Microascaceae from the Marine Environment, with Descriptions of Six New Species

Wang, Meng-Meng; Yang, Shi-Yu; Li, Qi; Zheng, Yao; Ma, He-He; Tu, Ye-Hui; Li, Wei; Cai, Lei

doi:10.3390/jof10010045

Open AccessArticle

Microascaceae from the Marine Environment, with Descriptions of Six New Species

by

Meng-Meng Wang

^1,2,3,

Shi-Yu Yang

¹,

Qi Li

^1,2,3,

Yao Zheng

⁴,

He-He Ma

⁴,

Ye-Hui Tu

¹,

Wei Li

^1,2,3,4,*

and

Lei Cai

^5,*

¹

College of Science, Shantou University, Shantou 515063, China

²

Guangdong Provincial Key Laboratory of Marine Biotechnology, Shantou University, Shantou 515063, China

³

Guangdong Provincial Key Laboratory of Marine Disaster Prediction and Prevention, Shantou University, Shantou 515063, China

⁴

College of Marine Life Sciences, Ocean University of China, Qingdao 266005, China

⁵

State Key Laboratory of Mycology, Institute of Microbiology, Chinese Academy of Sciences, Beijing 100101, China

^*

Authors to whom correspondence should be addressed.

J. Fungi 2024, 10(1), 45; https://doi.org/10.3390/jof10010045

Submission received: 3 November 2023 / Revised: 20 December 2023 / Accepted: 23 December 2023 / Published: 5 January 2024

(This article belongs to the Special Issue Women in Mycology, 2nd Edition)

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Abstract

:

Most reported members of Microascaceae that have been reported originate from the terrestrial environment, where they act as saprobes or plant pathogens. However, our understanding of their species diversity and distribution in the marine environment remains vastly limited, with only 22 species in nine genera having been reported so far. A survey of the fungal diversity in intertidal areas of China’s mainland has revealed the discovery of several Microascaceae strains from 14 marine algae and 15 sediment samples. Based on morphological characteristics and LSU-ITS-tef1-tub2 multilocus phylogeny using Bayesian inference and maximum likelihood methods, 48 strains were identified as 18 species belonging to six genera. Among these, six new species were discovered: Gamsia sedimenticola, Microascus algicola, M. gennadii, Scedosporium ellipsosporium, S. shenzhenensis, and S. sphaerospermum. Additionally, the worldwide distribution of the species within this family across various marine habitats was briefly reviewed and discussed. Our study expands the knowledge of species diversity and distribution of Microascaceae in the marine environment.

Keywords:

marine fungi; new species; Microascaceae; species diversity

1. Introduction

The family Microascaceae (Microascales, Sordariomycetes, and Ascomycota) was originally erected in 1951 by Luttrell to accommodate the genus Microascus, characterised as having beaked ascocarps with evanescent asci disposed irregularly throughout the centrum [1]. Later in 1970, Malloch reviewed known species, introduced two new species, and then illustrated the new concepts of this family, including ascocarps, ascospores, and complex hyaline to brightly coloured, conidiophores that are phialide bearing [2]. Over the past several decades, advances in morphology and multilocus phylogenetic analyses have led to a better understanding of the taxonomy and species diversity of this family. Species in this family are mainly characterised by their annellidic asexual morphs with dry aseptate conidia, as well as their sexual morphs that form cleistothecial or perithecial, carbonaceous ascomata producing reniform, lunate, or triangular ascospores with or without germ pores [3]. Currently, about 290 species in 23 genera are accepted in Microascaceae [4]. The majority of these species are found in terrestrial environments and act as saprobes or pathogens of plants, and also as opportunistic pathogens of humans with some exhibiting intrinsic resistance to antifungal agents [5].

However, there is limited information available on the species diversity and distribution of Microascaceae in the marine environment. In 1973, a new species, Scopulariopsis halophilica Tubaki, was introduced and described from the macroalgae Undaria pinnatifida collected from Japan [6]. This is, to our knowledge, the first microascaceous fungus to be isolated from the marine environment. Since then, several studies using culture-dependent approaches have documented the wide distribution of microascaceous fungi from intertidal zones of European and tropical regions, and marginal seas of China, with a total of 22 species reported in nine genera (Acaulium, Cephalotrichum, Microascus, Petriella, Pseudallescheria, Pseudoscopulariopsis, Scedosporium, Scopulariopsis, and Wardomyces) [7,8,9,10]. Several culture-independent approaches using ITS1 or ITS2 rDNA metabarcoding have uncovered substantial occurrences of this family in the seas surrounding China [11,12,13]. This is fortified by the identification of 109 microascaceous OTUs (operational taxonomic units), which were annotated into 13 genera, and extracted from intertidal sediments from China’s mainland [14]. Five microascaceous OTUs were also detected from the seawater samples collected from the Western Pacific Ocean [15]. These findings indicate the potential global distribution of microascaceous fungi within the ocean.

Marine fungi are capable of producing a variety of secondary metabolites such as those with antimicrobial properties [16]. The Microascaceae fungi recovered from the marine environment have demonstrated great potential in industrial and agricultural applications. A new monoterpenoid compound, Scopuquinolone B, was first isolated from a coral-derived Scopulariospis sp. isolate LF580 [17]. Proteomic analysis of Sc. brevicaulis from marine sponges identified thousands of proteins and diverse biosynthetic enzyme complexes [18]. Several species, e.g., Micoascus trigonosporus, displayed a highly lethal effect on agricultural pests and a significant inhibitory effect on pathogens of plant diseases [19]. It is necessary to obtain more Microascaceae fungi from the marine environment and to promote more research about the physiology, biochemistry, metabolites, and ecological functions of this group of fungi.

Most of the known culturable fungal species have been found on various substrates collected from the intertidal region, such as seagrasses, seaweeds, mangrove plants, sediments, and driftwood [7,8,9,10], indicating that the intertidal region provides an ideal shelter to host numerous and diverse fungi. In a survey of fungal diversity in the intertidal areas of China’s mainland, 48 microascaceous strains were isolated from 14 marine algae and 15 sediment samples collected from 22 locations. Our aims for this study are (1) to identify species and clarify the phylogenetic relationships of these fungi, (2) to identify and describe new species of Microascaceae, and (3) to review species diversity, host/habitat, and geographic distribution of Microascaceae in the marine environment.

2. Materials and Methods

2.1. Sample Collection and Fungal Isolation

Algae and sediment samples were collected from intertidal zones of Fujian, Guangdong, Jiangsu, Liaoning, Shandong, and Zhejiang provinces, and Tianjin city (Figure 1). For algae, six asymptomatic thalli of each algae species from each site were collected and put into sterilised plastic bottles. Species identification of algae was carried out following morphological descriptions by Zeng [20]. For sediment samples, a 200 g sediment sample was collected from each site and placed into a sterilised sampling bag. The samples were placed into a low-temperature storage box with gel packs and brought back to the laboratory as soon as possible.

Fungi were isolated from algae using the dilution-plate method [21] and tissue-isolation method, with some modifications. Each algae sample was washed with sterilised seawater, cut into segments of about 0.5 × (0.2–0.5) cm, and surface sterilised by dipping in 70% ethanol for 5 s followed by immersion in 4% NaOCl for 60 s and washed with sterile distilled water for 10 s [22]. Using the dilution-plate method, approximately 1 g of the segments were placed in a sterilised mortar and ground to tissue homogenate with 10 mL of sterilised seawater. The suspension was moved into a sterilised tube, diluted to a series of concentrations (10⁻¹, 10⁻², 10⁻³, and 10⁻⁴), and, finally, spread onto isolation media with three replicates. Using the tissue-isolation method, after cutting into segments and surface sterilization, 6–10 algal segments were spread on the isolation media with three replicates. Five types of isolation media, namely Martin medium (MM; each 1 L medium containing peptone 5.0 g, dextrose 10.0 g, monopotassium phosphate 1.0 g, magnesium sulfate 0.5 g, chloramphenicol 0.1 g, rose Bengal 0.033 g, agar 20.0 g, and seawater 1 L), 1/10 potato dextrose agar (1/10 PDA; each 1 L medium containing potato 20.0 g, dextrose 2.0 g, agar 20.0 g, and seawater 1 L), 1/5 malt extract agar (1/5 MEA; each 1 L medium containing malt extract 4.0 g, peptone 0.2 g, dextrose 4.0 g, agar 20.0 g, and seawater 1 L), corn meal agar (CMA; each 1 L medium containing corn meal 30.0 g, agar 20.0 g, and seawater 1 L), and yeast extract peptone glucose agar (YPG; each 1 L medium containing yeast extract 1.25 g, peptone 1.25 g, dextrose 4.0 g, agar 20.0 g, and seawater 1 L) containing ampicillin (500 mg/L) and streptomycin (500 mg/L), were selected and used for fungal isolation in this study.

Figure 1. Locations of the 14 marine algae (green dot) and 15 sediments (black dot) samples from the intertidal areas of mainland China (a), the thallus of algal hosts of the microascaceous fungi (b), and the typical algal habitats and the typical mudflat, sand beach, and gravel beach in the intertidal zones (c).

Fungi were isolated from sediments using the dilution-plate method [21] and the direct-isolation method, with some modifications. In the dilution-plate method, 10 g of sediment from each sample were suspended in 90 mL of sterile seawater in a 100 mL triangular glass flask and cultivated by shaking at 150 rpm/min at 25 °C for 20 min. The suspension was diluted to a series of concentrations (10⁻¹, 10⁻², 10⁻³, and 10⁻⁴) and plated on five types of isolation media with three replicates. Using the direct-isolation method, approximately 1 g of each sediment sample was spread directly on five types of isolation media with three replicates.

All plates were incubated at room temperature and examined every 2 days using an Olympus SZX7 stereomicroscope for fungal hyphae. Individual colonies were picked up with a sterilised needle and transferred onto fresh PDA plates on the benchtop. All the cultures were incubated at room temperature after 7 days and then were purified using an optimised protocol for single-spore isolation [23]. All isolates examined in this study were deposited in Wei Li’s personal culture collection (WL). Type specimens of new species were deposited in the Fungarium of the Institute of Microbiology (HMAS), with the ex-type living cultures in the China General Microbiological Culture Collection Center (CGMCC).

2.2. Morphological Observation

The isolates studied were incubated on synthetic nutrient-poor agar plates (SNA) [24], PDA, and oatmeal agar (OA). After 7 days of incubation in the dark, culture characteristics, including colony morphology, pigmentation, and odour were observed. Colours were assessed according to the colour charts of Kornerup and Wanscher (1978) [25]. Micromorphological characteristics were examined and photo-documented using water as a mounting medium under an Olympus BX53 microscope with differential interference contrast (DIC) optics. For each species, respectively, 30 conidiophores, 30 conidiogenous cells, 30 chlamydospores, and 50 microconidia were mounted and measured randomly.

2.3. DNA Extraction and Amplification

Genomic DNA was extracted from fungal mycelia grown on PDA, using a modified CTAB protocol as described in Guo et al. (2000) [26]. Four loci, including partial large-subunit ribosomal RNA (LSU), 5.8S nuclear ribosomal RNA gene with the two flanking internal transcribed spacer (ITS) regions, partial translation elongation factor (tef1), and partial β-tubulin (tub2), were amplified using primer pairs LR0R/LR5 [27], ITS5/ITS4 [28], EF1-983F/EF1-2218R [29], and Bt2a/Bt2b [30], respectively. Amplification reactions were performed in a reaction volume containing 12.5 μL of 2 × Taq PCR Master Mix (Vazyme Biotech Co., Ltd., Nanjing, China), 1 μL each of 10 μM primers, and 1 μL of the undiluted genomic DNA, adjusted to a final volume of 25 μL with distilled deionised water (Dongsheng, EDC810, China). PCR parameters were as follows: 94 °C for 10 min, followed by 35 cycles of 94 °C for 30 s, 50 (for LSU)/54 (for ITS)/57 (for tef1 and tub2) °C for 30 s, 72 °C for 30 s, and a final elongation step at 72 °C for 10 min. The PCR products were visualised on 1% agarose electrophoresis gel. Sequencing was performed bidirectionally and conducted by the BGI Write Company (Beijing, China). Consensus sequences were obtained using SeqMan of the Lasergene software package v. 14.1 (DNAstar, Madison, WI, USA).

2.4. Phylogenetic Analyses

The sequences of the Microascaceae strains examined in this study and the reference strains are listed in Table 1. For each locus, sequences were aligned using MAFFT v. 7 [31], and the alignments were manually adjusted where necessary. The best-fitting nucleotide-substitution models according to the Akaike Information Criterion (AIC) were selected using jModelTest v. 2.1.7 [32,33]. Alignments derived from this study were deposited in TreeBASE (submission ID 30581), and taxonomic novelties were deposited in FungalNames.

Phylogenetic analyses of the combined dataset were performed using Bayesian inference (BI) and maximum-likelihood (ML) methods. The BI analyses were conducted using MrBayes v. 3.2.1 [34] following the protocol of Wang et al. (2019) [35], with optimisation of each locus treated as a partition in combined analyses, based on the Markov Chain Monte Carlo (MCMC) approach [36]. All characters were equally weighted, and gaps were treated as missing data. The stationarity of the analyses was determined by examining the standard deviation of split frequencies (<0.01) and –ln likelihood plots in AWTY [37]. The ML analyses were conducted using PhyML v. 3.0 [38], with 1000 bootstrap replicates. The general time reversible model was applied with an invariable gamma-distributed rate variation (GTR+I+G).

3. Results

3.1. Phylogenetic Analyses

Analyses of the Microascaceae phylogeny were conducted by using a combined LSU (897 bp), ITS (665 bp), tef1 (924 bp) and tub2 (539 bp) dataset. For the BI analysis, the GTR+I+G model was selected for the LSU, ITS, tef1 and tub2 loci. The phylogeny showed that our isolates were clustered into 18 species in six genera of Microascaceae, namely Cephalotrichum (3 species), Gamsia (1), Microascus (7), Scedosporium (5), Scopulariopsis (1), and Wardomyces (1), including six new species (Figure 2).

3.2. Species List and Taxonomy

Cephalotrichum Link, Mag. Gesell. naturf. Freunde, Berlin 3(1-2): 20 (1809).

Cephalotrichum microsporum (Sacc.) P.M. Kirk, in Kirk and Spooner, Kew Bull. 38(4): 578 (1984).

Examined isolates: CHINA, Shandong Province, Qingdao city, from an unidentified red alga collected from a sand beach, April 2010, Y.T. Peng and K.M. Sun (WL00192); Weihai city, from unidentified green algae, June 2010, K.M. Sun and W. Li (WL00303, WL00305); Weihai city, from an unidentified brown alga, June 2010, K.M. Sun and W. Li (WL00350).

Cephalotrichum nanum (Ehrenb.) S. Hughes, Can. J. Bot. 36: 744 (1958).

Examined isolates: CHINA, Zhejiang Province, Ningbo city (121°46′36.72″ E, 29°58′15.42″ N), from intertidal sediment of a mudflat, July 2014, X.M. Bian and W. Li (WL03115, WL03362).

Cephalotrichum purpureofuscum (S. Hughes) S. Hughes, Can. J. Bot. 36: 744 (1958).

Examined isolates: CHINA, Guangdong Province, Shenzhen city, from Sargassum canfusum collected from a gravels beach, May 2014, M.M. Wang and W. Li (WL02022, WL06350, WL06351).

Gamsia M. Morelet, Ann. Soc. Sci. Nat. Arch. Toulon et du Var 21: 105 (1969).

Gamsia sedimenticolaM.M. Wang, W. Li and L. Cai sp. nov., Figure 3.

FungalNames: FN 571622.

Etymology: named after the habitat of the type specimen, sediment.

Typus: CHINA, Shandong Province, Qingdao city (120°19′09.12″ E, 36°03′38.64″ N), from intertidal sediment of a mudflat, June 2014, X.M. Bian and W. Li (HMAS352501, holotype designated here, dried culture on SNA; culture ex-type CGMCC3.25342 = WL02722).

Sexual morph not observed. Asexual morph on PDA and OA conidiophores reduced to conidiogenous cells, polyblastic, subcylindrical to cylindrical with a swollen apical part, 2–2.5 × 2–3.5 μm, and hyaline to somewhat darkening at the apex, smooth- and thin-walled, with 1–3 apical conidiogenous loci. Conidia 0–1-septate, ovoid to broadly ellipsoidal, with a rounded-to-pointed apex, flat at the base, pale to dark brown, 7–9 × 5–6.5 μm, smooth and thick walled, and often with a conspicuous longitudinal germ slit.

Figure 3. Morphological characters of Gamsia sedimenticola (from ex-type WL02722). (a–f): colonies on PDA, OA and SNA after 7d; (g,h): Conidiogenous cells; (i,j): Conidia in chains. Bars: (g–j) = 10 μm.

Culture characteristics—colonies on PDA are 30–40 mm diam in 7 d at 25 °C, flat, felty to floccose, and olive green near the centre, with a white regular margin; reverse pale olive green near the centre and white near the margin. Colonies on OA are 30–40 mm diam in 7 d at 25 °C, margin regular, flat, and dark olive green; the reverse is dark olive green. Colonies on SNA are 30–35 mm diam in 7 d at 25 °C, flat, with scarce aerial mycelia, and pale olive green near the centre, with a white regular margin; reverse pale olive green near the centre, white near the margin.

Other examined isolates: CHINA, Shandong Province, Qingdao city (120°19′09.12″ E, 36°03′38.64″ N), from intertidal sediment of a mudflat, June 2014, X.M. Bian and W. Li (WL06358); ibid. (WL06359).

Notes: The genus Gamsia was erected to accommodate the Wardomyces species that form 1-septate annelloconidia [39]. Sandoval-Denis et al. demonstrated that the lack of well-differentiated conidiophores and the conidial arrangement with large apical clusters justifies the separation of Gamsia from Wardomyces [40]. Five species are currently accepted in Gamsia [39,40,41,42,43], and one new species, G. sedimenticola, was added in this study. Phylogenetically, G. sedimenticola is closely related to G. aggregate (Malloch) Kiffer and M. Morelet, G. columbina (Demelius) Sand.-Den., Guarro and Genéand G. kooimaniorum Sand.-Den. (Figure 2), but differs from G. aggregate and G. kooimaniorum by 29 and 24 bp in the LSU-ITS sequences, and from G. columbina by 34 bp in the LSU-ITS-tef1-tub2 dataset, respectively. Morphologically, the four species exhibit marked differences in characters of aerial conidiophores (reduced to conidiogenous cells, polyblastic, subcylindrical to cylindrical with a swollen apical part, 2–2.5 × 2–3.5 μm in G. sedimenticola vs. borne singly or in small clusters on short branches, flask-shaped, 10–35 × 3–4 μm in G. aggregate, usually unbranched, 0−1-septate, 3–15 × 1.5–3 μm in G. columbina and unbranched or rarely laterally branched once, produced abundantly borne laterally and singly on the aerial hyphae, 0−1(−2)-septate, 12–28 × 1.5–7 μm in G. kooimaniorum), and the shape, size, and colour of conidia (7–9 × 5–6.5 μm, ovoid to broadly ellipsoidal, pale to dark brown in G. sedimenticola vs. 8–10.5 × 3.5–5 μm, ellipsoidal, rounded or apiculate/hyaline in G. aggregate, 5–10.5 × 2.5–5.5 μm, oval, smooth/hyaline in G. columbina and 5.5–10.5 × 4–7 μm, ovoid to broadly ellipsoidal, and pale to dark brown in G. kooimaniorum) [40,41,42,43]. In addition, G. sedimenticola was isolated from intertidal sediment in China, differing from G. aggregate from the dung of a carnivore in the USA, G. columbina from air, soil, decaying wood, and milled rice in Austria, Germany, Japan, and the Netherlands, and G. kooimaniorum from the soil in Netherlands [40,41,42,43].

MicroascusZukal, Verh. Kaiserl.-Königl. zool.-bot. Ges. Wien 35: 342 (1886).

Microascus algicolaM.M. Wang, W. Li and L. Cai sp. nov., Figure 4.

FungalNames: FN 571623.

Etymology: named after the host of type specimen, algae.

Typus: CHINA, Shandong Province, Qingdao city, from Grateloupia filicina collected from a gravels beach, unknown date, M.M. Wang and W. Li (HMAS352502, holotype designated here, dried culture on SNA; culture ex-type CGMCC3.25343 = WL01268).

Sexual morph not observed. Asexual morphs on PDA, OA, and SNA conidiophores are simple, straight, septate, branched or rarely unbranched, and hyaline. Conidiogenous cells in whorls of 2–3 on the apex of conidiophores, or rarely solitary on aerial hyphae, lageniform to ampulliform, straight or slightly curved, pale brown, 5–11 × 2.5–4 µm. Conidia in long chains, ellipsoidal, smooth to slightly rough, thick walled, hyaline to pale brown, and 3.5–6 × 3–5 µm.

Culture characteristics—colonies on PDA are 35–45 mm diam in 7 d at 25 °C, flat, felty to floccose, and greyish brown near the centre, with a pale-brown regular margin; the reverse is greyish brown near the centre, white near the margin. Colonies on OA are 35–45 mm diam in 7 d at 25 °C, margin regular, flat, and dark olive green in the centre, with a white regular margin; the reverse is dark olive green near the centre and white near the margin. Colonies on SNA are 30–35 mm diam in 7 d at 25 °C, flat, with scarce aerial mycelia, and pale olive green near the centre, with a white regular margin; the reverse is pale olive green near the centre and with a white regular margin.

Figure 4. Morphological characters of Microascus algicola (from ex-type WL01268). (a–f): colonies on PDA, OA and SNA after 7 d; (g–j): Conidiophores and conidiogenous cells; (k): Conidia in chains. Bars: (g–k) = 10 μm. Bars: (g–k) = 10 μm.

Other examined isolates: CHINA, Shandong Province, Weihai city, from an unidentified brown alga collected from a sand beach, June 2010, K.M. Sun and W. Li (WL00347); Qingdao city, from Colpomenia sinuosa from a sand beach, October 2011, Y.T. Peng, C.H. Feng, and C.L. Li (WL00633), from Ahnfeltiopsis flabelliformis from a sand beach, December 2014, M.M. Wang (WL01021).

Notes: phylogenetically, Microascus algicola is most closely related to M. hyalinus (Malloch and Cain) Sand.-Den., Gené and Guarro (Figure 2), but differs by 233 bp in the four loci dataset. Morphologically, M. algicola could be distinguished in the shape and size of conidia (ellipsoidal, 3.5–6 × 3–5 µm), while M. hyalinus produces ovoid, 3.5–5 × 2–3.5 μm conidia [4]. In addition, currently, all known isolates of M. algicola was isolated from marine algae (listed above) in intertidal zones in China, while M. hyalinus was isolated from soil and dung in Europe and North America [44,45].

Microascus croci (J.F.H. Beyma) Sand.-Den., Gené and Guarro, in Sandoval-Denis, Gené, Sutton, Cano-Lira, de Hoog, Decock and Guarro, Persoonia 36: 17 (2015).

Examined isolates: CHINA, Shandong Province, Qingdao city, from Blidingia minima from a gravels beach, May 2014, M.M. Wang and W. Li (WL02042).

Microascus gennadii M.M. Wang, W. Li, and L. Cai sp. nov., Figure 5.

Fungal names: FN 571624.

Etymology: named after the ellipsoidal conidia of this species.

Typus: CHINA, unknown location, from intertidal sediment, May 2014, X.M. Bian and W. Li (HMAS352503, holotype designated here, dried culture on SNA; culture ex-type CGMCC3.25344 = WL02353).

Sexual morph is not observed. Asexual morph on PDA and OA conidiophores are simple, straight, septate, branched or rarely unbranched, and hyaline. Conidiogenous cells are solitary on aerial hyphae or in whorls of 2–3 on the apex of conidiophores, lageniform to ampulliform, straight or slightly curved, pale brown, and 9–14 × 2–3.5 µm. Conidia are in long chains, ellipsoidal, smooth to slightly rough, thick-walled, hyaline, and 4–8 × 3–6 µm.

Culture characteristics—colonies on PDA are 35–45 mm diam in 7 d at 25 °C, flat, felty to floccose, and pale grey near the centre, with a pale brown irregular margin; the reverse is pale brown near the centre and white near the margin. Colonies on OA are 35–40 mm diam in 7 d at 25 °C, margin regular, flat, and dark olive green, with a white regular margin; the reverse is dark olive green near the centre and white near the margin. Colonies on SNA are 30–40 mm diam in 7 d at 25 °C, flat, with scarce aerial mycelia, and pale olive green near the centre, with a white regular margin; the reverse is pale olive green near the centre, with a white regular margin.

Figure 5. Morphological characters of Microascus gennadii (from ex-type WL02353). (a–f): colonies on PDA, OA, and SNA after 7 d; (g–j): Conidiophores and conidiogenous cells; (k): Conidia in chains. Bars: (g–k) = 10 μm.

Other examined isolates: CHINA, unknown location, from intertidal sediment, May 2014, X.M. Bian and W. Li (WL06354); ibid. (WL06355).

Notes: phylogenetically, Microascus gennadii is closely related to M. murinus (Samson and Klopotek) Sand.-Den., Gené and Guarro (Figure 2), but differs by 241 bp in the four loci dataset. Morphologically, the two species are distinct in the shape and size of conidia (ellipsoidal, 4–8 × 3–6 µm in M. gennadii vs. cylindrical, 4–6 × 1.5–2 μm in M. murinus) [5].

Microascus croci (Samson and Klopotek) Sand.-Den., Gené and Guarro, in Sandoval-Denis, Gené, Sutton, Cano-Lira, de Hoog, Decock and Guarro, Persoonia 36: 21 (2015).

Examined isolates: CHINA, Shandong Province, Yantai city (120°42′07.50″ E, 37°48′41.22″ N), from the intertidal sediment of a gravel beach, June 2014, X.M. Bian and W. Li (WL03684); Qingdao city (120°11′42.05″ E, 36°3′45.58″ N), from the intertidal sediment of a gravel beach, August 2014, Y. Zheng, H.P. Yang and W. Li (WL05483).

Microascus restrictus Sand.-Den., Gené and Deanna A. Sutton, in Sandoval-Denis, Gené, Sutton, Cano-Lira, de Hoog, Decock and Guarro, Persoonia 36: 21 (2015).

Examined isolates: CHINA, Liaoning Province, Huludao city (120°47′33.34″ E, 40°36′14.56″ N), from the intertidal sediment of a sand beach, May 2014, X.M. Bian and W. Li (WL02392).

Microascus trigonosporus C.W. Emmons and B.O. Dodge, Mycologia 23(5): 317 (1931).

Examined isolates: CHINA, Shandong Province, Qingdao city, from Cladophora sp. from a sand beach, October 2010, Y.T. Peng, C.H. Feng and C.L. Li (WL00670); ibid., from Ulva linza from a sand beach, April 2014, M.M. Wang (WL01853); ibid., from Gracilaria textorii from sand beach, June 2014, M.M. Wang (WL01882); ibid., from the intertidal sediment of a sand beach, X.M. Bian and W. Li (WL02833).

Microascus verrucosus Sand.-Den., Gené and Cano, in Sandoval-Denis, Gené, Sutton, Cano-Lira, de Hoog, Decock and Guarro, Persoonia 36: 23 (2015).

Examined isolates: CHINA, Shandong Province, Dongying city (119°09′45.18″ E, 37°45′34.86″ N), from the intertidal sediment of a mudflat, January 2014, M.M. Wang (WL02828).

Scedosporium Sacc. ex Castell. and Chalm., Manual of Tropical Medicine (London): 1122 (1919).

Scedosporium boydii (Shear) Gilgado, Gené, Cano and Guarro, J. Clin. Microbiol. 46(2): 770 (2008).

Examined isolates: CHINA, Shandong Province, Qingdao city (120°19′06.25″ E, 36°03′34.13″ N), from the intertidal sediment of a sand beach, January 2014, X.M. Bian and W. Li (WL02794); Weihai city (122°10′13″E, 37°30′2″ N), from the intertidal sediment of a sand beach, November 2020, M.M. Wang and Y. Zheng (WL05602); Tianjin city (117°45′38″ E, 39°6′36.64″ N), from the intertidal sediment of a mudflat, April 2021, M.M. Wang and Y. Zheng (WL05951).

Scedosporium ellipsosporium M.M. Wang, W. Li and L. Cai sp. nov., Figure 6.

FungalNames: FN 571625.

Figure 6. Morphological characters of Scedosporium ellipsosporium (from ex-type WL02370). (a–f): colonies on PDA, OA, and SNA after 7 d; (g,h): Conidiophores and conidiogenous cells; (i): Conidia. Bars: (g–i) = 10 μm.

Etymology: referring to the shape of conidia, ellipsoidal.

Typus: CHINA, Guangdong Province, Shenzhen city (114°20′45.63″ E, 22°36′01.03″ N), from intertidal sediment of a gravel beach, May 2014, X.M. Bian and W. Li (HMAS352504, holotype designated here, dried culture on SNA; culture ex-type CGMCC3.25345 = WL02370).

Sexual morph is not observed. Asexual morph on PDA and SNA conidiophores are solitary, often reduced to a single conidiogenous cell arising laterally from undifferentiated hypha, or stalked, bearing two or three conidiogenous cells at the top. Conidiogenous cells are annellidic, lateral or terminal, hyaline, smooth- and thin-walled, cylindrical to flask-shaped, and 10–40 × 1.5–2.5 µm, with several, distinct annellations at the top with age. Conidia aseptate, solitary, arranged in slimy masses, hyaline, ellipsoidal, flat at the base, and 5–9 × 3–5 µm.

Culture characteristics—colonies on PDA are 40–55 mm diam in 7 d at 25 °C, flat, felty to floccose, and olive green near the centre, with a white regular margin; the reverse is olive green near the centre, and white near the margin. Colonies on OA are 50–65 mm diam in 7 d at 25 °C, flat, and olive green near the centre, with a white regular margin; the reverse is olive green near the centre, and white near the margin. Colonies on SNA are 30–40 mm diam in 7 d at 25 °C, flat, with scarce aerial mycelia, and pale olive green near the centre, with a white regular margin; the reverse is pale olive green near the centre, with a white regular margin.

Other examined isolates: CHINA, Shandong Province, Qingdao city (120°19′09.12″ E, 36°03′38.64″ N), from intertidal sediment of a mudflat, June 2014, X.M. Bian and W. Li (WL02793).

Notes: phylogenetically, Scedosporium ellipsosporium is closely related to S. dehoogii Gilgado, Cano, Gené and Guarro (Figure 2), but differs by 42 bp in the ITS-tub2 sequences. Morphologically, the two species could be distinguished in the colour, shape, and size of conidia (hyaline, ellipsoidal, and 5–9 × 3–5 µm in S. ellipsosporium vs. subhyaline or slightly grey, and usually ovate, 5–8 × 5–6 μm in S. dehoogii) [46].

Scedosporium hainanense Zhi Y. Zhang, Y.F. Han and Z.Q. Liang, in Zhang, Shao, Li, Chen, Liang, Han, Huang and Liang, Microbiology Spectrum 9(2): e00867-21, 16 (2021).

Examined isolates: CHINA, Jiangsu Province, Yancheng city (119°52′32″ E, 34°27′27″ N), from intertidal sediment of a mudflat, April 2021, Z.Q. Zeng and C. Liu (WL05931).

Scedosporium shenzhenensis M.M. Wang, W. Li and L. Cai sp. nov., Figure 7.

FungalNames: FN 571626.

Etymology: named after the location of the type specimen, Shenzhen.

Typus: CHINA, Guangdong Province, Shenzhen city (113°56′59.08″ E, 22°31′18.51″ N), from intertidal sediment of a gravel beach, May 2014, X.M. Bian and W. Li (HMAS352505, holotype designated here, dried culture on SNA; culture ex-type CGMCC3.25346 = WL02375).

Sexual morph is not observed. Asexual morph on PDA and SNA conidiophores are solitary, often reduced to a single conidiogenous cell arising laterally from undifferentiated hypha, or stalked, bearing two or three conidiogenous cells at the top. Conidiogenous cells are annellidic, lateral or terminal, hyaline, smooth and thin walled, cylindrical to flask-shaped, and 8–30 × 1.5–2.5 µm, with several distinct annellations at the top with age. Conidia aseptate, solitary, arranged in slimy masses, hyaline, ellipsoidal, flat at the base, smooth to slightly rough, and 7–16 × 3.5–7 µm.

Culture characteristics—colonies on PDA are 40–55 mm diam in 7 d at 25 °C, flat, felty to floccose, and pale olive green near the centre, with a white regular margin; the reverse is pale olive green near the centre and white near the margin. Colonies on OA are 50–65 mm diam in 7 d at 25 °C, flat and pale olive green near the centre, with a white regular margin; the reverse is pale olive green near the centre with white near the margin. Colonies on SNA are 30–40 mm diam in 7 d at 25 °C, flat, with scarce aerial mycelia and are pale olive green near the centre, with a white regular margin; the reverse is pale olive green near the centre, with a white regular margin.

Other examined isolates: CHINA, Guangdong Province, Shenzhen city (113°56′59.08″ E, 22°31′18.51″ N), from intertidal sediment of a gravels beach, May 2014, X.M. Bian and W. Li (WL06356); ibid. (WL06357).

Figure 7. Morphological characters of Scedosporium shenzhenensis (from ex-type WL02375). (a–f): colonies on PDA, OA, and SNA after 7 d; (g–j): Conidiophores and conidiogenous cells; (k): Conidia. Bars: (g–k) = 10 μm.

Notes: Phylogenetically, Scedosporium shenzhenensis formed a distinct basal clade in Scedosporium (Figure 2). Considering the typical Scedosporium morphology of our isolates (Figure 8), we tentatively placed this species in the genus Scedosporium. Morphologically, S. shenzhenensis is similar to S. aurantiacum Gilgado, Cano, Gené and Guarro, S. dehoogii, S. ellipsosporium (Arx and Fassat.) McGinnis, A.A. Padhye and Ajello and S. sphaerospermum in the cylindrical to flask-shaped conidiogenous cells, but differs in the shape and size of conidia (ellipsoidal, 7–16 × 3.5–7 µm in S. shenzhenensis vs. obovoid, 6–10 × 3–5 µm in S. aurantiacum, obovoid, 5–8 × 5–6 µm in S. dehoogii, ellipsoidal, 5–9 × 3–5 µm in S. ellipsosporium and globose to ellipsoidal, 6–8 × 4–5 µm in S. sphaerospermum) [46,47,48].

Scedosporium sphaerospermum M.M. Wang, W. Li and L. Cai sp. nov., Figure 8.

FungalNames: FN 571627.

Etymology: referring to the globose shape of conidia.

Typus: CHINA, Shandong Province, Qingdao city (120°19′09.12″ E, 36°03′38.64″ N), from intertidal sediment of a mudflat, June 2014, X.M. Bian and W. Li (HMAS352506, holotype designated here, dried culture on SNA; culture ex-type CGMCC3.25347 = WL02796).

Sexual morph is not observed. Asexual morph on PDA and SNA conidiophores are solitary, sometimes reduced to a single conidiogenous cell arising laterally from undifferentiated hyphae. Conidiogenous cells are annellidic, lateral or terminal, hyaline, smooth- and thin walled, cylindrical to flask-shaped, and 2–20 × 1.5–2.5 µm, with several, distinct annellations at the top with the age. Conidia aseptate, solitary, arranged in slimy masses, hyaline to pale brown, globose to ellipsoidal, sometimes elliptic to oblong obovate, flat at the base, and 6–8 × 4–5 µm.

Culture characteristics—colonies on PDA are 15–25 mm diam in 7 d at 25 °C, flat, felty to floccose, and pale grey near the centre, with a white regular margin; the reverse is yellowish brown near the centre and white near the margin. Colonies on OA are 20–35 mm diam in 7 d at 25 °C, flat, and pale grey near the centre, with a white regular margin; the reverse is a pale greyish yellow near the centre and white near the margin. Colonies on SNA are 10–20 mm diam in 7 d at 25 °C, flat, with scarce aerial mycelia, and white; the reverse is white.

Figure 8. Morphological characters of Scedosporium sphaerospermum (from ex-type WL02796). (a–f): colonies on PDA, OA, and SNA after 7d; (g–i): Conidiophores and conidiogenous cells; (j): Conidia. Bars: (g–j) = 10 μm.

Other examined isolates: CHINA, Shandong Province, Qingdao city (120°19′09.12″ E, 36°03′38.64″ N), from intertidal sediment of a mudflat, June 2014, X.M. Bian and W. Li (WL06360); ibid. (WL06361).

Notes: phylogenetically, S. sphaerospermum forms a sister clade to S. angustum and S. fusoideum (Arx) McGinnis, A.A. Padhye and Ajello in the genus Scedosporium (Figure 2), and differs from the latter species by 36 bp and 129 bp in the LSU-ITS-tef1-tub2 dataset, respectively. Morphologically, the three species could be distinguished by the characters of the sexual morph (absence in S. sphaerospermum, ascomata spherical, nonostiolate, dark brown, 100–150 µm, with allipsoidal or nearly cylindrical with rounded ends ascospores in S. angustum and ascomata submerged or semi-immersed, spherical or nearly so, non-ostiolate, dark brown, 50–100 µm, with broadly fusiform, and yellowish or straw-coloured ascospores in S. fusoideum), and shape and size of conidia (globose to ellipsoidal, 6–8 × 4–5 µm S. sphaerospermum vs. clavate or nearly cylindrical, 5–10 × 3–4.5 µm in S. angustum and clavate, 6–10 × 3.5–5 µm in S. fusoideum) [49].

Scopulariopsis Bainier, Bull. Soc. mycol. Fr. 23(2): 98 (1907).

Scopulariopsis brevicaulis (Sacc.) Bainier [as ‘brevicaule’], Bull. Soc. mycol. Fr. 23(2): 99 (1907).

Examined isolates: CHINA, Shandong Province, Qingdao city, from Ulva pertusa from a sand beach, October 2011, Y.T. Peng, C.H. Feng, and C.L. Li (WL00657); Fujian Province, Ningde city (120°03′39.98″ E, 26°52′51.89″ N), from intertidal sediment of a mudflat, June 2014, X.M. Bian and W. Li (WL03882).

Wardomyces F.T. Brooks and Hansf., Trans. Br. Mycol. Soc. 8(3): 137 (1923).

Wardomyces inflatus (Marchal) Hennebert, Trans. Br. Mycol. Soc. 51(5): 755 (1968).

Examined isolates: CHINA, Shandong Province, Weihai city, from intertidal sediment of a sand beach, June 2010, K.M. Sun and W. Li (WL00510); Liaoning Province, Huludao city (120°47′33.34″ E, 40°36′14.56″ N), from intertidal sediment of a sand beach, May 2014, X.M. Bian and W. Li (WL02318).

4. Discussion

A systemic survey of fungal resources in Chinese intertidal areas has been implemented by us since 2007, and more than 3000 fungal strains were successfully isolated from thousands of marine algae and sediment samples. Based on morphological and phylogenetic analyses, approximately 600 species have been identified from these fungal strains (unpublished data). Using brine shrimp, agricultural pests, and plant pathogens as targets, we have screened the bioactivities of 181 fungal strains and found more than half of them displayed marked insecticidal and antifungal activities [19]. These results are consistent with the notion that the intertidal zone is an ideal shelter for hosting numerous fungi that can produce diverse metabolic activities [19,50].

Most of the microascaceous fungi have been previously reported as saprobes in seawater and sediments, and on mangrove plants and marine algae [8,9,10]. They can also act as endophytes on marine algae and seaweeds or be isolated from the inner tissue of marine animals such as marine sponges [7,8,9,51] (Table 2). In this study, 18 microascaceous species (48 isolates) were retrieved from Chinese intertidal areas. According to the catalogue shown in Table 2, the number of marine microascaceous species increased from 22 to 33 under our efforts. The newly increased species include six new species (Gamisa sedimenticola, Microascus algicola, M. gennadii, Scedosporium ellipsosporium, S. shenzhenensis, and S. sphaerospermum) and five new records for the marine environment (M. murinus, M. restrictus, M. verrucosus, S. hainanense, and Wardomyces inflatus).

Although only a small proportion of microascaceous fungi were recovered (~3% of the total fungal species recovered), we observed a relatively wide distribution of these fungi across different geographic regions. This distribution ranges from the higher-latitude regions, such as the Liaoning and Hebei provinces, to the lower regions, such as Fujian and Guangdong provinces. Furthermore, diverse substrates were also found to host microascaceous fungi in this study, such as several marine algae and sediments from mudflats, sandy beaches, and gravel beaches. These findings are consistent with our previous investigation using a molecular approach [14] and research based on culturable methods [8,52,53,54,55], This also suggests that microascaceous fungi probably possess a wide geographical distribution, diverse habitats/hosts, and multiple ecological functions in the ocean.

Altogether, our results broaden the information related to the diversity, distribution, and habitat of microascaceous fungi in the marine environment. However, the potential ecological roles and bioactivities of these microascaceous fungi are currently unknown and need further investigation.

Table 2. Records of Microascaceae in the marine environment.

Species	Country/Region/Location	Known Habitats/Hosts	Recorded Database/Reference
Acaulium acremonium	na	na	MF
Cephalotrichum microsporum	China; Europe	unidentified brown algae, green algae, and red algae	WoRMS; this study
Ce. nanum	China; Europe	Intertidal sediment	WoRMS; this study
Ce. purpureofuscum	China	Marine algae Sargassum canfusum	This study
Ce. stemonitis	Europe	na	MF and WoRMS
Gamsia sedimenticola *	China	Intertidal sediment	This study
Microascus algicola *	China	Unidentified brown algae; marine algae Ahnfeltiopsis flabelliformis, Colpomenia sinuosa, Grateloupia filicina	This study
M. croci#	China; Hawaiian, Line, and Phoenix Islands	Marine algae Blidingia minima; coastal sands	[52]; This study
M. gennadii *	China	Intertidal sediment	This study
M. murinus +#	China	Intertidal sediment	This study
M. paisii	na	na	MF
M. restrictus +#	China	Intertidal sediment	This study
M. senegalensis	Senegal	Mangrove soil	[53]
M. trigonosporus	China, Europe; Hawaiian, Line, and Phoenix Islands	Marine algae Cladophora sp., Ulva linza, Gracilaria textorii; intertidal sediment; coastal sand	MF and WoRMS; [52]
M. verrucosus +#	China	Intertidal sediment	This study
Petriella sordida	na	na	MF
Scedosporium boydii	China	Intertidal sediment	MF; this study
S. dehoogii	China	Coastal sediment	[8]
S. ellipsosporium *	China	Intertidal sediment	This study
S. hainanense +	China	Intertidal sediment	This study
S. marinum	India	Decaying woody stem of Suaeda monoica	[54]
S. shenzhenensis *	China	Intertidal sediment	This study
S. sphaerospermum *	China	Intertidal sediment	This study
Scopulariopsis brevicaulis	China, Europe, Croatia; Hawaiian, Line, and Phoenix Islands	Marine sponge Tethya aurantium; marine algae Ulva pertusa; intertidal sediment; coastal sands	MF and WoRMS; [52]; This study
Sc. Brumptii	Hawaiian, Line, and Phoenix Islands	Coastal sands	MF; [52]
Sc. Candida	Egypt	Salt marshes	MF; [55]
Sc. Coprophila	Hawaiian, Line, and Phoenix Islands	Coastal seawater and sands	[52]
Sc. Fusca	Europe	na	WoRMS
Sc. Halophilica	na	na	MF and WoRMS
Sc. Hibernica	na	na	MF
Wardomyces anomalus	na	na	MF
W. inflatus+	China	Intertidal sediment	This study
Yunnania carbonaria	Hawaiian	Coastal seawater	[52]

Notes: new species described in this study are marked as “*”, new records for the marine environment with “+”, and new records for China with “#”. MS = the Marine Fungi database (https://www.marinefungi.org/ (accessed on 30 October 2023)), WoRMS = the World Register of Marine Species database (https://www.marinespecies.org/ (accessed on 30 October 2023)), na = no data available.

Author Contributions

Conceptualization, M.-M.W., W.L. and L.C.; methodology, M.-M.W., S.-Y.Y., Q.L. and Y.-H.T.; software, M.-M.W.; investigation, M.-M.W., Y.Z. and H.-H.M.; resources, M.-M.W., Y.Z. and H.-H.M.; data curation, M.-M.W.; writing—original draft preparation, M.-M.W.; writing—review and editing, W.L. and L.C.; visualization, M.-M.W.; supervision, W.L. and L.C.; project administration, M.-M.W.; funding acquisition, W.L. and L.C. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Science and Technology Fundamental Resources Investigation Program (Grant No. 2019FY100700), the National Natural Science Foundation of China (32100005), and the STU Scientific Research Initiation Grant (NTF23002, NTF23018T).

Informed Consent Statement

Not applicable.

Data Availability Statement

All sequences generated in this study were submitted to GenBank (https://www.ncbi.nlm.nih.gov, accessed on 25 December 2023).

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 2. Fifty percent majority rule consensus tree from a Bayesian analysis based on a four-locus combined dataset (LSU-ITS-tef1-tub2) showing the phylogenetic relationships of genera within the family Microascaceae. The Bayesian posterior probabilities (PP > 0.9) and PhyML bootstrap support values (BS > 50%) are displayed at the nodes (PP/BS). The tree was rooted to Graphium penicillioides (CBS 102632 T). Ex-type cultures are indicated with “T”, epi-type with “ET”, iso-type with “IT”, and neo-type with “NT”. New species introduced in this paper are marked in bold. New records in the marine environment are marked in the blue line and new records in China in the red line. Strains newly isolated in this study are marked in green dots (isolates from algae) and brown dots (isolates from sediment).

Table 1. Strains examined in this study, with information on the source, origin and GenBank accessions of the sequences.

Species	Isolate and Status	Source	Origin	GenBank Accession Number
				LSU	ITS	TEF	TUB
Acaulium acremonium	MUCL 8274 = CBS 104.65 ^ET	Wheatfield soil	Schleswig-Holstein, Germany	KY852479	KY852468	--	--
A. album	CBS 539.85 ^ET	Hair in dung in pole cat	The Netherlands	KY852484	KY852473	--	--
Canariomyces arenarius	CBS 507.74 ^IT	Desert soil	Egypt	KM655383	KM655344	KM655474	MK926898
Ca. microsporus	CBS 276.74 ^IT	Desert soil	Egypt	MH872590	MH860852	MN078437	MK926899
Ca. notabilis	CBS 548.83 ^T	Litter of Phoenix canariensis	Egypt	MH873362	MH861648	MN078432	MK926902
Ca. subthermophilus	CBS 509.74 ^T	Desert soil	Egypt	MH872612	MH860876	MN078436	MK926904
Ca. vonarxii	CBS 160.80 = NHL 2831 ^T	Dried flower of Hibiscus	Sudan	--	--	MN078435	MK926905
Cephalotrichum asperulum	CBS 582.71 ^T	Soil	Buenos Aires, Argentina	LN851007	LN850960	LN851061	LN851114
Ce. brevistipitatum	CBS 157.57 ^T	Tuber	Wageningen, The Netherlands	LN851031	LN850984	LN851084	LN851138
Ce. columnare	CBS 159.66 ^T	Dung of hare	Johannesburg, South Africa	LN851010	LN850963	LN851064	LN851117
Ce. cylindricum	UAMH 1348 ^T	Seed of sorghum	Kansas, USA	LN851012	LN850965	LN851066	LN851119
Ce. dendrocephalum	CBS 528.85 ^T	Cultivated soil	Basrah, Iraq	LN851013	LN850966	LN851067	LN851120
Ce. gorgonifer	UAMH 3585	Mushroom compost	Alberta, Canada	LN851025	LN850978	LN851078	LN851132
Ce. guizhouense	CGMCC 3.18330 ^T	Air from cave	Guizhou, China	MF419758	MF419788	MF419728	MF434549
Ce. hinnuleum	CBS 289.66 ^T	Dung of deer	Tasmania, Australia	LN851032	LN850985	LN851085	LN851139
Ce. laeve	CGMCC 3.18329 ^T	Limestone from cave	Guizhou, China	MF419778	MF419808	MF419748	MF434569
Ce. microsporum	CBS 523.63 ^ET	Wheatfield soil	Schleswig-Holstein, Germany	LN851014	LN850967	LN851068	LN851121
	WL00192	Unidentified red algae	Qingdao, Shandong, China	OR339938	OR339892	OR347703	OR338658
	WL00303	Unidentified green algae	Weihai, Shandong, China	OR339939	OR339893	OR347704	OR338659
	WL00305	Unidentified green algae	Weihai, Shandong, China	OR339940	OR339894	OR347705	OR338660
	WL00350	Unidentified brown algae	Weihai, Shandong, China	OR339941	OR339895	OR347706	OR338661
Ce. nanum	CBS 191.61 ^ET	Dung of deer	Surrey, England	LN851016	LN850969	LN851070	LN851123
	WL03115	Intertidal sediment	Ningbo, Zhejiang, China	OR339945	OR339899	OR347710	OR338662
	WL03362	Intertidal sediment	Ningbo, Zhejiang, China	OR339946	--	OR347711	--
Ce. oligotriphicum	CGMCC 3.18328 ^T	Limestone from cave	Guizhou, China	MF419771	MF419801	MF419741	MF434562
Ce. purpureofuscum	UAMH 9209	Indoor air	British Columbia, Canada	LN851018	LN850971	LN851072	LN851125
	WL06350	Sargassum canfusum	Shenzhen, Guangdong, China	OR339942	OR339896	OR347707	OR338664
	WL06351	Sargassum canfusum	Shenzhen, Guangdong, China	OR339943	OR339897	OR347708	OR338665
	WL02022	Sargassum canfusum	Shenzhen, Guangdong, China	OR339950	OR339898	OR347709	OR338663
Ce. stemonitis	CBS 103.19 ^NT	Seed	Wageningen, Netherlands	LN850952	LN850951	LN850953	LN850954
Ce. verrucisporum	CBS 187.78	Sand dune soil	Katijk, The Netherlands	LN851033	LN850986	LN851086	LN851140
Gamsia aggregata	CBS 251.69 ^ET	Dung of carnivore	USA	LM652500	LM652378	--	--
G. columbina	CBS 233.66 ^ET	Sandy soil	Giessen, Germany	LN851039	LN850990	LN851092	LN851146
G. dimera	CBS 235.66 = ATCC 18887 = IMI 117371 = MUCL 6388 ^T	Wheatfield soil	Schleswig-Holstein, Germany	--	MH858785	--	--
G. kooimaniorum	CBS 143185 ^T	Garden soil	The Netherlands	--	NR_159824	--	--
G. sedimenticola	WL02722 = CGMCC3.25342 ^T	Intertidal sediment	Qingdao, Shandong, China	OR339947	OR339900	OR347712	OR338666
	WL06358	Intertidal sediment	Qingdao, Shandong, China	OR339948	OR339901	OR347713	OR338667
	WL06359	Intertidal sediment	Qingdao, Shandong, China	OR339949	OR339902	OR347714	OR338668
G. simplex	CBS 546.69 ^IT	Milled Oryza sativa	Japan	LM652501	LM652379	LN851094	LN851148
Graphium penicillioides	CBS 102632 ^T	Populus nigra	Czech Republic	KY852485	KY852474	--	--
Kernia columnaris	CBS 159.66 = IMI 116691 ^T	Dung of hare	South Africa	KY852486	KY852475	KY852478	KY852477
K. nitida	CBS 282.52 = NBRC 8200	Chrysolina sanguinolenta	France	KY852487	KY852476	--	--
Microascus algicola	WL00347	Unidentified brown algae	Weihai, Shandong, China	OR339954	OR339907	OR347719	OR338669
	WL00633	Colpomenia sinuosa	Qingdao, Shandong, China	OR339955	OR339908	OR347720	OR338670
	WL01268 = CGMCC3.25343 ^T	Grateloupia filicina	Qingdao, Shandong, China	OR339962	OR339909	OR347721	OR338672
	WL01021	Ahnfeltiopsis flabelliformis	Qingdao, Shandong, China	OR339957	OR339910	OR347722	OR338671
M. campaniformis	CBS 138126 = UTHSC 10-565 = FMR 12343 ^T	Human BAL	USA	HG380495	LM652391	HG380418	LM652606
M. cinereus	FMR 12217 = UTHSC 10-2805 ^NT	Human BAL	USA	--	LM652397	--	LM652611
M. croci	CBS 158.44 = MUCL 9002 ^T	Crocus sp.	Lisse, The Netherlands	LM652508	LM652407	LM652560	LM652621
	WL02042	Blidingia minima	Qingdao, Shandong, China	OR339982	OR339903	OR347715	OR338673
M. expansus	CBS 138127 = UTHSC 06-4472 = FMR 12266 ^T	Human sputum	USA	HG380492	LM652410	HG380415	LM652624
M. gennadii	WL02353 = CGMCC3.25344 ^T	Intertidal sediment	Unknown	OR339971	OR339904	OR347716	OR338674
	WL06354	Intertidal sediment	Unknown	OR339952	OR339905	OR347717	OR338675
	WL06355	Intertidal sediment	Unknown	OR339953	OR339906	OR347718	OR338676
M. gracilis	CBS 369.70 ^IT	Food	Japan	HG380467	LM652412	HG380390	LM652625
M. hyalinus	CBS 766.70 ^IT	Dung of cow	USA	LM652513	LM652418	LM652564	LM652631
M. intricatus	CBS 138128 = UTHSC 07-156 = FMR 12264 ^T	Human BAL	USA	HG380496	LM652419	HG380419	LM652632
M. longirostris	CBS 196.61 = MUCL 9058 ^NT	Wasp’s nest	Maine, USA	LM652515	LM652421	LM652566	LM652634
M. murinus	CBS 830.70 = IHEM 18567 ^T	Composed municipal waste	Giessen, Germany	HG380481	LM652424	HG380404	LM652637
	WL05483	Intertidal sediment	Qingdao, Shandong, China	OR339959	OR339912	OR347724	OR338678
	WL03684	Intertidal sediment	Yantai, Shandong, China	OR339958	OR339911	OR347723	OR338677
M. paisii	UTHSC 07-639 = FMR 12263	Human BAL	USA	HG380451	LM652425	HG380374	LM652638
M. pyramidus	CBS 212.65 ^IT	Desert soil	California, USA	HG380435	LM652439	HG380358	LM652652
M. restrictus	CBS 138277 = UTHSC 09-2704 = FMR 12227 ^T	Human left hallux	USA	HG380494	LM652440	HG380417	LM652653
	WL02392	Intertidal sediment	Huludao, Liaoning, China	--	--	OR347725	OR338679
M. senegalensis	CBS 277.74 = IHEM 18561 ^T	Mangrove soil	Senegal	LM652523	LM652441	LM652574	LM652654
M. sparsimycelialis	LC12478 ^T	Animal faeces	Laibin, Guangxi, China	--	--	MK336046	MK336124
M. superficialis	LC12597 ^T	Animal faeces	Laibin, Guangxi, China	--	--	MK336048	MK336126
M. trigonosporus	CBS 218.31 ^T	na	USA	HG380436	LM652443	HG380359	LM652655
	WL00670	Cladophora sp.	Qingdao, Shandong, China	OR339961	OR339916	OR347729	OR338683
	WL01853	Ulva linza	Qingdao, Shandong, China	OR339963	OR339917	OR347730	OR338684
	WL01882	Gracilaria textorii	Qingdao, Shandong, China	OR339944	OR339918	OR347731	OR338685
	WL02833	Intertidal sediment	Qingdao, Shandong, China	OR339964	OR339919	OR347732	OR338686
M. trigonus	LC12520 ^T	Soil	Guilin, Guangxi, China	--	--	MK336052	MK336130
M. verrucosus	CBS 138278 = UTHSC 10-2601 = FMR 12219 ^T	Human, BAL fluid	USA	HG380493	LM652446	HG380416	LM652658
	WL02828	Intertidal sediment	Dongying, Shandong, China	OR339965	OR339920	OR347733	OR338687
Microascus sp.	WL01046	Grateloupia filicina	Qingdao, Shandong, China	OR339956	OR339913	OR347726	OR338680
	WL06352	Grateloupia filicina	Qingdao, Shandong, China	--	OR339914	OR347727	OR338681
	WL06353	Grateloupia filicina	Qingdao, Shandong, China	--	OR339915	OR347728	OR338682
Parascedosporium tectonae	CBS 127.84 ^T	Human BAL	USA	EF151332	--	--	--
Petriella sordida	CBS 124169	Corner of a bathroom	The Netherlands	AY281099	GQ426957	--	--
Pithoascus ater	CBS 400.34 = IHEM 18608 ^T	na	na	LM652526	LM652447	LM652576	LM652659
Pi. exsertus	CBS 819.70 ^T	Megachile willoughbiella	Tastrup, Denmark	LM652528	LM652449	LM652578	LM652661
Pi. intermedius	CBS 217.32 ^T	Root of Fragaria vesca	North Carolina, USA	LM652529	LM652450	LM652579	LM652662
Pi. nidicola	CBS 197.61 ^ET	Dipodomys merriami	Utah, USA	LM652530	LM652451	LM652580	LM652663
Pi. stoveri	CBS 176.71 ^T	Root of Beta vulgaris	Ohio, USA	LM652532	LM652453	LM652581	LM652664
Pseudoscopulariopsis asperispora	LC12445 ^T	Animal faeces	Guilin, Guangxi, China	--	--	MK336064	MK336142
Ps. hibernica	UAMH 2643 = ATCC 16690	Soil	Ireland	LM652533	LM652454	LM652582	LM652665
Ps. schumacheri	CBS 435.86 ^NT	Soil	Puerto de la Quesera, Spain	LM652534	LM652455	LM652583	LM652666
Rhinocladium lesnei	CBS 108.10	Foot of human	France	MH866122	MH854594	--	--
Scedosporium angustum	CBS 254.72 ^ET	Sewage half digestion tank	Ohio, USA	--	AJ888414	--	AJ889604
S. apiospermum	FMR 8619 ^ET	Keratitis of huma	Brazil	--	NR_130664	--	AJ889584
S. aurantiacum	IMI 392886 ^T	Ulcer on ankle of human	Spain	--	AJ888440	--	AJ889597
S. boydii	CBS 101.22 = IMI 015407 = JCM 7441 = NCPF 2216 = UAMH 3982 ^T	Mycetoma	USA	EF151320	KT008518	KT069589	KT008455
	WL02794	Intertidal sediment	Qingdao, Shandong, China	OR339968	OR339923	OR347736	OR338688
	WL05602	Intertidal sediment	Yantai, Shandong, China	OR339969	OR339924	OR347737	OR338689
	WL05951	Intertidal sediment	Tianjin, China	OR339970	OR339925	OR347738	OR338690
S. cereisporum	FMR 12996 ^ET	Wastewater sludge	Mûrs-Erignés, France	--	KJ599660	--	KJ599659
S. dehoogii	CBS 117406 ^ET	Garden soil	Barcelona, Spain	--	KT163400	--	KT163401
S. desertorum	CBS 489.72 ^ET	Salt-marsh soil	Kuwait	--	--	--	AM409106
S. ellipsoideum	CBS 418.73 ^ET	Soil	Tayikistán	--	AJ888426	--	AJ889595
S. ellipsosporium	WL02370 = CGMCC3.25345 ^T	Intertidal sediment	Shenzhen, Guangdong, China	OR339973	OR339926	OR347739	OR338692
	WL02793	Intertidal sediment	Qingdao, Shandong, China	OR339972	OR339927	OR347740	OR338693
S. fusoideum	CBS 106.53 ^ET	Goat dung Aligarh	India	--	AJ888428	--	AJ889601
S. haikouense	CGMCC 3.20468 = GZUIFR 21.833 ^T	Green-belt soil	Haikou, Hainan, China	--	MZ469289	--	MZ488563
S. hainanense	CGMCC 3.20469 = GZUIFR 21.829 ^T	Green-belt soil	Sanya, Hainan, China	--	MZ469285	--	MZ488559
	WL05931	Intertidal sediment	Yancheng, Jiangsu, China	OR339967	OR339922	OR347735	OR338691
S. minutisporum	FMR 4072 ^ET	River sediment Tordera river	Spain	--	AJ888384	--	AJ889592
S. multisporum	CGMCC 3.20470 = GZUIFR 21.830 ^T	Green-belt soil	Huaihua, Hunan, China	--	MZ469286	--	MZ488560
S. rarisporum	GZUIFR-G79 ^T	Root soil of Wodyetia bifurcata	Guigang, Guangxi, China	--	KX790702	--	--
S. shenzhenensis	WL02375 = CGMCC3.25346 ^T	Intertidal sediment	Shenzhen, Guangdong, China	OR339960	OR339928	OR347741	OR338694
	WL06356	Intertidal sediment	Shenzhen, Guangdong, China	OR339974	OR339929	OR347742	OR338695
	WL06357	Intertidal sediment	Shenzhen, Guangdong, China	OR339975	OR339930	OR347743	OR338696
S. sphaerospermum	WL02796 = CGMCC3.25347 ^T	Intertidal sediment	Qingdao, Shandong, China	OR339976	OR339931	OR347744	OR338698
	WL06360	Intertidal sediment	Qingdao, Shandong, China	OR339977	OR339932	OR347745	OR338699
	WL06361	Intertidal sediment	Qingdao, Shandong, China	OR339978	OR339933	OR347746	OR338700
Scedosporium sp.	WL02426	Intertidal sediment	na	OR339966	OR339921	OR347734	OR338697
Scopulariopsis africana	CBS 118736 ^T	Mud, salt pan	South Africa	KX924040	KX923954	KX924176	KX924388
Sc. albida	CBS 119.43 ^T	Soil	The Netherlands	LN850849	LN850800	LM652592	LN850897
Sc. alboflavescens	CBS 399.34 ^T	Diseased skin	Austria	LM652539	KX923956	KX924179	JQ434537
Sc. asperula	CBS 853.68	Compost soil	Germany	JQ434669	LM652461	JQ434621	JQ434558
Sc. brevicaulis	MUCL 40726 ^T	Indoor air	Alberta, Canada	HG380440	LM652465	HG380363	LM652672
	WL00657	Ulva pertusa	Qingdao, Shandong, China	OR339979	OR339934	OR347747	OR338701
	WL03882	Intertidal sediment	Ningde, Fujian, China	OR339980	OR339935	OR347748	OR338702
Sc. candida	MUCL 40743 ^ET	Indoor air	Canada	HG380458	LM652484	HG380381	LM652690
Sc. caseicola	CBS 480.62 ^T	Cheese coating	The Netherlands	KX924041	KX924020	KX924247	KX924454
Sc. cordiae	FMR 12338 ^T	Human finger	USA	HG380499	LM652491	HG380422	LM652673
Sc. flava	CBS 207.61 = MUCL 9031 ^NT	Cheese	UK	HG380464	LM652493	HG380387	LM652697
Sc. macurae	CBS 506.66 ^T	Chicken litter	Canada	LN850854	LN850805	KX924250	LN850902
Sc. sexualis	CBS 250.64 ^T	Oryza sativa	Burma	KX924042	KX924024	KX924251	KX924458
Sc. soppii	UAMH 9169 ^T	Wood of Populus tremuloides	Alberta, Canada	LM652552	LM652495	LM652595	LM652698
Wardomyces anomalus	CBS 299.61 ^ET	Air cell of egg	Ontario, Canada	MH869626	MH858058	LN851095	LN851149
W. giganteus	CBS 746.69 ^T	Insect frass in dead log	Ontario, Canada	MH871180	MH859408	LN851096	LN851150
W. inflatus	CBS 216.61 ^IT	Wood, Acer sp.	Quebec, Canada	LM652553	LM652496	LN851098	--
	WL02318	Intertidal sediment	Huludao, Liaoning, China	OR339951	OR339937	OR347750	OR338704
	WL00510	Intertidal sediment	Weihai, Shandong, China	OR339981	OR339936	OR347749	OR338703
W. ovalis	CBS 234.66 = IMI 117372 = MUCL 6031 ^T	Wheatfield soil	Schleswig-Holstein, Germany	LN851050	MH858784	LN851101	LN851155
W. pulvinatus	CBS 112.65 ^IT	Salt marsh	Cheshire, England	MH870142	MH858508	LN851102	LN851156
Wardomycopsis dolichi	LC12503 ^T	Soil	Guilin, Guangxi, China	MK329043	MK329138	MK336073	--
Wa. fusca	LC12476 ^T	Soil	Guilin, Guangxi, China	MK329047	MK329142	MK336077	MK336148
Wa. humicola	CBS 487.66 ^T	Soil	Ontario, Canada	LM652554	LM652497	--	--
Wa. inopinata	FMR 10305	Soil	Myanmar	LM652555	LM652498	--	--
Wa. litoralis	CBS 119740 ^T	Beach soil	Castellon, Spain	LN851055	LN851000	LN851107	LN851161
Wa. longicatenata	CGMCC 3.17947 ^T	Air	Guizhou, China	KU746756	KU746710	KX855255	KU746801
Yunnania carbonaria	CBS 205.61 ^T	Soil	Panama	HG380462	KX923820	KX924044	KX924254
Y. penicillata	CBS 130296 ^T	Moulded pork sample	China	KY659809	JN831361	KY659808	KY659807
Y. smithii	CBS 855.68 ^T	Garden soil	Germany	KX924028	KX923822	KX924046	KX924256

Notes: ^T = ex-type, ^ET = epi-type, ^IT = iso-type, ^NT = neo-type. Sequences newly generated in this study are marked in bold.

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Wang, M.-M.; Yang, S.-Y.; Li, Q.; Zheng, Y.; Ma, H.-H.; Tu, Y.-H.; Li, W.; Cai, L. Microascaceae from the Marine Environment, with Descriptions of Six New Species. J. Fungi 2024, 10, 45. https://doi.org/10.3390/jof10010045

AMA Style

Wang M-M, Yang S-Y, Li Q, Zheng Y, Ma H-H, Tu Y-H, Li W, Cai L. Microascaceae from the Marine Environment, with Descriptions of Six New Species. Journal of Fungi. 2024; 10(1):45. https://doi.org/10.3390/jof10010045

Chicago/Turabian Style

Wang, Meng-Meng, Shi-Yu Yang, Qi Li, Yao Zheng, He-He Ma, Ye-Hui Tu, Wei Li, and Lei Cai. 2024. "Microascaceae from the Marine Environment, with Descriptions of Six New Species" Journal of Fungi 10, no. 1: 45. https://doi.org/10.3390/jof10010045

APA Style

Wang, M. -M., Yang, S. -Y., Li, Q., Zheng, Y., Ma, H. -H., Tu, Y. -H., Li, W., & Cai, L. (2024). Microascaceae from the Marine Environment, with Descriptions of Six New Species. Journal of Fungi, 10(1), 45. https://doi.org/10.3390/jof10010045

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Microascaceae from the Marine Environment, with Descriptions of Six New Species

Abstract

1. Introduction

2. Materials and Methods

2.1. Sample Collection and Fungal Isolation

2.2. Morphological Observation

2.3. DNA Extraction and Amplification

2.4. Phylogenetic Analyses

3. Results

3.1. Phylogenetic Analyses

3.2. Species List and Taxonomy

4. Discussion

Author Contributions

Funding

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

References

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