Cherdchai Phosri1, Roy Watling2, Nuttika Suwannasai3, Andrew Wilson4, María P Martín5. 1. Department of Biology, Faculty of Science, Nakhon Phanom University, Nakhon Phanom, Thailand. 2. Caledonian Mycological Enterprises, Edinburgh, Scotland, United Kingdom. 3. Department of Biology, Faculty of Science, Srinakharinwirot University, Bangkok, Thailand. 4. Department of Botany and Plant Pathology, Purdue University, West Lafayette, Indiana, United States of America. 5. Departamento de Micología, Real Jardín Botánico, RJB-CSIC, Madrid, Spain.
Abstract
Phu Khieo Wildlife Sanctuary (PKWS) is a major hotspot of biological diversity in Thailand but its fungal diversity has not been thouroughly explored. A two-year macrofungal study of this remote locality has resulted in the recognition of a new species of a star-shaped gasteroid fungus in the genus Astraeus. This fungus has been identified based on a morphological approach and the molecular study of five loci (LSU nrDNA, 5.8S nrDNA, RPB1, RPB2 and EF1-a). Multigene phylogenetic analysis of this new species places it basal relative to other Astraeus, providing additional evidence for the SE Asian origin of the genus. The fungus is named in honour of Her Majesty Princess Sirindhorn on the occasion the 84th birthday of her father, who have both been supportive of natural heritage studies in Thailand.
Phu Khieo Wildlife Sanctuary (PKWS) is a major hotspot of biological diversity in Thailand but its fungal diversity has not been thouroughly explored. A two-year macrofungal study of this remote locality has resulted in the recognition of a new species of a star-shaped gasteroid fungus in the genus Astraeus. This fungus has been identified based on a morphological approach and the molecular study of five loci (LSU nrDNA, 5.8S nrDNA, RPB1, RPB2 and EF1-a). Multigene phylogenetic analysis of this new species places it basal relative to other Astraeus, providing additional evidence for the SE Asian origin of the genus. The fungus is named in honour of Her Majesty Princess Sirindhorn on the occasion the 84th birthday of her father, who have both been supportive of natural heritage studies in Thailand.
Tropical rain forests are important terrestrial ecosystems. They harbour tremendous biodiversity and several of them are recongized as biodiversity hotspots [1]. Most of the attention paid to this biodiversity has focused on the fauna and flora at the expense of less charasmatic organisms such as fungi. In 1991, Hawksworth [2] has estimated that the number of fungi worldwide ultimately will be around 1.5 million species with fungal diversity considered to be highest in the tropical forests. More recently the estimated number of fungal species has been estimated anywhere between 3.5–5.1 million species [3]. According to Hibbett et al. [4] the overall rate of fungal species discovered worldwide has been fairly level for the last 10 years with a range of 1000–1200 new species reported per year, in both Basidiomycota and Ascomycota but mainly in the latter. Herein a new basidiomycete is added.The current project is part of an effort to document the diversity of EM fungi associated with a broad range of host plants at a variety of spatial scales in Phu Khieo Wildlife Sanctuary (abbrev.: PKWS) of northeastern Thailand. This project was lead by a team of biologists from Nakhon Phanom University (NPU), in collaboration with Pibulsongkram Rajabhat University (PSRU), Srinakharinwirot University (SWU), Chulalongkorn University (CU), Real Jardín Botánico (RJB-CSIC, Madrid, Spain) and Caledonian Mycological Enterprises (Scotland, UK). The PKWS is a tropical region with a relatively high concentration of ectomycorrhizal associations. It is located in Chaiyaphum province, consisting of a complex of eigth contiguous protected areas in the western part of NE Thailand, and covers and area of 4,594 square kilometers. The western Isan forest complex is the only sizeable expanse of closed forest remaining in the region. It is unique in that it is able to sustain viable populations of wildlife species requiring large home ranges (e.g. tigers and elephants) [5]. It is also important in supporting a range of IUCN Red Listed animals and birds and is essential for conserving water resources in what is otherwise a hot and dry environment [6].The scant research on fungi for the area has been partly addressed by excursions to describe the macrofungi associated with deciduous and mixed deciduous forest with pine. During the rainy season (July–September) in both 2010 and 2011, a subepigeous, gasteroid fungus was encountered exhibiting characteristics associated with the genus Astraeus Morgan (Order Boletales, clade Sclerodermatineae in [7]) and Geastrum Pers (Order Geastrales in [8]) (Fig. 1). The goal of this study is to identify the phylogenetic placement of this fungus using sequences of LSU nrDNA, 5.8S nrDNA, RPB1, RPB2 and EF1-a, as well as compare its morphology to that of other species of star-shaped gasteroid fungi.
Figure 1
Astraeus sirindhorniae from the field.
(A) immature basidiomes with basal rhizomorphs (arrowhead), bar = 17 mm. (B) mature basidiome split to form a series of rays revealing an endoperidium with an apical opening (arrowhead), bar = 24 mm. (C) basidiospores shooting from an opening apical (in blue circle), bar = 25 mm.
Astraeus sirindhorniae from the field.
(A) immature basidiomes with basal rhizomorphs (arrowhead), bar = 17 mm. (B) mature basidiome split to form a series of rays revealing an endoperidium with an apical opening (arrowhead), bar = 24 mm. (C) basidiospores shooting from an opening apical (in blue circle), bar = 25 mm.
Materials and Methods
Fungal specimens
All necessary permits were obtained for the described field studies issued by Department of National park, wildlife & plant conservation, Bangkok, Thailand (Reference document number 0907.1/17723).Basidiomes were collected in Phu Khieo Wildlife Sanctuary, Chaiyaphum province, Thailand, during the months of July and September, 2010 and 2011. Field characters such as peridial and glebal colours (Colour identification chart, Royal Botanic Garden, E, 1969) and textures, etc. were recorded in the field and in the laboratory. Basidiospores were mounted in Melzer's reagent [9] and examined and photographed using light microscopy at magnifications of 400–1000× (DIC BX51 Olympus). Mean spore size and range was determined by measuring the diameter of at least 30 spores. Ornamentations were described and later analysed using scanning electron microscopy (SEM). For SEM, spore samples were air-dried, mounted, and sputter-coated with gold before being scanned using a JEOL JSM-840 scanning electron microscope. Peridium structure was examined under polarization microscopy (Imager A1, Zeiss). Attempts to culture the mycelium from fresh basidiomes using a modified Melin Norkrans's medium (MMN) were unsuccessful. Specimens are deposited in BBH, E and MA-Fungi.
DNA isolation, amplification and sequencing
Genomic DNA was extracted from specimens mentioned in Table 1. DNeasy Plant Mini Kit (Qiagen) was used according to the manufacturer's instructions. Five loci were amplified: a) the partial of 5′ end of nuclear ribosomal large subunit RNA gene sequences (nrLSU) with primers LR0R, LR3R, LR5, and LR7 [10]; b) the internal transcribed spacer of nuclear ribosomal DNA (ITS) with primers ITS1F and ITS4B [11]; c) the largest subunit of RNA polymerase II gene sequences (RPB1) with primers RPB1-Af (5′-GAR TGY CCD GGD CAY TTY GG-3′) and RPB1-Cr (5′-CC NGC DAT NTC RTT RTC CAT RTA-3′) [12]; d) the second largest subunit of RNA polymerase II gene sequences (RPB2) with primers RPB2-f5F (5′-GAY GAY MGW GAT CAY TTY GG-3′) [13] and RPB2-b7R (5′-GAY TGR TTR TGR TCR GGG AAV GG-3′) [14]; and e) the transcription elongation factor 1-alpha (EF1-a) with primers 983F (5′-GCY CCY GGH CAY CGT GAY TTY AT-3′) and 2218R (5′-ATG ACA CCR ACR GCR ACR GTY TG-3′) [15]. Polymerase chain reactions (PCR) contained 0.4 U Phire Hot Start II DNA Polymerase (Finnzymes, Sweden), 1× Phire Plant PCR Buffer with 1.5 mM MgCl2, 200 µM of each dNTP and 0.5 µM of each primer. The ITS amplification was run on an Eppendorf thermocycler (Eppendorf, Germany) using the following parameters: initial denaturation of 5 min at 98°C, followed by 40 cycles each with a denaturation step of 5 s at 98°C, annealing for 5 s at 57°C, an elongation step of 20 s at 72°C, and a final elongation step of 10 min at 72°C. The same conditions were used for nrLSU, RPB1, RPB2 and EF1-a amplification except that the annealing temperatures were 50°C, 55°C, 55°C and 57°C, respectively. Amplicons were purified using the QIAquick PCR Purification Kit (Qiagen) and then sequenced at the 1st BASE laboratories Sdn Bhd (Malaysia). Except for RPB2 amplicon was cloned using TA cloning kit (Invitrogen) into Escherichia coli TOP10 before sequenced. Sequences were assembled and edited with BioEdit [16]. BLASTN queries with MEGABLAST option were used to compare sequences obtained against sequences in the National Center of Biotechnology Information (NCBI) nucleotide database [17]. All new sequences have been deposited on the EMBL-EBI database and their accession numbers are presented in Table 1.
Table 1
List of specimens in this study.
Genus
Species
ID/Herbarium ID
Location/Citation
ITS
nrLSU
RPBI
RPBII
EF1-a
Astraeus
sirindhorniae
GAPK1/E30288
PKWS, Chaiyaphum
HE681772
HE68182
HE68191
KC854536
KC854542
Astraeus
sirindhorniae
GAPK2/MA-Fungi82080
PKWS, Chaiyaphum
HE681773
HE68183
HE68192
KC854538
KC854543
Astraeus
sirindhorniae
GAPK3/BBH34831
Chaing Mai
HE681774
HE68184
HE68193
KC854539
KC854544
Astraeus
sirindhorniae
GAPK4/BBH34830
PKWS, Chaiyaphum
HE681775
HE68185
HE68194
KC854541
KC854545
Astraeus
asiaticus
Arora 02-121
Thailand
EU718089
DQ644199
FJ536588
FJ536625
FJ536665
Astraeus
asiaticus
ASTRAE-44
Sri Lanka
AJ629395
Astraeus
asiaticus
ASTRAE-56
Thailand
AJ629396
Astraeus
asiaticus
ASTRAE-64
Thailand
AJ629400
Astraeus
asiaticus
ASTRAE-65
Thailand
AJ629401
Astraeus
hygrometricus
Bneil (MB 05-029)
Massachusetts USA
EU718087
DQ682996
FJ536586
FJ536623
FJ536663
Astraeus
hygrometricus
AWW220a
Massachusetts USA
FJ710187
Astraeus
hygrometricus
ASTRAE-73a
Wisconsin, USA
AJ629398
Astraeus
hygrometricus
ASTRAE-86a
Michigan, USA
AJ629403
Astraeus
hygrometricus
ASTRAE-87b
Greece
AJ629404
Astraeus
hygrometricus
ASTRAE-72b
Spain
AJ629408
Astraeus
hygrometricus
ASTRAE-74a
Wisconsin, USA
AJ629399
Astraeus
hygrometricus
ASTRAE-43
France
AJ629406
Astraeus
hygrometricus
ASTRAE-42
France
AJ629394
Astraeus
odoratus
ASTRAE-61
Thailand
AJ6298776
Astraeus
odoratus
ASTRAE-62
Thailand
AJ629877
Astraeus
pteridis
Ashy 3
Switzerland
EU718088
AF336238
FJ536587
FJ536624
FJ536664
Astraeus
pteridis
PDD88503
New Zealand
FJ710188
EU718158
Astraeus
pteridis
ASTRAE-36
Mexico
AJ629392
Astraeus
pteridis
ASTRAE-25
Wisconsin, USA
AJ629410
Astraeus
pteridis
ASTRAE-24
Wisconsin, USA
AJ629409
Astraeus
pteridis
ASTRAE-37
Spain
AJ629393
Boletinellus
merulioides
MB 02-199
Massachusetts USA
DQ200922
AY684153
DQ435803
DQ366281
DQ056287
Boletinellus
merulioides
AF336239
Boletinellus
merulioides
AY612807
Boletinellus
rompelii
No1192
EU718159
Calostoma
berkeleyi
AWW268
Malaysia
EU718090
EU718128
FJ536589
FJ536626
FJ536666
Calostoma
cinnabarinum
AWW136
Massachusetts USA
AY854064
AY645054
AY780939
AY857979
AY879117
Calostoma
Fuscum
OKM 23918
Western Australia
EU718091
EU718129
FJ536590
FJ536627
Calostoma
Fuscum
PDD70777
FJ710190
EU718161
Calostoma
insignis
Arora 98-31
Thailand
EU718092
EU718130
FJ536628
Calostoma
japonicum
TKG-SC-40701
Japan
EU718093
EU718131
FJ536591
FJ536629
Calostoma
junghuhnii
VC1151
India
EU718163
Calostoma
lutescens
1329
FJ710192
EU718164
Calostoma
orirubra
HKAS32119
China
FJ710195
EU718165
Calostoma
rodwayi
GMM 7572
New Zealand
EU718095
EU718133
FJ536631
Calostoma
sarasinii
DED7660
Malaysia
EU718096
EU718134
FJ536593
FJ536632
FJ536668
Calostoma
Sp
HKAS38133
China
EU718097
EU718135
FJ536633
Calostoma
Sp
HKAS38139
China
EU718098
EU718136
FJ536594
FJ536634
Diplocystis
wrightii
DH2002
DQ534665
Gyroporus
aff. castaneus
E4600
EU718169
Gyroporus
aff. castaneus
E843c
EU718170
Gyroporus
aff. castaneus
E4879c
FJ710208
Gyroporus
castaneus
Gc1
Germany
EU718099
AF336252
FJ536595
FJ536635
FJ536669
Gyroporus
castaneus
239-97
USA
EU718100
AF336253
FJ536596
FJ536636
FJ536670
Gyroporus
castaneus
REH8804
Thailand
EU718101
EU718137
FJ536597
FJ536637
FJ536671
Gyroporus
aff. cyanescens
REH8821
Western Australia
EU718103
EU718139
FJ536599
FJ536639
FJ536673
Gyroporus
aff. cyanescens
E486
Australia
EU718173
Gyroporus
cyanescens
MB 05-001
USA
EU718102
EU718138
FJ536598
FJ536638
FJ536672
Gyroporus
cyanescens
Gcy2
Germany
AF336254
Gyroporus
cyanescens
E8758c
Australia
EU718171
Gyroporus
aff. cyanescens
OKM23719
Western Australia
EU718104
EU718140
FJ536600
FJ536640
Gyroporus
purpurinus
PRL 3737
Illinois, USA
EU718105
EU718141
FJ536601
FJ536641
FJ536674
Gyroporus
sp.
REH8799
Thailand
EU718106
EU718142
FJ536602
FJ536642
FJ536675
Gyroporus
sp.
Arora 00-429
Zimbabwe
EU718107
EU718143
FJ536603
FJ536643
FJ536676
Gyroporus
sp.
E8155
EF561627
Gyroporus
sp.
REH8805
EU718175
Gyroporus
subalbellus
OKM25477
Texas, USA
EU718108
EU718144
FJ536604
FJ536644
FJ536677
Phlebopus
beniensis
Omon 98.015
AY612822
Phlebopus
marginatus
REH8883
Eastern Australia
EU718109
EU718145
FJ536605
FJ536645
FJ536678
Phlebopus
marginatus
MEL2145841
Australia
FJ600322
Phlebopus
portentosus
php1
Africa
EU718110
AF336260
FJ536606
FJ536646
FJ536679
Phlebopus
sp.
AY612816
Phlebopus
sp.
REH8795
Thailand
EU718111
AF336260
FJ536607
FJ536647
FJ536680
Phlebopus
sudanicus
AF336261
Pisolithus
albus
PERTH4681
Australia
FJ710202
EU718176
Pisolithus
arhizus
AF336262
Pisolithus
aurantioscabrosus
AWW297
Malaysia
EU718112
EU718146
FJ536608
FJ536648
FJ536681
Pisolithus
sp.
ECV3205
California USA
EU718113
EU718147
FJ536609
FJ536649
Pisolithus
tinctorius
AWW219
Massachusetts USA
EU718114
EU718148
FJ536610
FJ536650
FJ536682
Scleroderma
areolatum
AWW211
Massachusetts USA
EU718115
EU718149
FJ536611
FJ536651
FJ536683
Scleroderma
areolatum
PBM2208
W. Australia
EU718116
EU718150
FJ536612
FJ536652
FJ536684
Scleroderma
bermudense
BZ3961
Belize
EU718118
DQ644137
FJ536614
FJ536654
FJ536686
Scleroderma
citrinum
AWW212
Massachusetts USA
EU718119
EU718151
FJ536615
FJ536655
FJ536687
Scleroderma
citrinum
AF336266
Scleroderma
columnare
AF261533
Scleroderma
columnare
AF336273
Scleroderma
echinatum
AF336268
Scleroderma
fuscum
Trappe26575
EU718178
Scleroderma
leave
MCA242
North Carolina USA
EU718117
DQ677138
FJ536613
FJ536653
FJ536685
Scleroderma
leave
OSC27936
EU718120
DQ683003
FJ536616
Scleroderma
mcalpinei
OSC 24605
EU718122
DQ682999
FJ536657
Scleroderma
meridionale
AWW218
Massachusetts USA
EU718121
EU718152
FJ536617
FJ536656
FJ536688
Scleroderma
polyrhizum
AWW216
Massachusetts USA
EU718123
EU718153
FJ536618
FJ536658
FJ536689
Scleroderma
sinnamariense
AWW254
Malaysia
EU718124
EU718154
FJ536619
FJ536659
FJ536690
Scleroderma
sp.
HKAS43607
FJ710210
Scleroderma
sp.
Arora9917
EU718179
Scleroderma
sp.
MCA2168
EU718180
Scleroderma
sp.
MEL2295738
EU718181
Scleroderma
sp. Brown
AWW311
Malaysia
EU718126
EU718156
FJ536621
FJ536661
FJ536692
Scleroderma
sp. White
AWW260
Malaysia
EU718125
EU718155
FJ536620
FJ536660
FJ536691
Scleroderma
verrucosum
AF336271
Tremellogaster
surinamensis
MCA 1985
Guyana
EU718127
DQ534664
FJ536622
FJ536662
FJ536693
Notes:
New species described in Phosri et al. [32]: A. smithii and ASTRAE-86 is the holotype.
New species described in Phosri et al. [32]: A. telleriae and ASTRAE-87 is the holotype.
Specimen codes as indicated in Figure 2 and 3. All specimens from Phu Khieo Wildlife Sanctuary abbreviated as PKWS.
Notes:New species described in Phosri et al. [32]: A. smithii and ASTRAE-86 is the holotype.New species described in Phosri et al. [32]: A. telleriae and ASTRAE-87 is the holotype.Specimen codes as indicated in Figure 2 and 3. All specimens from Phu Khieo Wildlife Sanctuary abbreviated as PKWS.
Figure 2
Maximum likelihood tree from a multigene dataset reveals the placement of Astraeus sirindhorniae within the Sclerodermatineae.
Thick vertical black bars identify root branch for the taxonomic lineage indicated by the adjacent label. Numbers above branches identify the statistics bootstrap percentages (bold text, before forward slash) and Bayesian posterior probabilities (normal text, after forward slash) for that branch. Maximum likelihood bootstraps from 1000 iterations. Bayesian posterior probabilities from 1000 iterations (1 million runs sampling every 1000th iteration).
Figure 3
Maximum likelihood tree from ITS dataset identifies Astraeus sirindhorniae as a distinct species of Astraeus.
Numbers above branches identify the statistics bootstrap percentages (bold text, before forward slash) and Bayesian posterior probabilities (normal text, after forward slash) for that branch. Maximum likelihood bootstraps from 1000 iterations. Bayesian posterior probabilities from 1000 iterations (1 million runs sampling every 1000th iteration).
Phylogenetic analysis
Two datasets were created for this study. One is a multigene dataset that examines the phylogenetic position of the gasteroid fungus from PKWS using ribosomal RNA and protein coding genes (nrLSU, the 5.8S region of the ITS, RPB1, RPB2 and EF1-a). Genes missing for individual samples were coded as “?” in the dataset to represent missing data. A second dataset consisted of only ITS sequence data to compare this taxon against other known Astraeus species. Both datasets, consisting of original sequences, plus sequences acquired from Genbank, were aligned using MUSCLE [18] with additional manual adjustments to the alignment performed in Mesquite 2.74 [19].For each dataset, maximum likelihood and Bayesian analyses were performed using the CIPRES web portal (http://www.phylo.org/portal2/) [20]. Maximum likelihood bootstrapping analyses was performed on each dataset with RAxML 7.2.8 [21], using the default parameters as implemented on the CIPRES NSF XSEDE resource with bootstrap statistics calculated from 1000 bootstrap replicates. Bayesian phylogenetic analyses were performed using Mr Bayes v. 3.2.1 [22] on CIPRES XSEDE resource with default parameters (Nst = 6, with 2 runs, 4 chains per run, each run searching for 1000000 generations sampling every 1000th generation).
Nomenclature
The electronic version of this article in Portable Document Format (PDF) in a work with an ISSN or ISBN will represent a published work according to the International Code of Nomenclature for algae, fungi, and plants, and hence the new names contained in the electronic publication of a PLOS ONE article are effectively published under that Code from the electronic edition alone, so there is no longer any need to provide printed copies.The new taxon described herein has been submitted to MycoBank and the unique MycoBank number provided can be used to retrieve the associated taxonomic information at http://www.mycobank.org/MycoTaxo.aspx?Link=T&Rec=.
Results
BLAST searches with megablast option were used to compare the sequences obtained (nrLSU and 1 around 1460 and 1310 bp, respectively) against the sequences in the National Center of Biotechnology Information (NCBI) nucleotide databases [17]. Sequences from the gasteroid fungus from PKWS produce matches for Astraeus spp., Diplocystis wrightii Berk. & M.A. Curtis, Pisolithus spp., Scleroderma spp., Tremellogaster surinamensis E. Fisch. and Veligaster columnaris (Berk. & Broome) Guzman. All of these taxa are gasteroid Boletales included in Sclerodermatineae [7].To evaluate the phylogenetic position of the sclerodermatoid fungus from PKWS, a multigene dataset was created using nrLSU, 5.8S, RPB1, RPB2 and EF1-a genes from 80 specimens. This dataset was rooted using the Boletinellaceae (Boletellus and Phlebopus) while the genera Astraeus, Calostoma, Diplocystis, Gyroporus, Phlebopus, Scleroderma and Tremellogaster consisted of the ingroup. Maximum likelihood bootstrap (MLB) and Bayesian posterior probabilities (PP) strongly support a monophyletic placement for the sclerodermatoid fungus with Astraeus (MLB = 99%, PP = 1.0; Fig. 2). With it's inclusion in Astraeus, there is a strong sister relationship with the monotypic genus Tremellogaster (MLB = 97%, PP = 1.0) and weak support for the inclusion of these taxa, along with Diplocystus to form the Diplocystidiaceae (MLB = 71%, PP = 0.95). Sequences use for both phylogenetic datasets and their corresponding GenBank accession numbers are given in Table 1.
Maximum likelihood tree from a multigene dataset reveals the placement of Astraeus sirindhorniae within the Sclerodermatineae.
Thick vertical black bars identify root branch for the taxonomic lineage indicated by the adjacent label. Numbers above branches identify the statistics bootstrap percentages (bold text, before forward slash) and Bayesian posterior probabilities (normal text, after forward slash) for that branch. Maximum likelihood bootstraps from 1000 iterations. Bayesian posterior probabilities from 1000 iterations (1 million runs sampling every 1000th iteration).An ITS dataset was developed to evaluate the uniqueness of this new taxon relative to other Astraeus species. This dataset consists of 28 samples (2 outgroup samples from Gyroporus). Maximum likelihood and Bayesian phylogenetic analysis identifies eight major clades that can be recognized as species (each with MLB>98% and PP = 1.0; Fig. 3). Five of these represent taxa already defined by Phosri et al. [23]. Four samples of the new Astraeus taxon form a strongly supported group distinct from the other major Astraeus clades (MLB = 100%, PP = 1.0) which we will from now on refer to as Astraeus sirindhorniae.
Maximum likelihood tree from ITS dataset identifies Astraeus sirindhorniae as a distinct species of Astraeus.
Numbers above branches identify the statistics bootstrap percentages (bold text, before forward slash) and Bayesian posterior probabilities (normal text, after forward slash) for that branch. Maximum likelihood bootstraps from 1000 iterations. Bayesian posterior probabilities from 1000 iterations (1 million runs sampling every 1000th iteration).
The species is named after Princess Sirindhorn on the occasion the 84th birthday of her father, who have both been supportive of natural heritage studies in Thailand and as a token of respect and recognition of the great interest shown by Her Majesty in the natural history and conservation of natural resources of Thailand. Now her name will be known in association with the Greek Titan of Astrology (Astraeus).
Large, subglobose to ellipsoid, subepigeous, dry basidiomes splitting at maturity to form a non-gelatinised, exoperidium with rays that unfold into a star-shaped structure. Enclosed within the exoperidium is a pale, thin, dry, stipitate endoperidium containing a powdery gleba of date-brown to umber (Colour identification chart, Royal Botanic Garden, E, 1969), large, globose, distinctly but minutely verrucose spores <11 µm diam. and lacking a columella.Basidiomes subglobose to ellipsoid at first (Fig. 4A), slightly compressed, hard, subepigeous 24.5–55.0 mm diam., dry, with woolly, adpressed covering forming felty, adpressed triangular to hexagonal scales, denser and more fluffy towards base where they are intermixed with date-brown to sepia rhizomorphs (Fig. 1A), splitting into concentric zones which fuse towards uppermost, exoposed parts, with thick, complex exoperidium (Fig. 4E), expanding to become star-shaped and then 40–100 mm broad, tough, surface often encrusted with soil particles; odour strong, penetrating, pleasant. When mature exoperidium buff to snuff-brown, squamulose, consisting of at least 3 distinct layers 3–5 mm thick when fresh, contracting to <1 mm when dry, leathery, splitting into 6–8 broad, stellate rays, innermost layer varying from buff to brownish, extensively scaly cracked to give almost regular pattern. Endoperidium shortly stipitate (Fig. 4B), globose to subglobose ca 18–32 µm diam., white at first, becoming buff to hazel when mature, very fluffy-fibrillose (Fig. 4C), even velvety opening by apical, irregular tear and lacking defined peristome. Gleba purplish chestnut becoming umber to date-brown when mature (Fig. 4D), lacking columella. Exoperidial suprapellis ca 70–80 µm, brownish, consisting of interwoven, periclinal to perpendicular, thin- or thick-walled hyphae 4–7 µm broad, with central lumen and walls 1–2 µm thick (Fig. 5A–C). Exoperidial mediopellis, fibrous ca 600 µm broad of interwoven periclinal to orthogonal hyphae 5–7 µm broad with hyaline, continuous lumen and walls 1–2 µm thick and becoming more parallel at junction with subpellis (Fig. 5C–F). Exoperidial subpellis pseudoparachymatous, ca 1050–1100 µm broad of hyaline, parallel to anticlinal, thick-walled hyphae with walls 1–2 µm thick (Fig. 5F and Fig. 6A–B). Clamp-connections absent in exoperidium. Endoperidium consisting of brownish, interwoven, unbranched, aseptate hyphae ca 5–8 µm broad with continous lumen and walls 1–2 µm thick, clamp-connections absent. Capillitium of long, unbranched, interwoven, hyaline, aseptate threads 4–7 µm broad and lacking clamp-connections (Fig. 6D). Basidiospores globose, (5.19)-6–11 µm diam., including ornamentation, umber to date-brown (Fig. 6D), with moderately dense, rounded, narrow, tapered, separate tubercles which coalesce in groups (Fig. 6 E–F).
Figure 4
Astraeus sirindhorniae.
(A) immature basidiomes, bar = 60 mm. (B) short stipitate endoperidium (arrowhead), bar = 3 mm. (C) fibrillose endoperidium (arrowhead), bar = 3 mm. (D) gleba colour become umber to date- brown when mature (arrowhead), bar = 10 mm. (E) complex outer peridium, bar = 3 mm.
Figure 5
Astraeus sirindhorniae.
Exoperidium layers. (A) exoperidial suprapellis, outer most surface, bar = 6 µm. (B) exoperidial suprapellis, bar = 7 µm. (C) interface layer between exoperidial suprapellis (top left) and mediopellis (lower right), bar = 6 µm. (D) exoperidial mediopellis, bar = 7 µm. (E) exoperidial mediopellis (inner most), bar = 7 µm. and (F) interface layers between exoperidial mediopellis (top left) and subpellis (lower right), bar = 8 µm. Magnification at 1,000×.
Figure 6
Astraeus sirindhorniae.
Exoperidium layers (A–B). (A) exoperidial subpellis, bar = 5 µm. (B) exoperidial subpellis (innermost), bar = 10 µm. (C) rhizomorph hyphae with clamp connection (arrowhead), bar = 5 µm. (D) capillitium hyphae displaying continuous lumen (arrowhead) and basidiospore (arrow), bar = 5 µm. (E–F) spore ornamentation demonstrated coalescent spines in groups, bar = 1 µm. A–D magnification at 1,000×.
Astraeus sirindhorniae.
(A) immature basidiomes, bar = 60 mm. (B) short stipitate endoperidium (arrowhead), bar = 3 mm. (C) fibrillose endoperidium (arrowhead), bar = 3 mm. (D) gleba colour become umber to date- brown when mature (arrowhead), bar = 10 mm. (E) complex outer peridium, bar = 3 mm.Exoperidium layers. (A) exoperidial suprapellis, outer most surface, bar = 6 µm. (B) exoperidial suprapellis, bar = 7 µm. (C) interface layer between exoperidial suprapellis (top left) and mediopellis (lower right), bar = 6 µm. (D) exoperidial mediopellis, bar = 7 µm. (E) exoperidial mediopellis (inner most), bar = 7 µm. and (F) interface layers between exoperidial mediopellis (top left) and subpellis (lower right), bar = 8 µm. Magnification at 1,000×.Exoperidium layers (A–B). (A) exoperidial subpellis, bar = 5 µm. (B) exoperidial subpellis (innermost), bar = 10 µm. (C) rhizomorph hyphae with clamp connection (arrowhead), bar = 5 µm. (D) capillitium hyphae displaying continuous lumen (arrowhead) and basidiospore (arrow), bar = 5 µm. (E–F) spore ornamentation demonstrated coalescent spines in groups, bar = 1 µm. A–D magnification at 1,000×.
Habitat
In rainy season, gregarious, partially buried in ultisols in dry deciduous forests associated with Dipterocarpus tuberculatus Roxb., Shorea obtusa Wall. and Shorea siamensis Miq.
Distribution
North and Northeastern areas of Thailand.
Material examined
Thailand, Chiyaphum province, Phu khieo Wildlife Sanctuary, Dipterocarp forests, N 16°27′32″ and E 101°39′414″, elev. 640 msl, 9 September 2010 (BBH 34830, duplicate E30288, duplicate MA-Fungi 82080); Ibidem, date, (BBH 34831), Mae Cham district, Dipterocarp forests, N 18°31′981″ and E 98°24′939″, June–September 2010.
Note
Her Royal Highness the Crown Princess of Thailand, has considered and granted for a new fungus name; A. sirindhornii. This name is a great honor and a privilege. However according to ICBN Recommendation 60C.1(b) If the personal name ends with a consonant (but not in -er), substantival epithets are formed by adding -i- (stem augmentation) plus the genitive inflection appropriate to the sex and number of the person(s) honoured (e.g. lecard-ii for Lecard (m), wilson-iae for Wilson (f), verlot-iorum for the Verlot brothers, braun-iarum for the Braun sisters, mason-iorum for Mason, father and daughter). Therefore A. sirindhornii should ending with –iae and then the epithet to be spelled; A. sirindhorniae.
Discussion
Astraeus sirindhorniae represents a new species of star-shaped gasteroid fungus which differs morphologically from many other genera of star-shaped fungi. In comparing this species, the earthstar genus, Geastrum, tends to have a well defined peristome. Myriostoma species may be distinguished by the formation of multiple irregular shaped peristomes from which spores escape. Trichaster differs in having an endoperidium that remains attached to the exoperidium after opening, then soon disintegrates leaving a powdery spore-mass suppported by a stout, persistent collumella. The endoperidium of Terrostella is thin and peels away to expose a powdery spore-mass supported by a distinct sterile base. Phialastrum has a strongly developed columella and Geasteropsis produces an extremely hard basidiome when dry.According to Phosri et al. there are only two Astraeus species in Thailand, A. odoratus and A. asiaticus
[23], [24]. Astraeus odoratus is found under ecological conditions similar to those at the Phu Khieo Wildlife Sanctuary. However, A. sirindhorniae differs in its much larger basidiomes, both when immature and when its rays are fully expanded, displaying flared margins, and exposing complex layering. Astraeus sirindhorniae is further differentiated from A. odoratus through the presence of prominent rhizomorphs, a complex multi-layered exoperidium, and smaller basidiospores (range 6–11 µm). These basidiospores are also smaller than A. asiaticus spores (8.75–15.2 µm) and generally given for A. hygrometricus s. str. viz. (7.5–12 µm) [25], [26], [27], [28], [29]. The spore ornamentation of A. sirindhorniae is notable under SEM as it has moderately dense, rounded, narrow, tapered, separate tubercles, which coalesce spines in groups. In addition, A. sirindhorniae has a short stipitate, very fluffly- fibrillose endoperidium when immature, which further differentiates this taxon from other Astraeus species.The outermost felty, scaly covering of the young basidiomes of A. sirindhorniae closely resembles that of members of Scleroderma previously placed in Veligaster. The gleba is probably not divided into tramal plates. As in A. sirindhorniae clamp-connections are absent from both the gleba and the peridium. On maturing the highly gelatinized middle layer is exposed well before the powdery gleba is revealed. In A. sirindhorniae the peridial medio- and subpeillis are not gelatinized and the hyphae are fully differentiated but otherwise the very young basidiomes are similar in primordial structure.In the multi-gene phylogenetic analyses A. sirindhorniae, along with other Astraeus species, form a monophyletic clade with Tremellogaster, and Diplocystis (Fig. 2). This clade is recognized as the Diplocystidiaceae. The structure of the peridium in Tremellogaster is also rather complex: the outer wall consists of thickened, sclerotised hyphae; the middle layer is brown and heavily gelatinised and divided into polygonal areas of plate-like, non-gelatinous tissue; and the innermost layer consisting of hyaline, thin-walled hyphae similar to those in A. sirindhorniae but posses transverse thickenings. A summary of the pertinent characters and literature references for Tremellogaster are given in Watling [30].Members of the Sclerodermatineae form ectomycorrhizal associations with many host plants. Species of Astraeus are known to associate with ectomycorrhizal plant hosts in the Pinaceae, Betulaceae, Fagaceae, Ericaceae and Dipterocarpaceae [31]. Given its phylogenetic placement, and the fact that it is found in dipterocarp dominated forests, it is likely that A. sirindhorniae is also an ectomycorrhizal fungus. Further study into the ecology of this species is needed in order to conclusively identify possible relationships to dipterocarpacious hosts.In the multigene phylogeny the basal position of A. sirindhorniae relative to other Astraeus taxa is interesting from a biogeographic standpoint (Fig. 2). This placement suggests a Southeast Asian origin for the genus, which is observed in many Sclerodermatineae genera [31]. However, this is complicated by the fact that the basal Diplocystidiaceae (Diplocystis and Tremellogaster) are monotypic genera whose species are described from the new world (the Caribbean and South America respectively). Further investigation into the biogeogaphic history of these taxa is necessary to understand the current distribution of new- and old-world Astraeus.
Conclusions
In summary A. sirindhorniae is morphologically distinguished from A. odoratus, A. asiaticus and A. hygrometricus s.l. by basidiome and basidiospore size, spore ornamentation and peridium structure. Phylogenetic analysis clearly resolves Astraeus sirindhorniae as a basal lineage of Astraeus, within the Diplocystidiaceae and Sclerodermatineae. This systematic relationship, in combination with its associations with dipterocarp forests, it is probable that this species is ectomycorrhizal with members of the Dipterocarpaceae. Astraeus sirindhorniae represents a new gasteroid, star-shaped fungus from Thailand. This discovery reinforces the belief that fungi represent a group of organisms with many undescribed taxa; some of which exist within the dry evergreen dipterocarp forests of SE Asia.
Authors: Kentaro Hosaka; Scott T Bates; Ross E Beever; Michael A Castellano; Wesley Colgan; Laura S Domínguez; Eduardo R Nouhra; József Geml; Admir J Giachini; S Ray Kenney; Nicholas B Simpson; Joseph W Spatafora; James M Trappe Journal: Mycologia Date: 2006 Nov-Dec Impact factor: 2.696
Authors: Fredrik Ronquist; Maxim Teslenko; Paul van der Mark; Daniel L Ayres; Aaron Darling; Sebastian Höhna; Bret Larget; Liang Liu; Marc A Suchard; John P Huelsenbeck Journal: Syst Biol Date: 2012-02-22 Impact factor: 15.683
Authors: A Paz; J-M Bellanger; C Lavoise; A Molia; M Ławrynowicz; E Larsson; I O Ibarguren; M Jeppson; T Læssøe; M Sauve; F Richard; P-A Moreau Journal: Persoonia Date: 2017-06-02 Impact factor: 11.051
Authors: Julieth O Sousa; Laura M Suz; Miguel A García; Donis S Alfredo; Luana M Conrado; Paulo Marinho; A Martyn Ainsworth; Iuri G Baseia; María P Martín Journal: PLoS One Date: 2017-06-07 Impact factor: 3.240
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