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Article

Untapped Diversity of Termite-Associated Ophiocordyceps and a New Species from China

by
Quan-Ying Dong
1,*,
Jin-Lin Liu
1,
Chang-Kun Liu
1,
Chao Hu
2,
Jun Yang
1,
Wan-Li Xu
1 and
Cheng-Dong Xu
1
1
College of Agronomy, Chuxiong Normal University, Chuxiong 675000, China
2
Key Laboratory of East China Plant Conservation and Utilization, National Forestry and Grassland Administration, Shanghai Chenshan Botanical Garden, Shanghai 201602, China
*
Author to whom correspondence should be addressed.
Diversity 2026, 18(6), 313; https://doi.org/10.3390/d18060313
Submission received: 6 April 2026 / Revised: 18 May 2026 / Accepted: 21 May 2026 / Published: 23 May 2026
(This article belongs to the Section Phylogeny and Evolution)
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Abstract

Termite-associated Ophiocordyceps species remain understudied despite the high diversity of the genus. Here we describe Ophiocordyceps minuta (holotype CXAC 0026) from termites (Termitidae, Macrotermitinae) collected in Yunnan, China. Phylogenetic analyses based on nrLSU (nuclear large subunit ribosomal RNA), tef1-α (translation elongation factor 1-alpha), and rpb2 (RNA polymerase II second largest subunit) sequences resolve this fungus as a distinct lineage. Notably, deep genetic divergence (65 bp in tef1-α) between the two ex-type strains of the allied O. fusiformis (BCC 93025 and BCC 93026) reveals cryptic diversity within that nominal species. Beyond the new species, a morphological assessment of termite-associated Ophiocordyceps indicates that perithecial immersion status, ascospore morphology, and conidial features are the most taxonomically valuable characters for this ecological group. These findings expand the known diversity in southwest China and underscore the importance of integrating phylogenetic data with key morphological traits for species delimitation in under-explored habitats.

1. Introduction

The genus Ophiocordyceps Petch (Ophiocordycipitaceae, Hypocreales) ranks among the most species-rich lineages of entomopathogenic fungi, with over 370 accepted names distributed globally (www.indexfungorum.org, accessed on 15 March 2026). Unlike their close relatives in Cordyceps sensu stricto, which typically produce brightly coloured, fleshy stromata, Ophiocordyceps species are characterized by dark-pigmented, wiry to pliant stromata and are associated with anamorphic genera including Hirsutella, Hymenostilbe, Paraisaria, and Syngliocladium [1,2,3]. Members of this genus exploit an exceptionally broad range of insect hosts, attacking various life stages across Blattodea, Coleoptera, Diptera, Hemiptera, Hymenoptera, Lepidoptera, Megaloptera, Neuroptera and Odonata [3,4,5,6,7]. However, the association with Blattodea is not restricted to termites; several Ophiocordyceps species, including the type species O. blattae, as well as O. asiatica, O. cf. blattae, and O. salganeicola, have been confirmed from non-termite Blattodea [8,9]. This ecological diversity is matched by morphological plasticity: perithecia may be superficial, immersed, or partially embedded, while ascospores either remain intact as multiseptate units or dissociate into individual part-spores [2,10].
Despite this overall diversity, the distribution of Ophiocordyceps species across host groups is markedly uneven [11,12,13]. Certain host associations, particularly with ants and beetle larvae, have yielded numerous described species, while others remain poorly documented [14,15]. Termites (Blattodea: Termitidae) represent one such understudied host group [16]. Termites were historically treated as a separate order, Isoptera, but molecular phylogenetic studies have firmly placed them within Blattodea [17], a placement further corroborated by recent genomic-scale analyses [18]. Termitidae is the most speciose termite family, comprising approximately 2000 described species [19]. As eusocial insects inhabiting subterranean nests in tropical and subtropical ecosystems worldwide, termites play critical roles in decomposition and nutrient cycling [20]. Their constant exposure to soil-borne microorganisms creates opportunities for fungal pathogens, yet the diversity of termite-associated Ophiocordyceps has only recently begun to receive sustained attention [8,21,22,23].
Historical records of termite-pathogenic Ophiocordyceps were limited to three species described over a span of six decades: O. bispora from East Africa, O. koningsbergeri from Java, and O. octospora from Mexico [24,25,26]. Following these early reports, progress remained slow until intensive surveys in Thailand during the past decade uncovered 11 additional species from forests [8,27]. The remaining species have been documented from other East and Southeast Asian localities: O. globiperitheciata, O. longistipes, O. ovatospora and O. taiwanensis from China, and O. puluongensis from Vietnam [21,22,23,28]. Thus, a total of 20 Ophiocordyceps species have been reported from termite hosts worldwide to date, not including the new species described in the present study [2,8,21,23,24,25,26,29]. These discoveries demonstrated that termite-pathogenic lineages harbor substantially greater diversity than previously recognized and suggested that similar surveys in other under-explored regions would likely yield additional taxa.
Southwest China, particularly Yunnan Province, has emerged as a promising area for discovering novel Cordyceps sensu lato species [30,31]. The region’s complex topography, elevational gradients, and high forest cover support diverse insect communities and their associated fungal pathogens [32,33]. Recent investigations have documented multiple new Ophiocordyceps taxa from Yunnan across various insect hosts, including two termite-associated species described in the past two years [21,22]. These findings indicate that the termite-pathogenic Ophiocordyceps diversity in this region remains incompletely sampled, with additional species awaiting discovery through continued field efforts. In the present study, we describe the new termite-associated species O. minuta using morphological and multigene phylogenetic evidence, reassess the key morphological characters for delimiting termite-associated Ophiocordyceps, and discuss the group’s diversity in southwest China.

2. Materials and Methods

2.1. Specimen Collection

Fungal specimens were collected from ground-dwelling termites (Termitidae, Macrotermitinae) in Taiyanghe National Nature Reserve, Yunnan Province, China. Specimens were carefully removed to preserve host integrity, placed in sterile plastic containers, and transported to the laboratory. Upon arrival, they were examined under a stereomicroscope (OLYMPUS SZ61, Olympus Corporation, Tokyo, Japan), cleaned of surface debris, assigned accession numbers CXAC 0026–0027, and air-dried. Hosts were identified using morphological characters and with guidance from termite taxonomists; finer identification was precluded by the condition of the fungus-infected specimens. Voucher specimens are deposited at the College of Agronomy Herbarium (CXAC), Chuxiong Normal University, China, for taxonomic identification and future studies.

2.2. Morphological Characterization

Specimen data, including host association and geographic origin, were documented. Sexual structures (perithecia, asci, ascospores, part-spores) were mounted in lactophenol cotton blue and measured under an Olympus BX53 compound microscope (Olympus Corporation, Tokyo, Japan). For each structure, 20–50 measurements were recorded, and the range was calculated.

2.3. Extraction of DNA, Polymerase Chain Reaction (PCR), and Molecular Sequencing

Genomic DNA was extracted from fungal mycelia using a commercial plant DNA isolation kit (FOREGENE, Chengdu, China) and amplified via polymerase chain reaction (PCR) for three genetic regions: nrLSU, tef1-α, and rpb2, with primers as following: the LSU region was amplified with the primer pair LR0R/LR5 [34,35], and the tef1-α and rpb2 genes using the primer sets EF1α-EF/EF1α-ER [2,36] and RPB2-5′F/RPB2-5′R [2,36] respectively. Each 25 μL PCR contained 2.5 μL of 10× buffer (2 mM Mg2+; Transgen Biotech, Beijing, China), 0.25 μL of Taq polymerase, 2 μL of dNTPs (2.5 mM each), 1 μL of DNA template (~500 ng/μL), 1 μL of each primer (10 μM), and 17.25 μL of deionized water. Amplification was conducted in a BIO-RAD T100™ Thermal Cycler following the gene-specific thermal cycling protocols detailed in Table 1. Successful amplification was verified by gel electrophoresis; the resulting amplicons were then purified prior to bidirectional Sanger sequencing at the Beijing Genomics Institute (Shenzhen, China) with the same PCR primers.

2.4. Phylogenetic Analyses

To establish the phylogenetic placement of our taxa, we analyzed a three-gene matrix (nrLSU, tef1-α, and rpb2). Newly obtained sequences were confirmed via BLAST searches and aligned with reference sequences from GenBank (Table 2) using MAFFT v7.526 (L-INS-i strategy) (http://mafft.cbrc.jp/alignment/server/, accessed 15 March 2026) and refined manually in BioEdit v7.7.1. These alignments were concatenated into a supermatrix with FASconCAT-G v1.06 [37]. The partition homogeneity test in PAUP v5.0 (1000 reps, p > 0.01) revealed no significant conflict between gene partitions. Optimal partitioning schemes and models of evolution were selected under the BIC criterion using PartitionFinder2 v2.0.0 (greedy algorithm) [38]. Phylogenetic relationships were then inferred using two complementary methods. First, a Maximum Likelihood (ML) analysis was performed in IQ-TREE v3.0.1 under the optimal partition scheme (GTR + G + I model), with nodal support assessed via 1000 ultrafast bootstrap replicates [39]. Second, Bayesian Inference (BI) was conducted in MrBayes v3.2.7 using the GTR + G + I model (selected by MrModeltest v2.2) [40]. MCMC chains were run for 5 million generations, sampling every 1000 generations [41]. Convergence (ESS > 200) was verified in Tracer v1.7.2, after which the first 25% of samples were discarded as burn-in [42]. The resulting trees were visualized and annotated in FigTree v1.4.4 (https://tree.bio.ed.ac.uk/software/figtree/ (accessed on 18 may 2026), with the final artwork prepared in Adobe Illustrator CS6 according to the standards of Xie et al. [43].

3. Results

3.1. Phylogenetic Analyses

Phylogenetic analyses of Ophiocordyceps were based on a dataset of 92 sequences (Table 2). Tolypocladium inflatum OSC 71235 and T. ophioglossoides CBS 100239 were used as the outgroups. The final concatenated matrix comprised 2927 characters (including gaps), with three partitions: nrLSU 908 bp, tef1-α 957 bp, and rpb2 1062 bp. Both Bayesian inference (BI) and maximum likelihood (ML) analyses produced congruent trees, recovering Ophiocordyceps as distinct, well-supported clades (Figure 1). The new species Ophiocordyceps minuta formed a distinct lineage within a well-supported clade, clearly separated from its close relatives (Figure 1).

3.2. Taxonomy

Ophiocordyceps minuta Q.Y. Dong & C. D. Xu, sp. nov.
Figure 2
MycoBank no: 862337
Etymology: minuta = minute, referring to the distinctly small size of the perithecia, a key diagnostic feature that distinguishes this species from its closely related congeners.
Holotype: China, Yunnan Province, Pu’er City, Simao District, Taiyanghe National Nature Reserve, on termite (Termitidae, Macrotermitinae), 15 August 2025, Quanying Dong (holotype CXAC 0026).
Stromata morph: Stromata arising from the segment between the prothorax and mesothorax of termite hosts buried in soil, solitary, simple, cylindrical, flexible, leathery, 6–14 cm long, 0.5–1.0 mm wide, brown to yellowish brown. Fertile parts cylindrical, yellowish brown, 3.5–5.5 cm long, 4–5 mm wide, located on the upper part of the stromata, with a spinous surface and a sterile apical tip 13–28 mm long, 0.5–1.0 mm wide. Perithecia superficial, pale yellow when young, turning brown at maturity, ovoid to flask-shaped, 151.5–221 × 115–188 µm, densely and irregularly scattered over the mid portion of the stromata. Ascospores dimorphic: type I fusiform, 80–92.5 × 5.0–6.5 µm, whole, hyaline, multiseptate, septa 8–14.5 µm long; type II vermiform or lanceolate, 32.5–52.5 × 2.0–4.5 µm.
Asexual morph: Undetermined.
Host: Parasitic on termites buried in soil.
Known distribution: Yunnan Province, China.
Additional specimens examined: China, Yunnan Province, Pu’er City, Simao District, Taiyanghe National Nature Reserve, on termite (Termitidae, Macrotermitinae), 15 August 2025, Quanying Dong (paratype CXAC 0027).
Commentary: The diagnostic morphology of Ophiocordyceps minuta conforms to the generic concept of Ophiocordyceps. The species produces dimorphic ascospores comprising two types: cylindrical, with pointed ends, and vermiform. The species can be distinguished by the following combination of morphological characteristics: perithecia distinctly small (151.5–221 × 115–188 µm), which is the smallest among its closely related congeners (Table 3); host specificity to termites (Termitidae, Macrotermitinae); producing dimorphic ascospores, type I fusiform and multiseptate (80–92.5 × 5.0–6.5 µm), type II vermiform or lanceolate (32.5–52.5 × 2.0–4.5 µm); and asci with conspicuous apical caps (3.5–5.5 μm high, 6.5–8.0 μm wide).
Our multi-locus phylogenetic data (Figure 1) indicate that Ophiocordyceps minuta is related to O. fusiformis Tasan. et al. and O. longistipes Y.B. Wang et al. However, it forms a distinct clade separate from these taxa (Figure 1). Morphologically, O. minuta differs from related species in the following ways. Ophiocordyceps fusiformis, a species described from Thailand, also similar to O. minuta in appearance, has relatively larger perithecia 300–360 × 180–270 µm, longer asci 141–227 × 7–15 µm and shorter ascospores 6–78 × 5–6.5 µm, shorter septa 5–12 (19) µm long [27]. Moreover, in our phylogenetic tree, the two strains of O. fusiformis (BCC 93025 and BCC 93026) did not form a single clade but instead separated into two distinct branches. Comparison of the tef1-α gene sequences between the two strains revealed a 65 bp difference (out of a total length of 903 bp). Ophiocordyceps longistipes can be distinguished from O. minuta by its grayish white to yellowish brown with relatively longer stromata, larger perithecia measuring 390–420 × 295–350 µm; filiform asci, 160–195 × 4.5–6.5 µm; and filiform shorter ascospores 70–85 × 3.5–4.5 µm [21].

3.3. Morphological Characters and Their Taxonomic Significance in Termite-Associated Ophiocordyceps Species

Analysis of termite-associated Ophiocordyceps (Table 3) shows that morphological characters differ in taxonomic usefulness, a pattern seen in other Ophiocordycipitaceae. Host association is uniform (all on termites, Isoptera), so it does not help distinguish species but defines the group as a specialized ecological guild. Stromatal characters provide moderate to high resolution. Stromatal color (orange-brown, brown, yellowish-brown, grayish-white to yellowish-brown, or pale to red-brown) aids species recognition. Stromatal size shows clear extremes: diminutive in O. octospora and O. taiwanensis, elongate in O. asiatica, O. longistipes, O. pseudocommunis, and O. pseudorhizoidea. Multiple stromata (O. bispora: 20–30; O. globiperitheciata: 2–5) are also diagnostic. Perithecial immersion status (superficial, immersed, or pseudo-immersed) reliably separates species, as does perithecial size (large in O. communis and O. pseudocommunis; small in O. ovatospora and O. khokpasiensis). Ascus characters are less informative. Ascospores vary strikingly: most species have filiform, septate, whole ascospores; exceptions include elliptical to ellipsoidal–fusiform, non-disarticulating ascospores (O. bispora, O. octospora) and dimorphic ascospores (O. minuta), the latter being a unique autapomorphy. Asexual morphs (Hirsutella- or Hymenostilbe-like), conidiogenous cells (monophialidic or polyphialidic), and conidia (fusiform, globose, oval, or citriform) offer additional characters. In summary, perithecial immersion status, ascospore architecture, and conidial features are the most taxonomically valuable traits.

4. Discussion

The description of Ophiocordyceps minuta from termite hosts in Yunnan Province adds a new species to the entomopathogenic fungal diversity of Southeast Asia. The morphological and phylogenetic data presented here contribute to ongoing discussions on species delimitation, ascospore variation, and biogeography within the genus Ophiocordyceps.
Taxonomic implications of O. fusiformis strain divergence. In our phylogenetic analysis, the two ex-type strains of O. fusiformis (BCC 93025 and BCC 93026) occupied distinct positions (Figure 1), with a 65 bp divergence in the tef1-α region. Although these strains were originally described as conspecific from Thailand [27], this level of sequence divergence suggests that the current concept of O. fusiformis may encompass multiple species. Confirming species boundaries would require re-examination of type material and additional collections from the type locality. This finding reinforces the importance of including multiple representatives per putative species in phylogenetic studies, as single-strain typification may not fully capture intraspecific variation or detect cryptic diversity [48,60].
Ophiocordyceps minuta produces two morphologically distinct ascospore types. The vermiform Type II spores (32.5–52.5 × 2.0–4.5 µm) are similar in size and shape to microconidia produced by some Hirsutella species associated with termite-pathogenic Ophiocordyceps [8,21,22]. Whether the two ascospore types differ in biological function remains unknown; infection assays comparing their relative infectivity would help clarify their respective roles in the life cycle of this species.
Biogeographic patterns. The discovery of O. minuta in Yunnan adds to the growing number of termite-associated Ophiocordyceps species recorded from the Indochinese Peninsula, including recent reports from Thailand and Vietnam [21,22,27]. Multiple species from this ecological group have now been documented in the Mekong River basin and adjacent areas [6]. The 65 bp divergence observed between the two O. fusiformis strains, both collected in Thailand, further indicates that sequence variation exists within what is currently recognized as a single species. This observation highlights the need for more intensive sampling across the region, particularly collecting multiple specimens per morphospecies and from different host colonies [61].
Ophiocordyceps minuta is a morphologically and phylogenetically distinct species. The genetic divergence detected among O. fusiformis strains and the presence of dimorphic ascospores in O. minuta point to several directions for future research, including taxonomic revision of the O. fusiformis complex and functional studies of ascospore variation in O. minuta. These findings underscore the value of continued exploration of termite-associated Ophiocordyceps in Southeast Asia.

Author Contributions

Conceptualization, Q.-Y.D.; methodology, J.-L.L. and C.-K.L. validation, C.H. and W.-L.X.; formal analysis C.-D.X. and J.Y.; investigation, Q.-Y.D.; writing—review and editing, Q.-Y.D. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Joint Program of Basic Research for Provincial Undergraduate Schools, Yunnan Provincial Department of Science and Technology (202401BA070001-139), the Ph.D. Research Start-Up Project of Chuxiong Normal University (BSQD2307), and the 2025 Self-funded Science and Technology Project of Chuxiong Prefecture (cxzc2025019).

Institutional Review Board Statement

Not applicable for studies not involving humans or animals.

Data Availability Statement

Data are contained within the article.

Conflicts of Interest

The authors declare no conflicts of interest.

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Diversity 18 00313 g001
Figure 1. Molecular phylogenetic analyses using the ML and BI based on combined nrLSU, tef1-α, and rpb2 sequence data. Statistical support values (BS ≥ 80% and PP ≥ 0.80) are shown at the nodes for ML bootstrap support (BS) and BI posterior probabilities (PP). Tolypocladium inflatum OSC 71235 and T. ophioglossoides CBS 100239 were used as outgroup taxa. Species in red type are those analyzed in this study. The scale bar represents the expected number of changes per site.
Figure 1. Molecular phylogenetic analyses using the ML and BI based on combined nrLSU, tef1-α, and rpb2 sequence data. Statistical support values (BS ≥ 80% and PP ≥ 0.80) are shown at the nodes for ML bootstrap support (BS) and BI posterior probabilities (PP). Tolypocladium inflatum OSC 71235 and T. ophioglossoides CBS 100239 were used as outgroup taxa. Species in red type are those analyzed in this study. The scale bar represents the expected number of changes per site.
Diversity 18 00313 g001
Diversity 18 00313 g002
Figure 2. Morphological features of Ophiocordyceps minuta (holotype CXAC 0026). (A). Habitat; (B,C). Fungus on termite; (DF). Ascospores; (G). Perithecia; (HJ). Ascospores. Scale bars: (B,C) = 10 mm; (DF,HJ) = 20 µm; (G) = 200 µm.
Figure 2. Morphological features of Ophiocordyceps minuta (holotype CXAC 0026). (A). Habitat; (B,C). Fungus on termite; (DF). Ascospores; (G). Perithecia; (HJ). Ascospores. Scale bars: (B,C) = 10 mm; (DF,HJ) = 20 µm; (G) = 200 µm.
Diversity 18 00313 g002
Table 1. PCR cycling conditions for each gene.
Table 1. PCR cycling conditions for each gene.
The ProgramsnrLSU/tef1-αrpb2
Initial denaturation95 °C 4 min 95 °C 4 min 
Phase 116 cycles17 cycles
 95 °C 50 s94 °C 50 s
 60 °C 50 s
−0.5 °C/cycle		55 °C 50 s
 72 °C 60 s72 °C 90 s
Phase 222 cycles19 cycles
 94 °C 50 s94 °C 50 s
 51 °C 50 s51 °C 50 s
 72 °C 60 s72 °C 90 s
Final extension72 °C 8 min72 °C 10 min
Table 2. Specimen information and GenBank accession numbers for sequences used in this study.
Table 2. Specimen information and GenBank accession numbers for sequences used in this study.
Current NameVoucherGenBank Accession NumberReferences
nrLSUtef1-αrpb2
Hirsutella citriformisARSEF 1446KM652106KM651990[44]
H. fusiformisARSEF 5474KM652110KM651993[44]
H. giganteaARSEF 30JX566977JX566980[44]
H. guyanaARSEF 878KM652111KM651994[44]
H. illustrisARSEF 5539KM652112KM651996[44]
H. kirchneriARSEF 5551KM652113KM651997[44]
H. lecaniicolaARSEF 8888KM652114KM651998[44]
H. liboensisARSEF 9603KM652115[44]
H. necatrixARSEF 5549KM652116KM651999[44]
H. nodulosaARSEF 5473KM652117KM652000[44]
H. radiataARSEF 1369KM652119KM652002[44]
H. rhossiliensisARSEF 3747KM652123KM652006[44]
H. strigosaARSEF 2197KM652129KM652012[44]
H. subulataARSEF 2227KM652130KM652013[44]
H. thompsoniiARSEF 414KM652143KM652021[44]
H. thompsonii var. vinaARSEF 254KM652149KM652028[44]
H. versicolorARSEF 1037KM652150KM652029[44]
Ophiocordyceps acicularisOSC 110988EF468804EF468745[2]
O. agriotidisARSEF 5692DQ518754DQ522322DQ522418[45]
O. appendiculataNBRC 106960JN941413AB968577AB968539[46]
O. arborescensNBRC 105891AB968414AB968572AB968534[47]
O. asiaticaBCC 30516MH753675MK284263MK214091[8]
O. bidoupensisYFCC 8793OK556894OK556900[13]
O. brunneinigraBCC 69032MF614654MF614638MF614681[48]
O. brunneiperitheciataBCC 66167MF614659MF614644MF614684[48]
O. brunneipunctataOSC 128576DQ518756DQ522324DQ522420[45]
O. brunneirubraBCC 14384MH753690GU797121MK751468[8]
O. campesBCC 36938MT118175MT118167MT118188[49]
O. communisBCC 1842MH753680MK284266MK214096[8]
O. cossidarumMFLU 17-0752MF398187MF928403[50]
O. fusiformisBCC 93025MZ675422MZ707849MZ707805[27]
O. fusiformisBCC 93026MZ675423MZ707850MZ707806[27]
O. geometridicolaBCC 35947MF614647MF614631MF614678[48]
O. globiperitheciataHKAS 126130OR015968OR030532[21]
O. globosaBCC 93023MZ675419MZ707846[27]
O. hydrangeaYFCC 8832OM304640OM831277OM831283[13]
O. irangiensisBCC 82795MH028186MH028174[8]
O. isopteraeMY12376MZ675420MZ707847MZ707803[27]
O. isopteraeBCC 93042MZ675421MZ707848MZ707804[27]
O. khokpasiensisBCC 48071MH753682MK284269[8]
O. kimflemingiaeSC09BKX713620KX713698[3]
O. konnoanaEFCC 7315EF468753EF468916[2]
O. kuchinaraiensisBCC 95830OQ627397OQ625474OQ625475[8]
O. linyphiidarumHKAS 132197PV139245PV156008PV155994[51]
O. linyphiidarumHKAS 132196PV139246PV156009PV155995[51]
O. longistipesKUNCC 5224OR015967OR030530OR113082[21]
O. longistromataBCC 44497MT118178MT118170MT118191[49]
O. macroacicularisNBRC 100685AB968416AB968574AB968536[47]
O. melolonthaeOSC 110993DQ518762DQ522331[52]
O. mosingtoensisBCC 30904MH753686MK284273MK214100[8]
O. minutaCXAC 0026PX973468PX984915PX984944This study
O. minutaCXAC 0027PX973469PX984916PX984945This study
O. multiperitheciataBCC 22861MF614656MF614640MF614683[48]
O. myrmecophilaCEM 1710KJ878894KJ878974[53]
O. neovolkianaOSC 151903KJ878896KJ878976[53]
O. nigrellaEFCC 9247EF468818EF468758EF468920[2]
O. nutansOSC 110994DQ518763DQ522333[45]
O. pauciovoperitheciataTBRC 8096MF614649MF614636MF614672[48]
O. pruinosaNHJ 12994EU369041EU369024EU369084[54]
O. pseudoacicularisBCC 53843MF614646MF614630MF614677[48]
O. pseudocommunisBCC 16757MH753687MK284274MK214101[8]
O. pseudorhizoideaBCC 86431MH753674MK284262MK214090[8]
O. puluongensisYFCC 6442MT270528MT270520MT270526[22]
O. radiciformisBCC 93036MZ675425MZ707852MZ707808[27]
O. radiciformisBCC 93035MZ675426MZ707853MZ707809[27]
O. ramosissimumGZUHHN8KJ028014[55]
O. raveneliiOSC 110995DQ518764DQ522334DQ522430[50]
O. raveneliiOSC 151914KJ878978KJ878950[53]
O. rhizoideaNHJ 12522EF468825EF468764EF468923[8]
O. rhizoideaNHJ 12529EF468824EF468765EF468922[8]
O. robertsiiKEW 27083EF468826EF468766[2]
O. rubiginosiperitheciataNBRC 106966JN941437AB968582AB968544[56]
O. salganeicolaMori01MT741719MT759575MT759580[9]
O. satoiJ7KX713599KX713683[3]
O. sinensisARSEF 6282KM652126KM652009[44]
O. sinensisEFCC 7287EF468827EF468767EF468924[56]
O. soboliferaNBRC 106967AB968422AB968590[47]
O. spataforaeNHJ 12525EF469078EF469063EF469111[2]
O. spataforaeOSC 128575EF469079EF469064EF469110[2]
O. sphecocephalaNBRC 101752JN941445AB968591AB968552[51]
O. spicatusMFLU 18-0164MK863054MK860192[57]
O. stylophoraOSC 111000DQ518766DQ522337DQ522433[55]
O. stylophoraOSC 110999EF468837EF468931[2]
O. thanathonensisMFLU 16-2909MF850377MF872613[58]
O. tricentriNBRC 106968AB968423AB968593AB968554[47]
O. trichosporaCBS 109876AF543790AF543779DQ522457[2]
O. unilateralisOSC 128574DQ518768DQ522339DQ522436[50]
O. unituberculataYFCC HU1301KY923216KY923220[7]
Tolypocladium inflatumOSC 71235EF469077EF469061EF469108[59]
T. ophioglossoidesCBS 100239KJ878874KJ878958KJ878944[53]
Boldface: data generated in this study, – means no data.
Table 3. Morphological comparison between Ophiocordyceps species associated with termites.
Table 3. Morphological comparison between Ophiocordyceps species associated with termites.
SpeciesDistributionStromata (cm)Perithecia (µm)Asci (µm)Ascospore (µm)Asexual MorphConidiogenous Cells (µm)Conidia (µm)References
O. asiaticaThailandSolitary, simple, filiform, orange brown, up to 15 longSuperficial, globose to subglobose, 240–320 × 180–260Filiform, 92.5–175 × 5–6.3Filiform, septate, whole, 80–132.5 × 1–2Hirsutella-likeMonophialidic or rarely polyphialidic, 15–20 × 2–3Fusiform, 7–9 × 2–3[8]
O. bisporaTanzania, KenyaMultiple (20–30), simple or branched, clavateImmersed, globose, 300–375 × 375Clavate, 162–163 × 58–61Elliptical closely appressed, septate, 95–105 × 34–35.4[24,29]
O. brunneirubraThailandSolitary, simple or branched, narrowly clavate, orange brown to red brown, 9.5 longImmersed, ovoid, 300–400 × 130–200Cylindrical, 155–225 × 4.5–8Filiform, septate, whole, 156.5–197.5 × 2–3Monophialidic, 32–50 × 2–3Fusiform, 12–17 × 2–4[8]
O. communisThailandSolitary, simple, filiform, base whitish-grey, upper part yellow-brown, 5–13 longSuperficial, 285–675 × 195–390Filiform, 215–250 × 15Filiform, septate, whole, 100–180 × 5–6Hymenostilbe/Hirsutella-likeMonophialidic or rarely polyphialidic, 10–14 × 2.7–3.3Almond-shaped, 7–9 × 2.5–3[2]
O. fusiformisThailandSolitary, simple, cylindrical, brown, up to 6 longSuperficial, ovoid, 300–360 × 180–270Cylindrical, 141–227 × 7–15Cylindrical, septate, whole, 36–78 × 5–6.5HymenostilbeMonophialidic, 9–24 × 2–4Fusiform, 6–18 × 2–4[27]
O. globosaThailandSolitary, simple, cylindrical, brown, up to 8 longPseudo-immersed, ovoid, 190–245 × 120–190Filiform, 100–157 × 7–13Filiform, septate, whole, 58–118 × 2–3Hirsutella-likeMonophialidic or polyphialidic, 9–15 × 3–5Globose, 2–4[27]
O. globiperitheciataChinaMultiple (2–5), unbifurcated, clavate, base brown, tip gray, 8–15 longSuperficial, subglobose, 240–295 × 215–280Filiform, 135–170 × 8.5–13.5Filiform, septate, whole, 85–110 × 3.5–4.5[21]
O. isopteraeThailandSolitary, simple, cylindrical, brown, up to 10 longSuperficial, ovoid, 270–320 × 140–180Filiform, 81–137 × 5–9Filiform, septate, whole, 55–78 × 2–2.5Hirsutella-likeMonophialidic, 14–28 × 2–4Fusiform, 6–11 × 1.5–3[27]
O. khokpasiensisThailandSolitary, simple, cylindrical, brown, 16 longPseudo-immersed, subglobose, 200–250 × 120–200Filiform, 62.5–125 × 4–5Filiform, whole, 46–90 × 2–3Hirsutella-likeMonophialidic or polyphialidic, 15–28 × 3–5Globose to oval, 4–6 × 2.5–4[8]
O. koningsbergeriJawaSolitary, filiform, gray-white, 8–10 longImmersed, 450 × 90Cylindrica, 180–200 × 4–5Filiform, whole, 150 × 1[25]
O. longistipesChinaSolitary, unbifurcated, cylindrical, grayish white to yellowish brown, 17–24 longSuperficial, pyramidal to oval, 390–420 × 295–350Filiform, 160–195 × 4.5–6.5Filiform, septate, whole, 70–85 × 3.5–4.5Hirsutella-likeMonophialidic or rarely polyphialidic, 29–60 × 4–4.5Citriform or oval, 7–10 × 4.5–7[21]
O. minutaChinaSolitary, simple, cylindrical, brown to yellowish brown, 6–14 long,Superficial, ovoid to flask-shaped, 151.5–221 × 115–188Dimorphic: type I fusiform, septate, whole, 80–92.5 × 5.0–6.5; type II vermiform or lanceolate, 32.5–52.5 × 2.0–4.5This study
O. mosingtoensisThailandSolitary, simple, cylindrical, brown to grey, 11 longPseudo-immersed, ovoid, 400–500 × 200–300Filiform, 187.5–287.5 × 4.5–7.5Filiform, septate, whole, 230–315 × 1.5–3Hirsutella-likeMonophialidic, 10–17 × 2–3Oval, 3–5 × 2–3[8]
O. octosporaMexicoMultiple, clavate, white to pale tan, 0.2–0.3 longImmersed, subglobose to ovoid, 180–220 × 200Clavate, about 250 × 60Cylindrical, septate, 40–70 × 15–30[26]
O. ovatosporaChinaSolitary, simple, cylindrical or clavate, light-yellow, up to 13 longPseudo-immersed, ovoid to pyriform, 110–140 × 80–110Filiform, 110–125 × 5–7Filiform, septate, whole, 110–130 × 1–2Hirsutella-likeMonophialidic or rarely polyphialidic, 15–35 × 3–6Oval, 3–5 × 3–4[28]
O. pseudocommunisThailandSolitary, simple, cylindrical, brown, 21 longSuperficial, Subglobose, 520–600 × 360–440Filiform, 160–165 × 14–17Filiform, septate, whole, 107.5–147.5 × 6–7.5HymenostilbeFusiform, septate (2–3), 13–27 × 3–5[8]
O. pseudorhizoideaThailandSolitary, simple, filiform, light brown, up to 21 longSuperficial, ovoid, 280–390 × 160–220Cylindrical, 120–150 × 5–7Filiform, whole, 65–82.5 × 2–3Hirsutella-likeMonophialidic, 9–21 × 2–4Fusiform, 5–10 × 1–2[8]
O. puluongensisVietnamSolitary, simple or branched, filiform, pale orange to red brown, 7.1–13.3 longSuperficial, subglobose, 181.8–251.0 × 123.7–205.4Filiform, 74.3–138.5 × 4.6–6.5Filiform, septate, whole, 67.0–124.5 × 1.5–2.5Hirsutella-likeMonophialidic or rarely polyphialidic, 7.9–21.2 × 1.7–5.0Fusiform or citriform, 2.8–6.1 × 1.9–3.4[22]
O. radiciformisThailandSolitary, simple, cylindrical, brown, up to 11 longSuperficial, ovoid, 330–460 × 200–320Cylindrical, 140–296 × 6–10Filiform septate, whole, 154–215 × 2–3Hirsutella-like6–15 × 2–5Fusiform, 5–7 × 2–3[27]
O. taiwanensisChinaGrayish light brown, clavate, simple, 0.4–2.6 × 0.5–0.7 mmImmersed, subglobose to ovoid, 280–365 × 140–210Cylindrical to clavate, 87–100 × 21–37Ellipsoidal to ellipsoidal-fusiform, 78–95 × 20–27[23]
O. termiticolaThailandSolitary, simple, filiform, yellow brown, up to 14 longPseudo-immersed, globose to subglobose, 200–280 × 150–250Filiform 62.5–110 × 4–6Filiform, whole, 85 × 2Hymenostilbe-likeMonophialidic to polyphialidic, 7–11 × 2.5–4Globose, 2.5–3.5[8]
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Dong, Q.-Y.; Liu, J.-L.; Liu, C.-K.; Hu, C.; Yang, J.; Xu, W.-L.; Xu, C.-D. Untapped Diversity of Termite-Associated Ophiocordyceps and a New Species from China. Diversity 2026, 18, 313. https://doi.org/10.3390/d18060313

AMA Style

Dong Q-Y, Liu J-L, Liu C-K, Hu C, Yang J, Xu W-L, Xu C-D. Untapped Diversity of Termite-Associated Ophiocordyceps and a New Species from China. Diversity. 2026; 18(6):313. https://doi.org/10.3390/d18060313

Chicago/Turabian Style

Dong, Quan-Ying, Jin-Lin Liu, Chang-Kun Liu, Chao Hu, Jun Yang, Wan-Li Xu, and Cheng-Dong Xu. 2026. "Untapped Diversity of Termite-Associated Ophiocordyceps and a New Species from China" Diversity 18, no. 6: 313. https://doi.org/10.3390/d18060313

APA Style

Dong, Q.-Y., Liu, J.-L., Liu, C.-K., Hu, C., Yang, J., Xu, W.-L., & Xu, C.-D. (2026). Untapped Diversity of Termite-Associated Ophiocordyceps and a New Species from China. Diversity, 18(6), 313. https://doi.org/10.3390/d18060313

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