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. 2022 May 11;8(5):500. doi: 10.3390/jof8050500

Three New Species of Hypoxylon (Xylariales, Ascomycota) on a Multigene Phylogeny from Medog in Southwest China

Zi-Kun Song 1,2,, An-Hong Zhu 3,, Zhen-Dong Liu 4, Zhi Qu 1, Yu Li 2, Hai-Xia Ma 1,5,6,*
Editor: Yucheng Dai
PMCID: PMC9146989  PMID: 35628755

Abstract

During a survey of hypoxylaceous fungi in Medog county (Tibet Autonomous Region, China), three new species, including Hypoxylon damuense, Hypoxylon medogense, and Hypoxylon zangii, were described and illustrated based on morphological and multi-gene phylogenetic analyses. Hypoxylon damuense is characterized by its yellow-brown stromatal granules, light-brown to brown ascospores, and frequently indehiscent perispore. Hypoxylon medogense is morphologically and phylogenetically related to H. erythrostroma but differs in having larger ascospores with straight spore-length germ slit and conspicuously coil-like perispore ornamentation. Hypoxylon zangii shows morphological similarities to H. texense but differs in having Amber (47), Fulvous (43) and Sienna (8) KOH-extractable pigments and larger ascospores with straight spore-length germ slit. The multi-gene phylogenetic analyses inferred from the datasets of ITS-RPB2-LSU-TUB2 supported the three new taxa as separate lineages within Hypoxylon. A key to all known Hypoxylon species from China and related species worldwide is provided.

Keywords: Ascomycota, Hypoxylon, multigene phylogeny, taxonomy, wood-decomposing fungi, Xylariales

1. Introduction

Polyphasic taxonomic studies based on phylogenetic, chemotaxonomic, and morphological data were extensively applied to identify species and reflect evolutionary relationships of hypoxylaceous fungi in recent years [1,2,3]. Since resurrected and emended by Wendt et al. [2], 15 genera were rearranged and recognized to Hypoxylaceae by having stromatal pigments and a nodulisporium-like anamorph. According to the arrangement of the families in Sordariomycetes by Hyde et al. [4], 19 genera were accepted in Hypoxylaceae as saprobes and endophytes. Interesting, Hypoxylon species in endophytic stages may play an important ecological role in protecting their host plants from pathogens [4], and some species are related to insect vectors [2,5,6,7]. As the main family of Xylariales, Hypoxylaceae exhibits high diversity in tropical and subtropical areas [8,9,10,11]. In the classification system of Ju and Rogers [12], the genus Hypoxylon Bull. contains two subclades, the Annulata and Hypoxylon sections. Then they were segregated and the Annulata section was accepted as a new genus, Annulohypoxylon, based on molecular phylogenetic data inferred from ACT and TUB2 sequences [13]. Hypoxylon species are mainly saprobic on dead and decaying wood of angiospermous plants [14]. In this genus, more than 200 species with 1189 epithets included in the Index Fungorum have been reported so far [4,15,16]. Despite species of Hypoxylon being widely distributed throughout Asia, only 57 species were reported in China currently [17,18,19,20,21].

Medog county, Tibet Autonomous Region is located in southwest China, at the eastern end of the Himalayas and the lower reaches of the Yarlung Zangbo River, and belongs to a subtropical humid climate zone in the Himalayas, with abundant rainfall and an average annual temperature of 18.0 °C [22]. These unique climatic conditions contribute to the abundant resources of macro-fungi. In the current study, we surveyed hypoxylaceous taxa in Medog county, and three undescribed species of Hypoxylon were identified. The morphological characteristics of the three new species were described, and their nucleotide sequences were analyzed phylogenetically to confirm their status within Hypoxylon.

2. Materials and Methods

2.1. Collection of Specimens

The studied specimens were collected from Medog county (Tibet Autonomous Region), which is located in southwestern China. The explored sites are approximately at elevations from 800 to 1600 m above sea level (m.a.s.l.). The collected samples were dried with a portable drier (manufactured in Germany). Dried samples were labeled and then stored by ultrafreezing at −80 °C for a week to kill insects and their eggs before they were ready for studies. The Fungarium of the Institute of Tropical Bioscience and Biotechnology, Chinese Academy of Tropical Agricultural Sciences (FCATAS) is responsible for the preservation of specimens.

2.2. Morphological Observations

Sexual structures of the collected specimens were used for morphological observations and identification. The stroma and perithecia were observed, photographed and measured with a VHX-600E 3D microscope from the Keyence Corporation (Osaka, Japan). Fresh material was respectively immersed in water, 10% KOH, and Melzer’s reagent to observe micromorphological structures as determined by Ma et al. and Song et al. [20,21]. The observations, micrographs, and measurements of asci and ascospores were performed by using an Olympus IX73 inverted fluorescence microscope (Olympus, Tokyo, Japan) and the CellSens Dimensions Software (Olympus, Tokyo, Japan). The observations and photographs of ornamentation of ascospores were examined by scanning electron microscope (SEM) (Phenom Corporation, Netherlands) as given in Friebes and Wendelin [23]. The stromatal color and KOH-extractable pigments were assigned following the mycological color chart of Rayner [24]. The present paper contains the following abbreviations: KOH = 10% potassium hydroxide; n = number of measuring objects; M = arithmetical average of sizes of all measuring objects.

2.3. DNA Extraction, Amplification, and Sequencing

Fresh tissue of stroma was used for DNA extraction and sequence generation following the suggestions by Ma et al. and Song et al. [20,21]. Sequences of four DNA loci—ITS (internal transcribed spacer regions), nrLSU (nuclear large subunit ribosomal DNA), RPB2 (RNA polymerase II second largest subunit), and β-tubulin (beta-tubulin) were selected for multi-gene phylogenetic analyses [2,25]. The target sequences were amplified by the primers ITS4/ITS5, LR0R/LR5, fRPB2-7CR/fRPB2-5F, and T1/T22 [26,27,28,29,30]. In total, six ITS, six LSU, six RPB2, and six β-tubulin sequences of new Hypoxylon specimens collected from Medog were obtained and submitted to GenBank.

2.4. Molecular Phylogenetic Analyses

The listed Hypoxylaceae and Xylariaceae species in Table 1 originated from previously published studies. Besides Hypoxylon spp., the backbone tree contained species of related genera including Annulohypoxylon, Daldinia, Hypomontagnella, Jackrogersella, Pyrenopolyporus, Rhopalostroma, and Thamnomyces with Xylaria hypoxylon (L.) Grev. and Biscogniauxia nummularia (Bull.) Kuntze chosen to be outgroups.

Table 1.

GenBank accession numbers of sequences used in the multi-gene phylogenetic analyses. T and ET represent holotype and epitype specimens, respectively. Species in bold were derived from this study. N/A: not available.

Species Name Specimen No. Locality GenBank Accession No. References
ITS LSU RPB2 β-Tubulin Status
Annulohypoxylon annulatum CBS 140775 USA KU604559 KY610418 KY624263 KX376353 ET [2,11,25]
A. moriforme CBS 123579 Martinique KX376321 KY610425 KY624289 KX271261 [25]
A. truncatum CBS 140778 USA KX376329 KY610419 KY624277 KX376352 ET [2,25]
Daldinia dennisii CBS 114741 Australia JX658477 KY610435 KY624244 KC977262 T [2,9,34]
D. petriniae MUCL 49214 Austria JX658512 KY610439 KY624248 KC977261 ET [2,9,34]
Hypomontagnella barbarensis STMA 14081 Argentina MK131720 MK131718 MK135891 MK135893 T [35]
Hypom. monticulosa MUCL 54604 French Guiana KY610404 KY610487 KY624305 KX271273 ET [2]
Hypom. submonticulosa CBS 115280 France KC968923 KY610457 KY624226 KC977267 [2,9]
Hypoxylon addis MUCL 52797 Ethiopia KC968931 N/A N/A KC977287 T [9]
H. anthochroum YMJ 9 Mexico JN660819 N/A N/A AY951703 [13]
H. aveirense CMG 29 Portugal MN053021 N/A N/A MN066636 T [36]
H. baihualingense FCATAS 477 China MG490190 N/A N/A MH790276 T [18]
H. baruense UCH 9545 Panama MN056428 N/A N/A MK908142 [32]
H. begae YMJ 215 USA JN660820 N/A N/A AY951704 [13]
H. bellicolor UCH 9543 Panama MN056425 N/A N/A MK908139 [32]
H. brevisporum YMJ 36 Puerto Rico JN660821 N/A N/A AY951705 [13]
H. carneum MUCL 54177 France KY610400 KY610480 KY624297 KX271270 [2]
H. cercidicola CBS 119009 France KC968908 KY610444 KY624254 KX271270 [2,9]
H . chrysalidosporum FCATAS 2710 China OL467294 OL615106 OL584222 OL584229 T [20]
H. crocopeplum CBS 119004 France KC968907 KY610445 KY624255 KC977268 [2]
H . cyclobalanopsidis FCATAS 2714 China OL467298 OL615108 OL584225 OL584232 T [20]
H. damuense FCATAS 4207 China ON075427 ON075433 ON093251 ON093245 T This study
H. damuense FCATAS 4321 China ON075428 ON075434 ON093252 ON093246 This study
H. dieckmannii YMJ 89041203 China JN979413 N/A N/A AY951713 [13]
H. duranii YMJ 85 China JN979414 N/A N/A AY951714 [13]
H. erythrostroma YMJ 90080602 China JN979416 N/A N/A AY951716 [13]
H. eurasiaticum MUCL 57720 Iran MW367851 N/A MW373852 MW373861 [37]
H. fendleri DSM 107927 USA MK287533 MK287545 MK287558 MK287571 [38]
H. ferrugineum CBS 141259 Austria KX090079 N/A N/A KX090080 [23]
H. fragiforme MUCL 51264 Germany KM186294 KM186295 KM186296 KM186293 ET [38]
H. fraxinophilum MUCL 54176 France KC968938 N/A N/A KC977301 ET [9]
H. fulvosulphureum MFLUCC 13-0589 Thailand KP401576 N/A N/A KP401584 T [39]
H. fuscum CBS 113049 France KY610401 KY610482 KY624299 KX271271 ET [2]
H. griseobrunneum CBS 331.73 India KY610402 MH872399 KY624300 KC977303 T [2,9,40]
H. guilanense MUCL 57726 Iran MT214997 MT214992 MT212235 MT212239 T [15]
H. haematostroma MUCL 53301 Martinique KC968911 KY610484 KY624301 KC977291 ET [35]
H. hinnuleum MUCL 3621 USA MK287537 MK287549 MK287562 MK287575 T [38]
H. howeanum MUCL 47599 Germany AM749928 KY610448 KY624258 KC977277 [2,9,41]
H. hypomiltum MUCL 51845 Guadeloupe KY610403 KY610449 KY624302 KX271249 [2]
H. invadens MUCL 51475 France MT809133 MT809132 MT813037 MT813038 T [42]
H. investiens CBS 118183 Malaysia KC968925 KY610450 KY624259 KC977270 [2,9]
H. isabellinum STMA 10247 Martinique KC968935 N/A N/A KC977295 T [9]
H. jecorinum YMJ 39 Mexico JN979429 N/A N/A AY951731 [13]
H. jianfengense FACATAS845 China MW984546 MZ029707 MZ047260 MZ047264 T [21]
H. larissae FACATAS844 China MW984548 MZ029706 MZ047258 MZ047262 T [21]
H. lateripigmentum MUCL 53304 Martinique KC968933 KY610486 KY624304 KC977290 T [2,9]
H. lenormandii CBS 135869 Cameroon KY610390 KY610453 KY624262 KM610295 [2,43]
H. liviae CBS 115282 Norway NR155154 N/A N/A KC977265 ET [9]
H. lividicolor YMJ 70 China JN979432 N/A N/A AY951734 [13]
H. lividipigmentum YMJ 233 Mexico JN979433 N/A N/A AY951735 [13]
H. macrosporum YMJ 47 Canada JN979434 N/A N/A AY951736 [13]
H. medogense FCATAS 4061 China ON075425 ON075431 ON093249 ON093243 T This study
H. medogense FCATAS 4320 China ON075426 ON075432 ON093250 ON093244 This study
H. musceum MUCL 53765 Guadeloupe KC968926 KY610488 KY624306 KC977280 [2,9]
H. notatum YMJ 250 USA JQ009305 N/A N/A AY951739 [13]
H. olivaceopigmentum DSM 10792 USA MK287530 MK287542 MK287555 MK287568 T [38]
H. papillatum ATCC 58729 USA NR155153 KY610454 KY624223 KC977258 T [2,9]
H. perforatum CBS 115281 France KY610391 KY610455 KY624224 KX271250 [2]
H. petriniae CBS 114746 France NR155185 KY610491 KY624279 KX271274 T [2]
H. pilgerianum STMA 13455 Martinique KY610412 N/A KY624308 KY624315 [2]
H. porphyreum CBS 119022 France KC968921 KY610456 KY624225 KC977264 [2,9]
H. pseudofendleri MFLUCC 11-0639 Thailand KU940156 KU863144 N/A N/A [44]
H. pseudofuscum 18264 Germany MW367857 MW367848 MW373858 MW373867 T [37]
H. pulicicidum CBS 122622 Martinique JX183075 KY610492 KY624280 JX183072 T [2,45]
H. rickii MUCL 53309 Martinique KC968932 KY610416 KY624281 KC977288 ET [2]
H. rubiginosum MUCL 52887 Germany KC477232 KY610469 KY624266 KY624311 ET [2,46]
H. rutilum YMJ 181 France N/A N/A N/A AY951752 [13]
H. samuelsii MUCL 51843 Guadeloupe KC968916 KY610466 KY624269 KC977286 ET [2,9]
H. shearii YMJ 29 Mexico EF026142 N/A N/A AY951753 [13]
H. spegazzinianum STMA 14082 Argentina KU604573 N/A N/A KU604582 T [11]
H. sporistriatatunicum UCH 9542 Panama MN056426 N/A N/A MK908140 T [32]
H. subgilvum YMJ 88113007 China JQ009315 N/A N/A AY951755 [13]
H. sublenormandii JF 13026 Sri Lanka KM610291 N/A N/A KM610303 T [43]
H. texense DSM 107933 USA MK287536 MK287548 MK287561 MK287574 T [38]
H. ticinense CBS 115271 France JQ009317 KY610471 KY624272 AY951757 [2,13]
H. trugodes MUCL 54794 Sri Lanka KF234422 NG066380 KY624282 KF300548 ET [2,9]
H. ulmophilum YMJ 350 Russia JQ009320 N/A N/A AY951760 [13]
H. vogesiacum CBS 115273 France KC968920 KY610417 KY624283 KX271275 [2]
H. wujiangense GMBC0213 China MT568854 MT568853 MT585802 MT572481 T [19]
H. wuzhishanense FCATAS2708 China OL467292 OL615104 OL584220 OL584227 T [20]
H. zangii FCATAS 4029 China ON075423 ON075429 ON093247 ON093241 T This study
H. zangii FCATAS 4319 China ON075424 ON075430 ON093248 ON093242 This study
Jackrogersella cohaerens CBS 119126 Germany KY610396 KY610497 KY624270 KY624314 [2]
J. multiformis CBS 119016 Germany KC477234 KY610473 KY624290 KX271262 ET [2,9]
Pyrenopolyporus hunteri MUCL 52673 Ivory Coast KY610421 KY610472 KY624309 KU159530 ET [2,25]
P. laminosus MUCL 53305 Martinique KC968934 KY610485 KY624303 KC977292 T [2,9]
P. nicaraguensis CBS 117739 Burkina Faso AM749922 KY610489 KY624307 KC977272 [2,9,41]
Rhopalostroma angolense CBS 126414 Ivory Coas KY610420 KY610459 KY624228 KX271277 [2]
Thamnomyces dendroidea CBS 123578 French Guiana FN428831 KY610467 KY624232 KY624313 T [2,47]
Xylaria hypoxylon CBS 122620 Sweden KY610407 KY610495 KY624231 KX271279 ET [2]
Biscogniauxia nummularia MUCL 51395 France KY610382 KY610427 KY624236 KX271241 [2]
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The alignment, trimming, and concatenation of sequences followed Song et al. [21]. The multi-gene phylogenetic analyses were performed by using two methods of maximum likelihood (ML) and Bayesian analyses (BA) based on ITS-LSU-RPB2-β-tubulin datasets and ITS-β-tubulin datasets. The latter was used for an added validation to the former. Maximum likelihood analyses used raxmlGUI 2.0 with 1000 bootstrap replicates and GTRGAMMA+G as a substitution model [20,31,32]. Bayesian analyses used MrBayes 3.2.6 with jModelTest 2 conducting model discrimination and Markov chain Monte Carlo (MCMC) sampling. Every 100th generation was sampled as a tree with 1,000,000 generations running for six MCMC chains [20,33]. Phylogenetic trees were viewed and edited by FigTree version 1.4.3 and Photoshop CS6.

This study selected 89 taxa from 10 genera to perform phylogenetic analysis, including 3 Annulohypoxylon spp., 2 Daldinia spp., 3 Hypomontagnella spp., 72 Hypoxylon spp., 2 Jackrogersella spp., 3 Pyrenopolyporus spp., 1 Rhopalostroma sp., and 1 Thamnomyces sp. with X. hypoxylon and B. nummularia added as the outgroups. The sequence datasets comprised 306 sequences with 91 ITS, 62 LSU, 62 RPB2, and 91 β-tubulin sequences. After being aligned and trimmed, the combined dataset contained 3530 characters including gaps with 587 characters for ITS, 867 characters for LSU, 729 characters for RPB2, and 1347 characters for β-tubulin alignment, of which 1537 characters were parsimony-informative.

3. Results

3.1. Phylogenetic Analysis

The best-scoring ML tree was built with a final ML optimization likelihood value of −77,579.198447. Bayesian posterior probabilities were calculated with a final average standard deviation of split frequencies of less than 0.01. Phylogenetic trees of BA and ML analyses were found to be highly similar in topology, and the ML tree is represented in Figure 1. ML bootstrap support (BS) ≥ 50% and Bayesian posterior probabilities (PP) ≥ 0.95 were labelled along the branches, while branches with BS ≥ 70% and PP ≥ 0.98 were considered to be significant.

Figure 1.

Figure 1

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Phylogram of the best ML trees of the Hypoxylon species from an analysis based on multi-gene alignment of ITS-LSU-RPB2-β-tubulin. ML bootstrap support (BS) ≥ 50% and Bayesian posterior probabilities (PP) ≥ 0.95 are labelled above or below the respective branches (BS/PP). Species in bold were sequenced in this study.

Multi-gene phylogeny shows that our new species are clustered within the clades H2 and H3. Hypoxylon damuense and H. zangii are phylogenetically well differentiated. Hypoxylon damuense clustered with H. hypomiltum Mont. and H. wujiangense Y.H. Pi, Q.R. Li in a full support subclade (BS = 100%, PP = 1) in clade H2. Hypoxylon zangii clustered together with H. guilanense Pourmogh., C. Lamb. and H. texense Kuhnert, Sir in a full support subclade as a sister to H. rubiginosum (Pers.) Fr. Hypoxylon medogense formed a subclade with H. erythrostroma J.H. Mill. with full support in clade H3. The phylogenetic tree shows that Hypoxylon is a paraphyletic group with other genera embedded (e.g., Annulohypoxylon, Daldinia, and Hypomontagnella).

3.2. Taxonomy

Hypoxylon damuense Hai X. Ma, Z.K. Song and Y. Li, sp. nov., Figure 2.

Figure 2.

Figure 2

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Hypoxylon damuense (holotype FCATAS 4207). (a,b) Stromata on the bark of dead wood. (c) Stromatal surface. (d,e) Stroma in vertical section showing perithecia and ostioles. (f) KOH-extractable pigments. (g) Asci in water. (h) Asci in Melzer’s reagent. (i) Ascospores in water. (j) Ascospore in 10% KOH showing germ slit. (k) Apical apparatus in Melzer’s reagent. (l) Ascospores in 10% KOH. (m,n) Ascospores under SEM. Scale bars: (a) = 1 cm; (b) = 1000 µm; (c) = 500 µm; (d,e) = 200 µm; (gl) = 10 µm; (m,n) = 5 µm.

MycoBank: MB 843581

Diagnosis. Differs from H. rubiginosum in its larger asci, light-brown to brown ascospores with conspicuous coil-like ornamentation and most of the perispore indehiscent. Differs from H. hypomiltum in its smaller perithecia, larger asci and apical apparatus. Differs from H. wujiangense in its larger stromata and stromatal KOH-extractable pigments.

Etymology. Damuense (Lat.): referring to the holotype locality of species in Damu Township.

Holotype. CHINA: Tibet Autonomous Region, Medog County, Damu Township, Kabu Village, 29°38′42″ N, 95°37′44″ E, alt. 1280 m, saprobic on the bark of dead wood, 2 October 2021, Haixia Ma, Col. XZ207 (FCATAS 4207).

Teleomorph. Stromata pulvinate to effused-pulvinate, 1–9 cm long × 0.4–2 cm broad × 0.6–0.9 mm thick; with inconspicuous to conspicuous perithecial mounds; surface Bay (6), Rust (39) and Livid Purple (81), exposing black subsurface layer when colored coating worn off; with yellow-brown granules immediately beneath the surface and between perithecia; yielding luteous (12) and ochreous (44) to fulvous (43) KOH-extractable pigments; tissue below the perithecial layer black, 0.1–0.46 mm thick. Perithecia ovoid, black, 0.16–0.3 mm broad × 0.3–0.45 mm high. Ostioles umbilicate, opening lower than the stromatal surface or at the same level as the stromatal surface. Asci cylindrical with eight obliquely uniseriate ascospores, long-stipitate, 102–242 µm total length, the spore-bearing portion 60–72 µm long × 6.2–8.6 µm broad, and stipes 41–174 µm long, with amyloid apical apparatus bluing in Melzer’s reagent, discoid, 0.8–1.5 µm high × 1.6–2.4 µm broad. Ascospores light-brown to brown, unicellular, ellipsoid-inequilateral, with narrowly rounded ends, 8.2–10.5 × 4.1–5.5 µm (n = 60, M = 9.2 × 4.8 µm), with straight spore-length germ slit on the convex side; most of the perispore indehiscent in 10% KOH, occasionally dehiscent, with conspicuous coil-like ornamentation in SEM; epispore smooth.

Additional specimens examined. CHINA: Tibet Autonomous Region, Medog County, Damu Township, Kabu Village, 29°38′48″ N, 95°37′46″ E, alt. 1310 m, saprobic on the bark of dead wood, 2 October 2021, Haixia Ma, Col. XZ321(FCATAS 4321).

Note. Hypoxylon damuense was found in the subtropics, and characterized by large pulvinate stromata, long asci stipes, amyloid apical apparatus, light-brown to brown ascospores with straight germ slit, most of the perispore indehiscent in 10% KOH, with conspicuous coil-like ornamentation. The new species is quite similar to H. rubiginosum in ascospore dimensions and KOH-extractable pigments, but the latter has darker colored ascospores, smaller asci (100–170 µm total length), dehiscent perispores and smooth or with inconspicuous coil-like ornamentation. Hypoxylon rubiginosum sensu stricto was always discovered in the temperate northern hemisphere except for samples reported in Florida [12,15,48]. Moreover, the status of H. damuense as a new species is also supported in the phylogenetic trees, where it appears distant from H. rubiginosum.

Although phylogenetic analyses showed that H. damuense clustered with H. hypomiltum and H. wujiangense in a clade with strong supported values (100%/1), there are distinct morphological differences among them. Hypoxylon hypomiltum differs in having larger perithecia ((0.2–)0.3–0.5 mm broad × 0.5–0.7 mm high), smaller asci (90–132(–145) µm total length), smaller apical apparatus (0.3–0.6 µm high × 1.2–1.5 µm broad) and slightly oblique to sigmoid germ slit [12]. Hypoxylon wujiangense can be distinguished by its smaller stromata with white pruina surface, Sienna (8) KOH-extractable pigments and larger apical apparatus 1.5–2 µm high × 2.5–3 µm broad [19].

Hypoxylon medogense Hai X. Ma, Z.K. Song and Y. Li, sp. nov., Figure 3.

Figure 3.

Figure 3

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Hypoxylon medogense (holotype FCATAS 4061). (a,b) Stromata on the bark of dead wood. (c) Stromatal surface. (d,e) Stroma in vertical section showing perithecia and ostioles. (f) Asci in water. (g) Asci in Melzer’s reagent. (h) Apical apparatus in Melzer’s reagent. (i) KOH-extractable pigments. (j) Ascospore in 10% KOH. (k) Ascospore in water showing germ slit. (l) Ascospores in water. (m,n) Ascospore under SEM. Scale bars: (a) = 1 cm; (b) = 2 mm; (ce) = 200 µm; (fh,jl) = 10 µm; (m) = 5 µm; (n) = 8 µm.

MycoBank: MB 843582

Diagnosis. Differs from H. erythrostroma in its larger ascospores with straight spore-length germ slit and very conspicuous coil-like perispore ornamentation. Differs from H. laschii in ovoid to obovoid perithecia, shorter asci, and larger ascospores with very conspicuous coil-like perispore ornamentation.

Etymology. Medogense (Lat.): referring to the holotype locality of species in Medog county.

Holotype. CHINA: Tibet Autonomous Region, Medog County, Dexing Township, Deguo village, 29°24′58″ N, 95°23′6″ E, alt. 814 m, saprobic on the bark of dead wood, 25 September 2021, Haixia Ma, Col. XZ61 (FCATAS 4061).

Teleomorph. Stromata plane, pulvinate to effused-pulvinate, 3.9–16.5 cm long × 2.5–6.2 cm broad × 0.52–0.72 mm thick; with inconspicuous to conspicuous perithecial mounds; surface cinnamon (62), fulvous (43), ochreous (44) and bay (6); with orange or reddish-orange granules immediately beneath the surface and between perithecia; yielding amber (47), orange (7) or scarlet (5) KOH-extractable pigments; tissue below the perithecial layer inconspicuous, black. Perithecia ovoid to obovoid, black, 0.16–0.3 mm broad × 0.25–0.4 mm high. Ostioles with conical black papillae, opening higher than the stromatal surface. Asci cylindrical, eight-spored, uniseriate, 91–142 µm total length, the spore-bearing portion 60–79 µm long × 6.9–9.4 µm broad, and stipes 25–85 µm long, with amyloid apical apparatus bluing in Melzer’s reagent, discoid, 0.9–1.4 µm high × 2.4–2.9 µm broad. Ascospores brown to dark brown, unicellular, ellipsoid-inequilateral, with narrowly rounded ends, 9.9–12.8 × 4.6–7 µm (n = 60, M = 11.1 × 5.7 µm), with straight spore-length germ slit on the convex side; perispore dehiscent in 10% KOH, with very conspicuous coil-like ornamentation in SEM; epispore smooth.

Additional specimens examined. CHINA: Tibet Autonomous Region, Medog County, Dexing Township, Deguo village, 29°25′28″ N, 95°23′26″ E, alt. 808 m, saprobic on the bark of dead wood, 25 September 2021, Haixia Ma, Col. XZ320 (FCATAS 4320).

Note.Hypoxylon medogense is characterized by having a bright orange red waxy layer beneath the surface, orange (7) or scarlet (5) KOH-extractable pigments, ostioles higher than the stromatal surface, brown to dark brown ascospores with straight germ slit and dehiscent perispore with very conspicuous coil-like ornamentation. Although the phylogenetic trees (Figure 1 and Figure S1) show that H. medogense and H. erythrostroma are closely related, as well as similar to each other in stromatal morphology and KOH-extractable pigments, H. erythrostroma was originally described and illustrated by Miller (1933) from Florida, and can be distinguished from H. medogense by having smaller ascospores (6.5–9.5 × 3–4.5 µm) and a shorter spore-bearing portion of asci (40–50 µm). Ju and Rogers [12] reexamined the isotype of H. erythrostroma (GAM 2374) from the USA and other specimens from Brazil, French Guiana, Madagascar, Mexico, Papua New Guinea, and Puerto Rico, and found that the fungi has smaller ascospores ((7–)7.5–9.5 × 3–4.5 µm) with sigmoid germ slit spore-length and inconspicuous coil-like perispore ornamentation; the species was also reported in Guadeloupe (French West Indies) by Fournier et al. [10].

Notably, Hypoxylon medogense shows morphological similarities to H. crocopeplum Berk., M.A. Curtis and H. laschii Nitschke in stromatal morphology. Hypoxylon crocopeplum can be distinguished by obovoid to long tubular perithecia (0.1–0.3(–0.4) mm broad × 0.2–1.5 mm high), longer asci ((100–)120–205(–217) µm total length) and slightly larger ascospores ((9–)9.5–15(–17.5) × 4–7(–7.5) µm) with inconspicuous to conspicuous coil-like perispore ornamentation. Hypoxylon laschii has longer asci (165–190 µm total length) and smaller ascospores (8–10 × 3.5–4.5 µm) with no perspore ornamentation [12]. In the phylogenetic trees, H. medogense is distant from the two species.

Hypoxylon zangii Hai X. Ma, Z.K. Song and Y. Li, sp. nov., Figure 4.

Figure 4.

Figure 4

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Hypoxylon zangii (holotype FCATAS 4029). (a) Stroma on the bark of dead wood. (b,c) Stromatal surface. (d,e) Stroma in vertical section showing perithecia and ostioles. (f) KOH-extractable pigments. (g,h) Asci in water. (i) Ascospores in water showing germ slit. (j) Apical apparatus in Melzer’s reagent. (k) Ascospore in 10% KOH. (l,m) Ascospores in water. (n,o) Ascospores under SEM. Scale bars: (a) = 1 cm; (b) = 1 mm; (ce) = 200 µm; (g,im) = 10 µm; (h) = 20 µm; (n) = 5 µm; (o) = 8 µm.

MycoBank: MB 843580

Diagnosis. Differs from H. fendleri and H. retpela in its smaller ascospores. Differs from H. rubiginosum in its stromatal granules and a subtropical distribution. Differs from H. texense in its stromatal KOH-extractable pigments and larger ascospores. Differs from H. guilanense in its stromatal morphology.

Etymology.Zangii (Lat.): referring in honor to Chinese mycologist Dr. Zang Mu, who is also the author of “Field Records in the Mountains and Valleys: Discovery Journey to the Third Pole—Notes and Drawings of Zang Mu Scientific Expeditions”.

Holotype. CHINA: Tibet Autonomous Region, Medog County, Yarlung Zangbo River, the large bend of Linduo, 29°27′52″ N, 95°26′39″ E, alt. 781 m, saprobic on the bark of dead wood, 24 September 2021, Haixia Ma, Col. XZ29 (FCATAS 4029).

Teleomorph. Stromata effused-pulvinate, 1.2–4.1 cm long × 0.8–1 cm broad × 0.25–0.45 mm thick; with conspicuous perithecial mounds; surface livid red (56) and vinaceous (57); with orange or reddish orange granules immediately beneath the surface and between perithecia; yielding amber (47), fulvous (43) and sienna (8) KOH-extractable pigments; tissue below the perithecial layer inconspicuous, brown. Perithecia spherical, ovoid to obovoid, black, 0.2–0.4 mm broad × 0.3–0.5 mm high. Ostioles umbilicate, sometimes overlain with conspicuous white substance, opening lower than the stromatal surface. Asci cylindrical, eight-spored, uniseriate, 85–145 µm total length, the spore-bearing portion 65–92 µm long × 7.1–10.9 µm broad, and stipes 12–66 µm long, with amyloid apical apparatus bluing in Melzer’s reagent, discoid, 0.8–1.3 µm high × 2–2.9 µm broad. Ascospores light-brown to brown, unicellular, ellipsoid-inequilateral, with slightly acute to narrowly rounded ends, 10.9–14.6 × 4.8–6.4 µm (n = 60, M = 12.2 × 5.5 µm), with straight spore-length germ slit on the convex side; perispore dehiscent in 10% KOH, with inconspicuous coil-like ornamentation in SEM; epispore smooth.

Additional specimens examined. CHINA: Tibet Autonomous Region, Medog County, Yarlung Zangbo River, the larger bend of Linduo, 29°27′35″ N, 95°26′32″ E, alt. 780 m, saprobic on the bark of dead wood, 24 September 2021, Haixia Ma, Col. XZ319 (FCATAS 4319).

Note. The stromatal morphology of H. zangii is similar to H. fendleri Berk. ex Cooke, H. retpela Van der Gucht, Van der Veken and H. rubiginosum. However, H. fendleri differs by having slightly thicker stromata at 0.5–0.8 mm, smaller ascospores ((8–)9–12 × 4–5.5 µm) with sigmoid germ slit spore-length, while H. retpela has thicker stromata at 0.5–0.8 mm, and smaller ascospores ((9–)9.5–12 × 4.5–5 µm) with very conspicuous coil-like ornamentation [12]. Hypoxylon rubiginosum can also be distinguished by its yellowish-brown or brown stromatal granules, thicker stromata (0.5–1.2(–1.5) mm) and smaller ascospores ((8–)9–12 × 4–5.5 µm). In addition, H. rubiginosum prefers to distribute in the northern temperate region, while H. zangii was found in subtropical region [12,15,47]. These three species are distant from H. zangii in the phylogenetic trees (Figure 1).

Hypoxylon zangii clustered with H. guilanense and H. texense in a strong support clade in the phylogenetic trees. Hypoxylon texense shows morphological similarities to H. zangii with reddish-orange stromatal granules, but differs in having rust (39) to dark brick (86) instead of amber (47), fulvous (43) and sienna (8) KOH-extractable pigments, and smaller ascospores ((9–)9.5–12 × 4.5–5 µm) with straight to slightly sigmoid germ slit spore-length [37]. Hypoxylon guilanense differs from H. zangii in having hemispherical to pulvinate stromata with sienna (8), umber (9) to buff (45) surface colors, with conspicuous perithecial mounds, and slightly larger ascospores (12–15 × 5–6 µm) with conspicuous coil-like ornamentation [15].

        Dichotomous key to Hypoxylon species from China

             and related species worldwide

1. Ascospores nearly equilateral ............................................................................................. 2

1. Ascospores inequilateral ...................................................................................................... 8

2. Ostiolar barely to slightly higher than the stromatal surface ......................................... 3

2. Ostioles lower than the stromatal surface ......................................................................... 4

3. Perithecia spherical, (0.2–)0.3–0.4 mm broad .................................................. H. croceum

3. Perithecia spherical to tubular, 0.3–0.6 mm broad × 0.4–0.8 mm high. H. parksianum

4. Perispore dehiscent in 10% KOH ............................................................... H. hypomiltum

4. Perispore indehiscent in 10% KOH .................................................................................... 5

5. Perithecia tubular to long tubular ....................................................................................... 6

5. Perithecia obovoid ................................................................................................................ 7

6. KOH-extractable pigments orange (7) ................................................... H. cinnabarinum

6. KOH-extractable pigments greenish yellow (16), dull green (70), or dark green

(21) ...................................................................................................................... H. investiens

7. Stromatal surface brown vinaceous (84), sepia (63), or chestnut (40); without apparent

KOH-extractable pigments or with dilute grayish sepia (106) to blackish

pigments ........................................................................................................ H. dieckmannii

7. Stromatal surface fawn (87) or umber (9); KOH-extractable pigments hazel

(88) ................................................................................................................... H. gilbertsonii

8. Ostiolar barely to slightly higher than the stromatal surface ......................................... 9

8. Ostioles lower than the stromatal surface ....................................................................... 15

9. Perithecia tubular.................................................................................... H. lienhwacheense

9. Perithecia spherical, ovoid to obovoid ............................................................................. 10

10. Stromatal granules black ............................................................................... H. hainanense

10. Stromatal granules colored ................................................................................................ 11

11. Stromata glomerate; KOH-extractable pigments hazel (88) .................. H. lenormandii

11. Stromata pulvinate; KOH-extractable pigments orange (7) ......................................... 12

12. Sigmoid germ slit ................................................………......................... H. erythrostroma

12. Straight germ slit ................................................................................................................. 13

13. Perispore with very conspicuous coil-like ornamentation ....................... H. medogense

13. Perispore smooth or with inconspicuous coil-like ornamentation .............................. 14

14. Stromata pulvinate to discoid, erumpent, usually encircled with ruptured plant tissue;

perithecia 0.2–0.4(–0.5) mm diam ............................................................ H. laschii

14. Stromata pulvinate to effused-pulvinate, sometimes hemispherical, plane; perithecia

0.1–0.2 mm diam ................................................................................................... H. rutilum

15. Sigmoid germ slit .........................................………........................………………… 16

15. Straight or slightly sigmoid germ slit ............................................................................... 19

16. Perispore with conspicuous coil-like ornamentation ................... H. cyclobalanopsidis

16. Perispore smooth or with inconspicuous coil-like ornamentation .............................. 17

17. Sigmoid germ slit much less than spore-length; stromata glomerate, with conspicuous

perithecial mounds; KOH-extractable pigments pure yellow (14) with citrine (13) tone,

greenish olivaceous (90), or orange (7) ............................. H. musceum

17. Sigmoid germ slit spore-length; stromata pulvinate or effused-pulvinate, with inconsp

icuous to conspicuous perithecial mounds; KOH-extractable pigments with other

colors ..................……................................................................................................. 18

18. KOH-extractable pigments orange (7) ..................……..................................... H. fendleri

18. KOH-extractable pigments vinaceous purple (101) ............…..................... H. fuscoides

19. Perispore infrequently dehiscent in 10% KOH .................…….....................……......... 20

19. Perispore dehiscent in 10% KOH .................…….........................…................................ 22

20. Stromata saprobic on surface of dead bamboo ................................... H. wuzhishanense

20. Stromata saprobic on the bark of dicot wood ................................................................. 21

21. Ascospores light-brown to brown, 8.2–10.5 × 4.1–5.5 µm, with straight germslit spore-

length ....................................................................................................... H. damuense

21. Ascospores brown to dark brown, (10–)10.5–11.5(–12.5) × 5–6.5 µm, with straight germ

slit slightly less than spore-length .............................................................. H. dengii

22. Perispore with conspicuous coil-like ornamentation .................................................... 23

22. Perispore smooth or with inconspicuous coil-like ornamentation .............................. 28

23. Stromata pulvinate to effused-pulvinate ......................................................................... 24

23. Stromata glomerate or hemispherical .............................................................................. 25

24. Perithecia tubular to long tubular or obovoid, 0.2–0.3 mm broad × 0.6–0.9 mm high;

ascospores light brown to dark brown, 10.3–13.6 × (4.2–) 4.7–6.1 μm, with conspicuous

straight germ slit .................................................................... H. jianfengense

24. Perithecia spherical to obovoid, 0.2–0.3 mm broad × 0.2–0.5 mm high; ascospores

brown to dark brown, (9–)9.5–12 × 4.5–5 μm, with straight to slightly sigmoid germ

slit ............................................................................................................................. H. retpela

25. KOH-extractable pigments orange (7) ............................................................................. 26

25. KOH-extractable pigments with other colors ................................................................. 27

26. Stromata glomerate to pulvinate; stromatal granules dull yellow

or rust ............................................................................................................. H. baihualingense

26. Stromata hemispherical to pulvinate; stromatal granules scarlet (5) to orange

(7) ....................................................................................................................... H. guilanense

27. Stromatal granules pale brown to dull reddish-brown; KOH-extractable pigments pale

luteous (11), honey (60) and ochreous (44); apical apparatus highly reduced or lacking,

not bluing in Melzer’s reagent; ascospores light-brown to brown, with slightly broad

rounded ends, 8–10.6(–11.1) × 4.1–6.3(–7.1) µm ... H. chrysalidosporum

27. Stromatal granules dull reddish-brown to blackish; KOH-extractable pigments

isabelline (65) or amber (47); apical apparatus bluing in Melzer’s reagent; ascospores

brown to dark brown, with narrowly rounded ends, 9.5–13(–14.5) × 4.5–6.5

µm ........................................................................................................................... H. duranii

28. KOH-extractable pigments greenish to olivaceous ........................................................ 29

28. KOH-extractable pigments with other colors ................................................................. 33

29. Stromata pulvinate to effused-pulvinate ......................................................................... 30

29. Stromata glomerate or hemispherical .............................................................................. 31

30. Ascospores brown to dark brown, 8.5–13.5 × 4–6 μm .......................... H. anthochroum

30. Ascospores light brown to brown, 5.5–8 × 2.5–3.5 μm ........................... H. brevisporum

31. Apical apparatus highly reduced or lacking, not bluing in Melzer’s rea

gent .................................................................................................................. H. notatum

31. Apical apparatus bluing in Melzer’s reagent .................................................................. 32

32. Perithecia spherical to obovoid, 0.1–0.3(–0.4) mm broad × 0.2–0.5 mm high; slightly

sigmoid germ slit ................................................................................................... H. fuscum

32. Perithecia long tubular, 0.3–0.6 mm broad × (0.6–)0.8–2 mm high; straight germ

slit ................................................................................................................. H. placentiforme

33. Stromata hemispherical ...................................................................................................... 34

33. Stromata pulvinate to effused-pulvinate ......................................................................... 37

34. Perithecia long tubular .......................................................................... H. haematostroma

34. Perithecia spherical to obovoid ......................................................................................... 35

35. KOH-extractable pigments amber (47) with greenish yellow (16) tone, or greenish

yellow (16) with citrine (13) tone ................................................................ H. perforatum

35. KOH-extractable pigments orange (7) ............................................................................. 36

36. Apical apparatus bluing in Melzer’s reagent, 0.8–1.2 μm high × 2.2–2.8 μm broad;

ascospores (10.5–)11–15 × 5–6.5(–7) μm ....................................................... H. fragiforme

36. Apical apparatus bluing in Melzer’s reagent, 0.4–0.8 μm high × 1.2–2 μm broad;

ascospores 7–9.5(–10) × 3–4.5 μm ................................................................. H. howeanum

37. Perithecia tubular ................................................................................................................ 38

37. Perithecia spherical to obovoid ......................................................................................... 42

38. Stromatal granules black; KOH-extractable pigments dark livid (80) .... H. lividicolor

38. Stromatal granules colored; KOH-extractable pigments with other colors ............... 39

39. KOH-extractable pigments pure yellow (14) or amber (47) ......................... H. trugodes

39. KOH-extractable pigments orange (7) ............................................................................. 40

40. Apical apparatus bluing in Melzer’s reagent, 0.2–0.5 μm high × 1–1.5 μm

broad ................................................................................................................... H. jecorinum

40. Apical apparatus lightly bluing or bluing in Melzer’s reagent, more than 1.5 μm

broad ..................................................................................................................................... 41

41. Perithecia spherical, obovoid to long tubular, up to 1.5 mm high; ascospores (9–)9.5

–15(–17.5) × 4–7(–7.5) μm; Virgariella-like conidiogenous structure

........................................................................................................ H. crocopeplum

41. Perithecia obovoid to tubular, up to 0.7 mm high; ascospores 7–11 × 3.5–5 μm;

Nodulisporium-like conidiogenous structure ................................................ H. subgilvum

42. Stromata saprobic on dead bamboo .......................................................... H. pilgerianum

42. Stromata saprobic on dicot wood ..................................................................................... 43

43. Ascospores 15.5–22.9(–23.6) × 7.3–10.6 μm ....................................................... H. larissae

43. Ascospores length less than 15 µm ................................................................................... 44

44. Perithecia subglobose, 0.5–0.7 mm broad; straight or slightly sigmoid germ slit nearly

spore-length ...................................................................................... H. wujiangense

44. Perithecia less than 0.5 mm broad; straight germ slit spore-length ............................. 45

45. Stromatal granules orange or reddish orange; ascospores light-brown ..................... 46

45. Stromatal granules yellowish-brown or dull purplish-brown; ascospores dark

brown .................................................................................................................................... 47

46. KOH-extractable pigments rust (39) to dark brick (86); ascospore (8.7–)9.1–10.8(–11.5)

× (4.0–)4.5–5.4 μm .................................................................................................. H. texense

46. KOH-extractable pigments amber (47), fulvous (43) and sienna (8); ascospore 10.9–14.6

× 4.8–6.4 µm ............................................................................................. H. zangii

47. Stromatal granules yellowish-brown or brown; perithecia 0.2–0.5 mm broad × 0.3–0.6

mm high; smooth or with inconspicuous coil-like ornamentation perispore; Periconiella-

like conidiogenous structure .................................................. H. rubiginosum

47. Stromatal granules dull purplish-brown; perithecia 0.1–0.2 mm broad × 0.2–0.3 mm

high; smooth perispore; Nodulisporium-like conidiogenous structure

.............................................................................................. H. vinosopulvinatum

4. Discussion

In the present study, three species of Hypoxylon from Medog in China, H. damuense, H. medogense, and H. zangii, are described as new species based on molecular analyses and morphological features. Phylogenetic analyses on the species of Hypoxylon presented confirmed that Hypoxylon is a polyphyletic genus. The species analyzed appeared mainly distributed in six separate clades (except H. papillatum Ellis, Everh. and H. dieckmannii Theiss.). Hypoxylon damuense and H. zangii were clearly separated from other sampled species of Hypoxylon and from each other in the clade H2, and H. medogense was included in clade H3 containing H. fragiforme (Pers.) J. Kickx f., the type species of the genus. The phylogenetic tree shows that the classification of Hypoxylon is confusing. It did not suggest any apparent correlation in morphological features with the distribution of species in the phylogenetic trees. Therefore, more collections, more gene sequences and new taxonomic features, as well as the application of polyphasic taxonomic approaches based on morphological (sexual and asexual), chemotaxonomic, and phylogenetic data of this genus are needed in the further studies. Previously numerous new species have been found in Southwest China [49,50], and present paper confirmed that more known fungal species in the area.

Acknowledgments

We express our gratitude to Zhu-nian Wang, Qing-long Wang, Hu-biao Yang, Shi-song Xu (Tropical Crops Genetic Resources Institute, Chinese Academy of Tropical Agricultural Sciences), Rong-jie Zhu (Tibet Academy of Agricultural and Animal Husbandry Sciences), and Xue-da Chen (Tibet Agriculture and Animal Husbandry University) for help during field collections. We gratefully acknowledge Guo-dao Liu for his helpful suggestions to improve the nomenclature of the new species. Special thanks to Xiao-wei Qin and Ting-yu Bai (Spice and Beverage Research Institute, Chinese Academy of Tropical Agricultural Sciences) for assistance in micrographs produced by SEM.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/jof8050500/s1, Figure S1: ML phylogram inferred from ITS-TUB2 sequences. ML bootstrap support (BS) ≥ 50% and Bayesian posterior probabilities (PP) ≥ 0.95 are labelled above or below the respective branches (BS/PP). Species in bold were sequenced in the this study.

Click here for additional data file. (417.2KB, zip)

Author Contributions

Z.-K.S., A.-H.Z., Z.-D.L., Z.Q. and H.-X.M. prepared the samples; Z.-K.S. made morphological examinations and performed molecular sequencing; A.-H.Z. performed phylogenetic analyses. Z.-K.S., A.-H.Z. and H.-X.M. wrote the manuscript; Y.L. revised the language of the text; H.-X.M. conceived and supervised the work. All authors have read and agreed to the published version of the manuscript.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

All newly generated sequences were deposited in GenBank (https://www.ncbi.nlm.nih.gov/genbank/, accessed on 15 March 2022; Table 1). All new taxa were deposited in MycoBank (https://www.mycobank.org/, accessed on 12 March 2022; MycoBank identifiers follow new taxa).

Conflicts of Interest

The authors declare no conflict of interest.

Funding Statement

The research was supported by the National Natural Science Foundation of China (No. 31972848, 31770023), and Central Public-interest Scientific Institution Basal Research Fund for Chinese Academy of Tropical Agricultural Sciences (No. 1630032022001, 1630052022003, 1630052022042).

Footnotes

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Click here for additional data file. (417.2KB, zip)

Data Availability Statement

All newly generated sequences were deposited in GenBank (https://www.ncbi.nlm.nih.gov/genbank/, accessed on 15 March 2022; Table 1). All new taxa were deposited in MycoBank (https://www.mycobank.org/, accessed on 12 March 2022; MycoBank identifiers follow new taxa).

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