, 1829, nom. sanct.
= Ostracoderma terrestre (Fr.) Nannf., Fungi. Exsicc.
Suec., Fasc. 53-54, Schedae: 40, 1959.
= Chromelosporium terrestre (Fr.) M.B. Ellis, More Demat. Hyphom.: 154, 1976.
= Trichoderma tuberculatum Pers., Ann. Bot. (Usteri) 15: 12, 1795 [as “tuberculata”].
= Chromelosporium tuberculatum (Pers.) Hennebert, Persoonia 7: 198, 1973.
= Trichoderma laeve Pers., Observ. Mycol. 1: 12, 1796.
= Trichoderma varium Ehrenb., Sylv. Mycol. Berol.: 22, 1803.
= Trichoderma nemorosum Pers.,Traité Champ. Comest.: 131, 1818.
= Botrytis ceratioides Peck, Annual Rep.New York State Mus. Nat. Hist. 35: 139, 1884.
= Sporotrichum fossarum Fautrey, Rev. Mycol. (Toulouse) 17: 71, 1893.
= Ostracoderma fossarum (Fautrey) S. Hughes, Canad. J. Bot. 36: 792, 1958.

Type: Trichoderma taeve-Pers- [laeve Pers.? scratched off] varium m. [mei] ad Berol.
in terra umbrosa humida, Thg. [Thiergarten] Berlin, 7/8 [Aug. 7] [scr. Erhenberg].
Herb. Ehrenberg (B, MBT 392413, here designated as lectotype; isolectotypes:
[DAOM 83392, DAOM 83393, MUCL 2387, MUCL 2388}).
CoLoniegs in small cushions, around 5 mm across, linked by a web-like
mycelium, greyish yellow when fresh, brown when dried.

HyPHAE narrow, irregular in diameter, 2-4 um, sometimes inflated to 6 um
before septa and constricted at septa, hyaline, thin-walled, with abundant
lateral narrower branchlets, fertile.

CONIDIOGENUS CELLS either reduced to a conical to cylindrical lateral
outgrowth of the hypha, 2-8 x 1-1.5 um or (most often) developed into a long
and narrow, sinuous, irregular, hypha, 8-50 x 1-1.5 um, possibly ramified,
producing <15-20 thallic conidia on lateral outgrowths and terminal ends.

Conrp1A thallic, solitary, borne on each hyphal outgrowth, seceding
schizolytically through a 1-1.5 um wide septum, one-celled, globose or
subglobose, 4.5-6(-6.5) um, hyaline, with a thick wall, at first smooth, soon
becoming verrucose, with 12-15 warts in median view.

HasitaT: on bare soil after rain in forest.

COMMENTS—'he type and authentic specimens of the species cited in the
nomenclator are microscopically characterized as having narrow, sinuous
conidiogenous hyphae and verrucose conidia mixed with young smooth
conidia, the relative abundance depending on maturity of the fungus.

710 ... Hennebert

Fig. 22. Geohypha terrestris. A. Trichoderma laeve (MUCL 2462) conidiogenous cell with young
conidia. B. Trichoderma varium (lectotype, MUCL 2387) with mature conidia. C. Sporotrichum
fossarum (holotype, MUCL 2486b and isotype, MUCL 2394), conidia borne either solitary on
hyphae, or numerous on tortuous conidiogenous hyphae. D. Botrytis ceratioides (holotype,
MUCL 2467) conidiogenous cell, after release of some conidia. E. Mature conidia from these
four specimens. Scale bar = 10 um.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 711

Fig. 23. A Trichoderma laeve Pers. (MUCL 2387). B. Trichoderma varium Ehrenb. (MUCL 2387)
(Photos made by J.W. Carmichael, University of Alberta Mold Herbarium in 1961).

The size of the conidia obtained from each specimen drawn in Fig. 21 are
T. laeve 4.5-5.5 (av. 5) um, T: varium 4-6 (av. 5) um, B. ceratioides 5-6(-6.8)
(av. 5.7) um, and S. fossarum 4-6.5 (av. 5) um.

In 1961, I sent slides of Trichoderma laeve and T. varium from Persoon’s
herbarium to J.W. Carmichael for comparison with Chrysosporium species.
He responded with photographs of the slides, and the opinion that the
species were not congeneric with Chrysosporium.

The type of Sporotrichum fossarum contains two packets, one wrapped in
paper contains soil in powder form ona piece of blotting paper (MUCL 2486a)
and the other, in an aluminium sheet, contains the same soil kept compact
and bearing the fungus (MUCL 2486b). The same fungus was distributed in
G. Roumeguere’s Fungi Selecti Exsiccati 6790 (MUCL 2394). The fungus has
abundant vegetative hyphae that are often inflated before the septa and, when
mature, verrucose conidia. Seeing the similarities with an Ostracoderma sp.
sensu Juel, Hughes (1958) classified the species as Ostracoderma fossarum.
Hennebert (1973) made it a synonym of Chromelosporium tuberculatum, an
opinion later reported by Stalpers (1984). Revisiting the collection, I now
assert that Sporotrichum fossarum is neither an Ostracoderma nor a
Chromelosporium species but what is identified here as Geohypha terrestris.

712 ... Hennebert

SPECIMENS EXAMINED

TYPE & AUTHENTIC SPECIMENS: EUROPE: (3) Trichoderma laeve [scr. Persoon]
Herb. Persoon (L 910.264.459) [MUCL 2462] (not L 910.264. 31, Trichoderma laeve?
as written by Persoon). (4) Trichoderma nemorosum [scr. Persoon] Herb. Persoon
(L 910.264-) [DAOM 83900, MUCL 2463]. (5) Trichoderma varium Ehbg. orig.
[on soil] [scr. Ehrenberg] Herb. Schwaegrichen [stamped]” (STR) [DAOM 83898,
MUCL 2441]. (6) “Trichoderma varium Ehrenb. [on soil, no locality, no date] [scr.
Ehrenberg] (B) (DAOM 83394, MUCL 2389). FRANCE (7). Sporotrichum fossarum
sp.n. Fautrey, sur la terre déjetée des fossés dans les bois humides. La Forét de
Clamecy. Eté 1894, Fautrey 212 (holotype) (UPS) [DAOM 83912, MUCL 2486-
a, 2486-b]. (8) Sporotrichum fossarum n. sp. Fautrey, sur la terre rejetée des fossés
dans les bois humides, été 1894. F. Fautrey (isotype). G. Roumeguere Fungi Selecti
Exsiccati 6790 (Rev. Myc. 1895, p. 71, n.49) (G, NY) [MUCL 2394]. GERMANY (9)
Botrytis epigaea Link, [var. alba] ad terram humidam, non raro, Aestate. Fuckel. Fungi
Rhenani Fasc. II, 1863, n° 147 (BX 47111, GRO, S, K, FH) [MUCL 1798]. (Jahrb.
Nassauischen Vereins. Naturk. 23: 363. 1870, p. 363 as, Hyphelia terrestris Fr. var. alba,
nom. inval.). USA: NEw york (10) Botrytis ceratioides Peck, on decaying wood of
Tsuga canadensis, Albany, June, leg. C.H. Peck. (holotype). See 35th Report p.139,
1884 (NYS) [MUCL 2467].

OTHER SPECIMENS: EUROPE: ITaty (11) Botrytis epigaea Lk. f. cinerea, ad terram
argillosam udam, Bosco Montello (Treviso), Sept. 1875. Saccardo Mycotheca Veneta
58 (K-M) [MUCL 2295]. FRANCE (12) Trichoderma nemorosum Pers. Autumno,
ad terram, St Cloud, near Paris. Herb. de Candolle (G 005431) [DAOM 83992,
MUCL 2392]. (13) Trichoderma nemorosum Pers. [on soil] Meudon, Augusto [no
year] Herbier Léveillé in Herb. de Candolle (G 005432) [DAOM 83899, MUCL
2393]. SWEDEN (14) Hyphelia, on half buried birch branches in Sphagnum cushion,
Gastrikland, NNW of Tolffors Swampy wood, Aug. 14 1950, J.A. Nannfeldt. Flora
Suecica 11057 (UPS) [MUCL 2479a]. NETHERLANDS (15) Hyphelia terrestris Fr. in
terra argillacea, Lugd. Batava, 1844, Oudemans (GRO) [MUCL 2775]. DENMARK
(16) Hyphelia terrestris Fr. on bare soil, Saelland, Tisvilde Hegn., Oct. 4 1955, J.A.
Nannfeldt. Flora Danica 14249 (UPS) [DAOM 84938a, MUCL 2495]. BELGruM (17)
Trichoderma laeve on bare soil, Lauzelle forest, Ottignies-LLN, Oct. 2017, G.L.H.
(MUCL 56656).

NORTH AMERICA: USA: NEBRASKA (18) Botrytis ceratioides Peck [on leaves
and mosses] Lincoln, 1200 ft, July 22 1890, T.A. Williams. Nebraska Flora 312
(BP) [MUCL 2423]. CANADA: ONTARIO (19) Rhinotrichum carneum Ell. & Ev. on
dead wood, Oct. 3 1896, Macoun, Ellis collection 185. (NY) [MUCL 2838]. (20)
Trichoderma laeve Pers. on soil, Queen’s University Biological Station, near Chafey’s
Lake, Ontario, July 12 1961, det. G.L. Hennebert (MUCL 2537).

Plicaria endocarpoides

Hennebert (1973) suggested that Plicaria endocarpoides could have a
Chromelosporium-like asexual morph in culture based on a strain from J.W.
Paden. The strain DAOMC 199565 produced on malt agar a conidial state
having no similarity with Chromelosporium as illustrated here.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 713

al? ae
Fig. 24. Plicaria endocarpoides (DAOMC 199565 = MUCL 57202).
Conidial morph on malt-agar.

Fig. 25. Plicaria endocarpoides (DAOMC 199565 = MUCL 57202).
A. Conidiophores and conidia on malt agar. Scale bar =10 um.

714 ... Hennebert

Plicaria endocarpoides (Berk.) Rifai, Verh. Kon. Ned. Akad. Wetensch., Afd.
Natuurk., Sect. 2, 57(3): 255, 1968. Fics 24, 25
= Peziza endocarpoides Berk., in Hooker, Fl. Nov.-Zel. 2: 199, 1855.

Myce.ivum hyaline prostrate on malt agar.

CONIDIOPHORES erect from creeping hyphae, one or pluri-celled, 10-110
um high, the basal cell enlarged, triangular, the stipe often furcate.

CONIDIOGENUS CELLS intercalary or terminal of the conidiophore,
cylindrical, fusiform, or triangular, 5-8 um wide, producing acropetal solitary
or branched chains of conidia, leaving unthickened scars at schizolytic
secession.

Conrp!1A hyaline, smooth, one-celled, some 2-3-celled, variable in shape,
from globose (3-5 um), to ovate, pyriform, or citriform (5-23 x 3-8 um),
most one celled, some septate, ramoconidia bearing one to three scars of
attachment of simple or branched chains of conidia.

SPECIMENS EXAMINED: CANADA: BritTisH CoLumBiA. Plicaria endocarpoides
(Berk.) Rifai, on burnt wood, slash and ash in coniferous forest, Lightning Lakes trail,
Manning Provincial Park, British Columbia, June 9 1985, K.N. Egger 2044 in living
culture (CCF 6892 = DAOMC 199565 = MUCL 57202).

Conclusion

In light of certain mononematous Chromelosporium asexual morphs
actually representing Peziza or Plicaria, and certain synnematous
Chromelosporiopsis asexual morphs representing Pachyphlodes, it was logical
to emphasize a morphological character to distinguish the asexual morphs of
these Pezizaceae. The chosen criterion of conidiophore fasciculation allows
segregating similar conidial fungi not known to have sexual morphs into two
genera—Chromelosporium around its mononematous type and the new genus
Chromelosporiopsis for the synnematous species. Chromelosporium includes
here five taxa with distinct morphologies. Chromelosporiopsis comprises so
far two named taxa. In addition to the excluded taxa, there remain some
doubtful taxa showing some (but insufficient) Chromelosporiopsis and a set
of unidentified species detected among the herbarium specimens that further
morphological investigation of might allow segregation into species. It is
recommended that any new fresh conidial samples be not only genetically
analysed but accurately described in their finest morphological details
(including electron microscopy) to allow characterization and identification
of these conidial fungi, many of which are likely to be asexual morphs of
some known Pezizaceae.

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 715

Examination of many herbarium specimens revealed a long history
of misapplication of the name Hyphelia terrestris, irrespective of Fries
protologue of the species. A neotype of the species designated among the
synonyms given by Fries allowed a new description of the species renamed
Geohypha terrestris.

Acknowledgments

I am thankful to my colleagues, Dr. Keith Seifert (Adjunct Professor, Carleton
University, Ottawa and formerly of Ottawa Research and Development Center,
Agriculture and Agri-Food Canada) and Dr. David L. Hawksworth (Royal Botanic
Gardens Kew), who thoroughly and accurately revised the manuscript in agreement
with the present rules of nomenclature. I thank Dr Scott Redhead (Curator, National
Mycological Herbarium (DAOM), Agriculture and Agri-Food Canada) for his
appreciated nomenclatural advice and Dr Konstanze Bensch, (MycoBank curator,
Westerdijk Fungal Biodiversity Institute, Utrecht) for the registration of names
and types in MycoBank and her meticulous revision of all name citations. I thank
Dr M. Scherrenberg and Dr J. Nuytinck of Naturalis Biodiversity Center in Leiden for
the photographs and examination of the precious Persoon’s material of Isaria carnea
and Mr Jonathan Mack from Quebec for the photographs of Chromelosporium
coerulescens I thank also Dr Shaun Pennycook and Dr Lorelei Norvell, editors of
Mycotaxon, for editing the paper through very friendly exchanges. Also I remain
grateful to the late Dr R.P. Korf of Cornell University, Ithaca, for his profound
friendship and the multiple scientific exchanges and support for this research,
particularly during 1973.

A personal note of gratitude to late Dr. Stanley J. Hughes

I am overall deeply grateful to late Dr. Stanley J. Hughes, a great mycologist, who
was a great teacher and a loyal friend. After sending him some pages of my doctoral
thesis on the genus Botrytis, inspired by some of his major publications, I received
an invitation to apply for a National Research Council of Canada postdoctoral
fellowship in the Mycology Section of the then Plant Research Institute of the
Department of Agriculture Canada, in Ottawa, from October 1960.

My wife Lidwina and I arrived in Canada at the end of September 1960 and were
received by Stanley and Lyndell Hughes. Once we were settled in the apartment they
had carefully prepared for us, Stan introduced us to his colleagues of the Mycology
Section in the Neatby Building at the Central Experimental Farm. The following
day, Stan immediately began my training with a collecting trip to Gatineau Park
near Ottawa (Fig. 26).

In the laboratory, showing great patience and efficiency with the student I then
was (speaking only a few words of English accented French), Stan tested my skills
with a simple project, describing Balanium from the DAOM herbarium. Then
followed the description of Arachnophora fagicola, a new genus and species collected

716 ... Hennebert

in Belgium. As many as seven times, he asked me to improve the manuscripts I
submitted to him, each word having to be useful and necessary.

To introduce me to ancient mycological literature, Stan asked me to clarify the
complex history of Oedemium didymum. To describe the apothecial stage of certain
Botrytis species reported in my doctoral thesis, Dr. J.W. Groves, in charge of the
Mycology Section, with Dr. Elliot, introduced me to the in vitro production of the
apothecia of Botrytis from living strains.

During the second year of the award, Stan (Fic. 27A) urged me to develop my
research on the Botrytis-like fungi begun in my PhD thesis and which he classified
in Ostracoderma. In 1973, incited by Dr Korf to publish, I revised some Botrytis-
like genera and renamed Ostracoderma species in Chromelosporium (also described

and illustrated in the present paper).

Chromelosporiopsis gen. nov. & Geohypha stat. nov. ... 717

Those two years of mycological training with Dr. Hughes and Dr. Groves not
only were essential to my career, but also provided the opportunity for creating an
indestructible bond of respect and friendship. Later, Stan Hughes did to me the
honour of visiting my laboratory at the UCL in Herverlee-Leuven in May 1973
(Fic. 27B) and in Louvain-la-Neuve in June 1994 (Fic. 27C) at the celebration
of the Centenary of the MUCL fungus collection (Hennebert 2010). I remain
very grateful to the late Stanley J. Hughes for the quality of my training and his
friendship.

Literature cited

Bonorden HE. 1851. Handbuch der allgemeinen Mykologie als Anleitung zum Studium
derselben. Stuttgart.

Corda ACJ. 1837. Icones Fungorum hucusque cognitorum, Part 1, Prague.

Ellis MB. 1976. More dematiaceous Hyphomycetes. Kew, Commonwealth Agricultural
Bureau.

Fresenius G. 1852. Beitrage zur Mykologie, Heft 2: 39-89. Frankfurt.
https://doi.org/10.5962/bh1 title.51534

Fries EM. 1825. Systema Orbis vegetabilium, I. Plantae hormonemae. Lund.

Fries EM. 1829. Systema mycologicum, Vol. 3(1). Gryphiswald.

Fries EM. 1832a. Systema mycologicum, Vol.3(2). Gryphiswald.

Fries EM. 1832b. Index alphabeticus generum, specierum et synonymorum in Eliae Fries
Systemate mycologico ejusque Supplemento ‘Elencho Fungorum’ enumeratorum.
Gryphiswald.

Fries EM.1849. Summa vegetabilium Scandinaviae. Vol. 2, Stockholm.

Fuckel L. 1870. Symbolae mycologicae. Jahrbiicher des Nassauischen Vereins fiir Naturkunde
23-24. 459 p.

Healy RA, Hobart C, Tocci GE, Bonar L, Merenyi Z, Paz Conde A, Smith ME. 2015. Fun with
the discomycetes: revisiting collections of Korf’s anamorphic Pezizales and Thaxter’s New
England truffles leads to a connection between forms and the description of two new
truffle species: Pachyphlodes pfisteri and P. nemoralis. Ascomycetes.org. 7(6): 357-366.
https://ascomycete.org/Portals/0/Archives/AscomyceteOrg%2007-06%20357-366.pdf

Healy R, Pfister DH, Rossman AY, Marvanova L. 2016. Competing sexual-asexual generic
names of Pezizomycetes and recommendations for use. IMA Fungus 7: 285-288.
https://doi.org/10.5598/imafungus.2016.07.02.08

Hennebert GL. 1960. Recherches morphologiques sur le genre Botrytis Persoon. PhD thesis
— UCL, Louvain. 187 p.

Hennebert GL. 1973. Botrytis and Botrytis-like genera. Persoonia 7(2): 183-204.

Hennebert GL. 2017. Glischroderma Fuckel. Mycotaxon 132: 745-757.
https://doi.org/10.5248/132.745

Hennebert GL. 2010. The 100 years of the Fungus Collection MUCL 1894-1994. Fungal
taxonomy and tropical mycology, Quo vadis? Taxonomy and nomenclature of the fungi.
Louvain-la-Neuve. https://doi.org/10.5248/2010mucl.pdf

Hennebert GL, Decock C. 2020. A comparison of anamorphs of some Pachyphlodes species
and the type of Chromelosporium: Are they congeneric? Mycotaxon 135(1): 167-182.
https://doi.org/10.5248/135.167

718 ... Hennebert

Hennebert GL, Korf RP. 1975. The peat mould, Chromelosporium ollare, conidial state
of Peziza ostracoderma, and its misapplied names, Botrytis crystallina, Botrytis
spectabilis, Ostracoderma epigaeum and Peziza atrovinosa. Mycologia 67(2): 214-240.
https://doi.org/10.2307/3758415

Hodge K. 2017. Chromelosporium coerulescens, photos. /blog-mycology.cornell.edu. Also
www.facebook.com/pg/CornellFungi/photos/?tab=album&album_id=1637053939892411/

Hughes SJ. 1958. Revisiones Hyphomycetum aliquot cum appendice de nominibus rejiciendis.
Canadian Journal of Botany 36: 727-836. https://doi.org/10.1139/b58-067

Jaklitsch W, Baral HO, Liicking R, Lumsch HT. 2016. Syllabus of Plant Families. Adolf
Engler’s Syllabus der Pflanzenfamilies. 13th ed. Part 1(2) Ascomycota. Borntraeger Science
Publishers, Stuttgart. https://doi-org/10.13158/heia.29.1.2016.207

Juel HO. 1920. Uber Hyphelia und Ostracoderma, zwei von Fries aufgestellte Pilzgattungen.
Svensk Botanisk Tidskrift 14: 212-222.

Kirk PM, Cannon P, Minter D, Stalpers J. 2008. Ainsworth and Bisby’s dictionary of the Fungi,
10th ed. CABI, Wallingford. https://doi.org/10.1079/9780851998268.0000

Korf RP. 1994. Fifty years of fun with the discomycetes and what’s left to do. Opening lecture
of the First Whetzel-Wescott-Dimock Lectureship, Cornell Univ., Ithaca.

Labbé R. 2015. Chromelosporium coerulescens, taxon IUMQ254. /mycoquebec.org/

Persoon CH. 1795. Observationes mycologicae. Annalen der Botanik (Usteri) 15: 1-39.

Persoon CH. 1796. Observationes mycologicae, pars prima. Leipzig. 116 p.

Preuss CGT. 1853. Uebersicht unterzuchter Pilze, bezonders aus der Umbegend von
Hoyerswerda, Linnaea 26: 705-725.

Saccardo PA. 1881. Fungi italici autographice delineati, tab. 641-1120. Padova.

Saccardo PA. 1886. Sylloge hyphomycetum. Sylloge Fungorum 4. Padova. 807 p.

Saccardo PA. 1877. Fungi veneti novi vel critici. Ser. VI. Michelia 1: 1-72.

Schweinitz LD von. 1832. Synopsis fungorum in America boreali media degentium.
Transactions of the American Philosophical Society, ns 4: 141-316.
https://doi.org/10.2307/1004834

Seifert K, Morgan-Jones G, Gams W, Kendrick B. 2012. The genera of hyphomycetes. CBS
Biodiversity Series 9. 997 p.

Stalpers JA. 1984. A revision of the genus Sporotrichum. Studies in Mycology 24. 105 p.

Sumstine DR. 1911. Studies in North American hyphomycetes—I. The genera Rhinotrichum
and Olpitrichum. Mycologia 3: 45-56. https://doi.org/10.1080/00275514.1911.12017662

Wijayawardene NN, Hyde KD, Al-Ani LKT, Tedersoo L, Haelewaters D, Rajeshkumar KC,
Zhao RL, Aptroot A, & al. 2020. Outline of Fungi and fungus-like taxa. Mycosphere 11(1):
1060-1456. https://doi.org/10.5943/mycosphere/11/1/8

Hymenochaete longisterigmata sp. nov.
(Kaur, Singh, Dhingra,— PLATE eae 633)
NAVPREET KAvr, artist