Multigene phylogeny of the family Cordycipitaceae (Hypocreales): new taxa and the new systematic position of the Chinese cordycipitoid fungus Paecilomyces hepiali

The phylogeny and systematics of cordycipitoid fungi have been extensively studied in the last two decades. However, systematic positions of some taxa in the family Cordycipitaceae have not yet been thoroughly resolved. In this study, a new phylogenetic framework of Cordycipitaceae is reconstructed using multigene (nrSSU, nrLSU, tef-1α, rpb1 and rpb2) sequence data with large-scale taxon sampling. In addition, ITS sequence data of species belonging to the Lecanicillium lineage in the family Cordycipitaceae are used to further determine their phylogenetic placements. Based on molecular phylogenetic data together with morphological evidence, two new genera (Flavocillium and Liangia), 16 new species and four new combinations are introduced. In the new genus Flavocillium, one new species F. bifurcatum and three new combinations previously described as Lecanicillium, namely F. acerosium, F. primulinium and F. subprimulinium, are proposed. The genus Liangia is built by the new species Lia. sinensis with Lecanicillium-like asexual morph, isolated from an entomopathogenic fungus Beauveria yunnanensis. Due to the absence of Paecilomyces hepiali, an economically and medically significant fungus, in the earlier phylogenetic analyses, its systematic position has been puzzling in both business and academic communities for a long time. Here, P. hepiali is recharacterized using the holotype material along with seven additional samples. It is assigned to the genus Samsoniella (Cordycipitaceae, Hypocreales) possessing Cordyceps-like sexual morph and Isaria-like asexual morph, and thus a new combination, namely S. hepiali is proposed. An additional nine new species in Samsoniella are described: S. alpina, S. antleroides, S. cardinalis, S. cristata, S. lanmaoa, S. kunmingensis, S. ramosa, S. tortricidae and S. yunnanensis. Four new species in Cordyceps are described: C. chaetoclavata, C. cocoonihabita, C. shuifuensis and C. subtenuipes. Simplicillium yunnanense, isolated from synnemata of Akanthomyces waltergamsii, is described as a new species.


Introduction
In the taxonomic system of the twentieth century, Cordyceps Fr. sensu lato belonged to the family Clavicipitaceae s. l. characterized by possessing cylindrical asci, thickened ascus apices, and filiform ascospores that often disarticulate into secondary ascospores (Mains 1958;Kobayasi 1982;Rossman et al. 1999Rossman et al. , 2002Sung et al. 2007). This genus is the most diverse group of Clavicipitaceae s. l. due to the large number of species and wide host range. The host associations for Cordyceps s. l. are complex and diverse. Most of species are pathogens of more than 10 orders of invertebrates, while others are parasites of hypocrealean fungi, the truffle-like Elaphomyces Nees and myxomycetes (Kobayasi and Shimizu 1960;Kobayasi 1982;Sung et al. 2007;Kepler et al. 2013Kepler et al. , 2017Wang et al. 2015a,b). Phylogenetic analyses have indicated that neither Cordyceps s. l. nor Clavicipitaceae s. l. are monophyletic (Sung et al. 2007). Three cordycipitoid families are now recognized in the order Hypocreales: Clavicipitaceae, Cordycipitaceae and Ophiocordycipitaceae. At least 39 genera accommodating more than 1300 cordycipitoid species have been assigned to these three families (Sung et al. 2007;Chaverri et al. 2008;Johnson et al. 2009;Luangsa-ard et al. 2011Luangsa-ard et al. , 2017Kepler et al. 2013Kepler et al. , 2014Kepler et al. , 2017Quandt et al. 2014;Spatafora et al. 2015;Tsang et al. 2016;Zare and Gams 2016;Mongkolsamrit et al. 2018).
The family Cordycipitaceae shares a common ancestor with Hypocreaceae and contains most of the species that have pallid or brightly pigmented, fleshy stromata (Sung et al. 2007;Maharachchikumbura et al. 2015). However, some species are characterized by possessing reduced stipes or subiculate stromata on the host. This family is the most complex group in Hypocreales with its varied morphological characteristics and wide-ranging hosts. Some genera with sexual or asexual morphs, such as Akanthomyces Lebert, Beauveria Vuill., Cordyceps, Gibellula Cavara, Isaria Pers., Lecanicillium W. Gams & Zare and Torrubiella Boud., present numerous taxonomical problems and exist competing names. Numerous species of Cordyceps are associated with genera described originally for asexual morphs, including Akanthomyces, Beauveria, Evlachovaea B.A. Borisov & Tarasov, Isaria, Lecanicillium, Microhilum H.Y. Yip & A.C. Rath and Paecilomyces Bainier. For example, in the genus Akanthomyces proposed by the type species A. aculeatus Lebert, C. tuberculata (Lebert) Maire is linked to an asexual morph A. pistillariiformis (Pat.) Samson & H.C. Evans (Samson and Evans 1974). The sexual morph C. confragosa (Mains) G.H. Sung et al. described by Mains (1949) in Torrubiella, is linked to the type species Lecanicillium lecanii (Zimm.) Zare & W. Gams of Lecanicillium and considered to be a synonym of Akanthomyces (Kepler et al. 2017). Cordyceps militaris (L.) Fr. also produces an asexual conidiogenous structure linked to Lecanicillium (Gams and Zare 2001). Cordyceps bassiana Z.Z. Li et al. was described as the sexual morph of B. bassiana (Bals.-Criv.) Vuill., the type species of Beauveria, which caused economically devastating epizootics of domestic larval silkworms in southern Europe during the eighteenth and nineteenth centuries (Li et al. 2001). Evlachovaea kintrischica B.A. Borisov & Tarasov, the type species of Evlachovaea, was demonstrated to be a synonym of Isaria and was later combined into C. kintrischica (B.A. Borisov & Tarasov) Kepler et al. (Humber et al. 2013;Kepler et al. 2017). Kepler et al. (2017) provided the most complete taxonomic treatment of Cordycipitaceae and harmonized competing names based on principles of priority, recognition of monophyletic groups, and the practical usage of affected taxa, following Article 59 of the International Code of Nomenclature for algae, fungi and plants. They proposed to accommodate 11 genera within Cordycipitaceae, namely Akanthomyces, Ascopolyporus Möller, Beauveria, Blackwellomyces Spatafora & Luangsa-ard, Cordyceps, Engyodontium  Cai on bat guano in this genus based on multigene phylogeny and morphology. Subsequently, Mongkolsamrit et al. (2018) erected the genus Samsoniella Mongkols et al. to accommodate three species with orange cylindrical to clavate stromata, superficial perithecia and orange conidiophores with Isaria-like phialides and white to cream conidia, and to segregate them from the Akanthomyces group. Although several taxonomic studies have been conducted, many species originally described in Lecanicillium remain incertae sedis members in the family Cordycipitaceae and are polyphyletic (Zare and Gams 2016;Kepler et al. 2017;Mongkolsamrit et al. 2018). To date, 32 Lecanicillium species have been formally described and recorded in the Index Fungorum (https ://www.index fungo rum.org). Available data indicated that some species, such as L. aranearum (Petch) Zare & W. Gams, L. antillanum (R.F. Castañeda & G.R.W. Arnold) Zare & W. Gams, L. primulinum Kaifuchi et al. and L. psalliotae (Treschew) Zare & W. Gams represent basal to subbasal monophyletic clades in the family Cordycipitaceae (Kepler et al. 2017;Huang et al. 2018;Zhou et al. 2018). Therefore, new generic names for these species in the family Cordycipitaceae need to be introduced and supported by more detailed morphological and phylogenetic evidence combined with a larger taxon sampling.
The genus Paecilomyces erected by Bainier (1907), based on the type species P. variotii Bainier, was placed in the family Aspergillaceae (Eurotiales). Samson (1974) expanded Paecilomyces and recognized some mesophilic species previously placed in Isaria or Spicaria Harting as a distinguishing sect. Isarioidea with mostly insect hosts. However, a nrSSU phylogenetic analysis indicated that Paecilomyces is not monophyletic and the sect. Isarioidea is not a eurotialean lineage (Luangsa-ard et al. 2004). Based on the β-tubulin and ITS phylogentic data, Luangsa-ard et al. (2005) found that Paecilomyces sect. Isarioidea is polyphyletic in the order Hypocreales. The group designed as the Isaria clade is excluded from the genus Paecilomyces. It is monophyletic comprising of 10 Paecilomyces species, nine of which are subsequently transfered into Cordyceps.
Paecilomyces hepiali Q.T. Chen & R.Q. Dai ex R.Q. Dai et al. was first isolated from natural Ophiocordyceps sinensis (Berk.) G.H. Sung et al. (syn. C. sinensis) associated with the larvae of Hepialus armoricanus Oberthür in China (Dai et al. 1989). This is a very important fungus because of its therapeutic benefits. However, molecular phylogenetic position of P. hepiali has been unclear for a long time due to the absence of nucleotide sequences from the holotype material. Recent phylogenetic analyses based on mitochondrial genomic sequences from five families within the order Hypocreales indicated that the putative P. hepiali specimen belongs to the family Cordycipitaceae . However, without any generic assignment, its wellestablished phylogenetic position within the family remains undetermined. For such a species that makes a significant contribution to human health, it is indispensable to elucidate its phylogeny and systematics using the holotype material.
During the last two decades, our efforts have been exerted in the investigation of cordycipitoid fungi especially in China and Southeast Asia. To date, over 18,000 specimens and 7500 strains of Cordyceps s. l., representing more than 450 species, have been deposited in Yunnan University, Kunming, Yunnan Province. In this study, 1568 specimens and 1075 strains of Cordycipitaceae from different regions in Yunnan Province of China and Vietnam were analyzed using molecular phylogeny and morphology. Among these materials, five-gene (nrSSU,nrLSU,rpb1 and rpb2) data from 56 samples, and ITS data from two samples were selected and submitted to GenBank. We established phylogenetic and evolutionary trees by maximum likelihood (ML) and Bayesian inference (BI) analyses from the five-gene and ITS data. Two new genera, 16 new species and four new combinations are introduced.

Fungal materials and isolation
The majority of Cordycipitaceae specimens were collected from Yunnan Province in China. Some specimens were collected from the Hoang Lien Mountains of Lao Cai Province in Vietnam. Specimens were noted and photographed in the fields. Collections were placed in sterilized plastic tubes and boxes, returned to the laboratory, and stored at 4 °C. The specimens were examined using an Olympus SZ61 stereomicroscope. To obtain axenic cultures, the stromata or synnemata were removed from insect bodies and divided into 5-10 segments, each 3 mm long. The segments were immersed in 30% H 2 O 2 for 30 s and then rinsed five times in sterilized water. After drying on sterilized filter paper, segments were inoculated onto potato dextrose agar (PDA: potato 200 g/L, dextrose 20 g/L, agar 20 g/L) plates. The conidia of cordycipitoid fungi at the conidial masses were picked up with an inoculating loop and spread on PDA plates containing 0.1 g/l streptomycin and 0.05 g/l tetracycline. To isolate the strains from the sexual morph, the stroma containing mature perithecia was placed over a PDA plate and care was taken that the stroma was above the PDA plate and did not touch the agar surface in an effort to discharge ascospores. Discharged ascospores were removed with a sterile needle from the agar and transferred onto a new PDA plate containing 0.1 g/l streptomycin and 0.05 g/l tetracycline. Pure cultures were transferred onto PDA plates and incubated in a culture room at 25 °C. After isolation into pure cultures, they were transplanted to a PDA slant and stored at 4 °C. Specimens were deposited in Yunnan Herbal Herbarium (YHH) of Yunnan University. The cultures were deposited in Yunnan Fungal Culture Collection (YFCC) of Yunnan University.

Morphological observations
For descriptions of the sexual morph, fruiting bodies were photographed and measured using an Olympus SZ61 stereomicroscope. Hand sections of the fruiting structures were mounted in water or lactophenol cotton blue solution for microscopic studies and photomicrography. The micromorphological characteristics of fungi such as perithecia, asci and ascospores were examined using Olympus CX40 and BX53 microscopes. Cultures on slants were transferred to PDA plates and cultured in an incubator for 21 days at 25 °C. The circular agar blocks, circa 5 mm in diameter, from a colony were removed and placed on new PDA plates to observe colony morphology. Colonies were photographed and measured every fourth day. For asexual morphological descriptions, microscope slide cultures were prepared by placing a small amount of mycelia on 5-mm diameter PDA medium blocks overlaid by a cover slip. Micro-morphological observations and measurements were conducted using Olympus CX40 and BX53 microscopes, and a FEI QUANTA200 scanning electron microscope.

DNA extraction, PCR, and sequencing
Clean-washed specimens and axenic living cultures were prepared for DNA extraction. Total DNA was extracted using the CTAB method described by Liu et al. (2001). The 1 3 following primer pairs were used for PCR amplification. The primer pair, nrSSU-CoF and nrSSU-CoR was used to amplify the nuclear ribosomal small subunit (nrSSU) (Wang et al. 2015a). The primer pair, LR5 and LR0R was used to amplify the nuclear ribosomal large subunit (nrLSU) (Vilgalys and Hester 1990;Rehner and Samuels 1994). The primer pair, EF1α-EF and EF1α-ER was used to amplify the translation elongation factor 1α (tef-1α) (Bischoff et al. 2006;Sung et al. 2007). The two primer pairs, RPB1-5′F and RPB1-5′R, RPB2-5′F and RPB2-5′R were used to amplify the largest and second largest subunits of RNA polymerase II (rpb1and rpb2), respectively (Bischoff et al. 2006;Sung et al. 2007). The primer pair, ITS4 and ITS5 was used to amplify the nuclear ribosomal internal transcribed spacer region (ITS) (White et al. 1990). Polymerase chain reaction (PCR) assays of five genes and ITS were performed as previously described (Bischoff et al. 2006;Wang et al. 2015b). The PCR assay was conducted as described by Wang et al. (2015b). PCR products were separated by electrophoresis in 1.0% agarose gels, purified using the Gel Band Purification Kit (Bio Teke Co., Ltd, Beijing, China) and then sequenced on an automatic sequence analyser (BGI Co., Ltd, Shenzhen, China). When PCR products could not be sequenced directly, coloning was performed by the TaKaRa PMD TM 18-T vector system (TaKaRa Biotechnology Co., Ltd, Dalian, China). nrLSU,rpb1 and rpb2) sequences from 56 samples of 30 species belonging to six genera, and ITS sequences from two samples of the new species Flavocillium bifurcatum, were newly generated. Sequences of five genes and ITS were retrieved from GenBank, and then combined with the newly generated sequences. The taxon information and GenBank accession numbers of five genes were listed in Table 1. GenBank accession numbers of ITS sequences were placed in the front of the species name, appearing in the ITS phylogenetic tree (Fig. 3). Sequences of five genes and ITS were aligned using Clustal X2.0 and MEGA6 (Larkin 2007;Tamura et al. 2013). Ambiguously aligned sites were excluded from phylogenetic analyses, and gaps were treated as missing data. Adjustment to the computer-assisted alignment was necessary regarding the nrSSU sequences containing an intron. These sequences were manually adjusted and ambiguous regions created by insertions and deletions (indel) were eliminated. After sequence alignments, the aligned sequences of five genes were concatenated. Conflicts between the five genes were tested using PAUP* 4.0b10 (Swofford 2002). The results showed that the phylogenetic signals in the five genes were not in conflict. Eleven data partitions were defined for the combined five-gene dataset employing PartitionFinder V1.1.1 (Lanfear et al. 2012). These included one each for nrSSU and nrLSU, and three for each of the three codon positions of tef-1α, rpb1 and rpb2. Phylogenetic analyses of the five-gene and ITS datasets were conducted using ML and BI methods. ML analyses were performed with RAxML v7.9.1 using the optimal model GTR + I with 1000 rapid bootstrap replicates on the five-gene and ITS datasets (Stamatakis 2006). The model was separately applied to each of the 11 partitions of five genes. BI analyses were performed with MrBayes v3.1.2 for five million generations using a GTR + G + I model determined by jModelTest version 2.1.4 and employed the model separately for each partition of five-gene analyses, whereas the default F81 model was used for the ITS analyses (Ronquist and Huelsenbeck 2003;Darriba et al. 2012). Trees were sampled every 100 generations. The first 25% trees were discarded as burn-in and the remaining trees were used to create a consensus tree using the sumt demand. Phylogenetic trees were visualised and modified using the Interactive Tree Of Life (iTOL) (https ://itol.embl.de) online tool (Letunic and Bork 2019).

Results
In ML and BI phylogenetic analyses, five-gene sequences of 30 species collected in this study were employed to reconstruct phylogenetic framework of the family Cordycipitaceae. Taxa within the order Hypocreales consisted of four families, viz. Cordycipitaceae, Ophicordycipitaceae, Clavicipitaceae, Hypocreaceae, and two taxa of Nectriaceae (Nectria cinnabarina CBS 114055 and Gliocephalotrichum bulbilium ATCC 22228) designated as the outgroup. The concatenated sequence dataset of 241 taxa was composed of 4837 bp sequence data (1082 bp for nrSSU, 904 bp for nrLSU, 1064 bp for tef-1α, 802 bp for rpb1 and 985 bp for rpb2). Phylogenetic trees obtained from ML and BI analyses were identical in overall topologies and were not significantly different (Fig. 1). Most well-resolved genera and lineages in Cordycipitaceae shared similar relationships with previous analyses (Sung et al. 2007;Sukarno et al. 2009;Kepler et al. 2017;Mongkolsamrit et al. 2018). Our ML and BI analyses showed that the placement of Cordycipitaceae in the order Hypocreales was well-supported by bootstrap proportions (BP = 70%) and posterior probabilities (PP = 95%), respectively.
Species in the typifed genus Lecanicillium were distributed throughout the family Cordycipitaceae and were polyphyletic ( Fig. 1, 2). These species were clustered into the clades of L. aranearum, L. antillanum, L. primulinum, L. fusisporum and L. psalliotae, respectively. In the five-gene phylogenetic tree, the L. primulinum clade harbored L. primulinum, L. acerosum W. Gams et al., Lecanicillium sp. and another new species (YFCC 6101) described in this study. ML and BI phylogenetic      (Fig. 1, 2). The systematic position of P. hepiali was determined by five-gene phylogeny with the holotype living culture ICMM 82-2 and seven other samples. These eight samples closely clustered together with a well-supported clade and were placed in the genus Samsoniella, all of which were phylogenetically distinct from C. farinosa (Holmsk.) Kepler et al. (type strain CBS 111113) belonging to the type genus Cordyceps of Cordycipitaceae (Fig. 1). Nine undescribed species collected from Yunnan in China also clustered in the  Etymology: Referring to the clavate stromata with spinous fertile parts.
Habitat: On the pupa of Lepidoptera buried in soil. Distribution: Kunming City, China.
Host: Pupae of Limacodidae. Notes: Cordyceps cocoonihabita is characterized by unbranched or terminally branched stromata, clavate fertile parts often have aperithecial apices, orange to pink or reddish-orange, superficial perithecia with oblong-ovate shape, cylindrical ascospores, and the host of lepidopteran pupae in oval cocoons. The asexual morph from PDA culture produces conidiophores with cylindrical to flask-shaped phialides which are monothetic, alternate or whorled, as well as oval to fusiform conidia in chains.
It is phylogenetically closely related to a formally undescribed taxon C. cf. pruinosa (EFCC 5197, EFCC 5693) and is separated from C. pruinosa Petch  Cordyceps cocoonihabita, C. pruinosa and C. ninchukispora have the similar macromorphological characteristics of stromata with orange to pink colors, pyriformlike perithecia, with the exception of the former fertile parts often have aperithecial apices (Petch 1924;Su and Wang 1986). The former two taxa have similar hosts of lepidopteran pupae in cocoons, they differ, however, from C. ninchukispora with hosts such as seeds of Beilschmiedia Nees. Ecologically, C. cocoonihabita and C. obliquiordinata Kobayasi & Shimizu have similar habitats that are in cocoons of Lepidoptera (Kobayasi and Shimizu 1982). However, C. obliquiordinata is morphologically different from C. cocoonihabita by having shorter stromata, brevis stipes, ovoid and irregular pars fertile parts, obliquely immersed perithecia, fairly short asci and ascospores. In terms of asexual morph, C. cocoonihabita has Isaria-like micromorphological characteristics and is significantly different from C. pruinosa and C. ninchukispora which respectively have morphs of Mariannaea G. Arnaud and Acremonium Link (Liang et al. 1983(Liang et al. , 1991Su and Wang 1986).
Mycobank: MB 833092; Fig. 6 Etymology: Named after the location Shuifu City where this species was collected.
Host: Pupa of Lepidoptera. Notes: Cordyceps shuifuensis phylogenetically clusters with C. militaris, C. kyusyuensis Kawam and C. roseostromata Kobayasi & Shimizu, but is distinguished from these three by forming a separate clade in this group. This species is morphologically closest to C. militaris having cylindrical to slightly clavate stromata with yellowish to reddish-orange colors, superficial perithecia and Verticillium-like asexual morph, but differs from the latter in size. Cordyceps shuifuensis only has Verticillium-like asexual morph, whereas C. militaris has both Verticillium-and Isaria-like asexual morphs (Yang et al. 2012). Cordyceps kyusyuensis differs from C. shuifuensis by having mutiple rhizoid stromata, the host larvae of Sphingidae and being very large in size (Kobayasi 1981;Liang 2007). Cordyceps roseostromata differs from C. shuifuensis by its mutiple and rhizoid stromata, rose color, and the host larvae of Coleoptera (Kobayasi and Shimizu 1983).
Host: Pupae of Lepidoptera.  conspicuous synnemata and Isaria-like asexual conidiogenous structure producing phialides with a swollen basal portion. It differs from C. tenuipes by its single or two synnemata, white color, phialides with a globose basal portion and smaller fusiform or oval conidia measuring 1.9-3.4 × 1.5-2.7 µm. Cordyceps tenuipes has mutiple synnemata, larger cylindrical to botuliform conidia with the size of 2.0-7.5 × 1.0-2.5 µm (Samson 1974). The sexual morph of C. tenuipes as proposed by the name C. takaomontana Yakush & Kumaz has yellowish stromata and often co-occurs with its asexual morph (Liang 2007  mononematous, cylindrical, with two to five phialides at the terminal nodes. Phialides lanceolate, solitary or in whorls of two to five, tapering gradually toward the apex. Two types of conidia hyaline, one-celled and smooth-walled, single or usually aggregate in subglobose to ellipsoidal heads at the apex of the phialides. Macroconidia fusiform, cymbiform or ellipsoidal to cylindrical. Microconidia oval to ellipsoidal or fusiform. Notes: Five-gene phylogenetic analyses show that L. acerosum, L. primulinum, Lecanicillium sp. and our samples (YHH 15428, YFCC 6101) group together, in a monophyletic clade in the family Cordycipitaceae (Fig. 1, 2). This L. primulinum clade is clustered in the subbasal portion of phylogenetic tree within Cordycipitaceae and has a close phylogenetic relationship with Engyodontium and Parengyodontium, but forms a distinct lineage. ML and BI phylogenetic analyses based on ITS sequences from 30 taxa in Lecanicillium and Simplicillium show that the Lecanicillium group is polyphyletic and consists of eight monophyletic clades (Fig. 3). The L. primulinum clade includes L. acerosum, L. primulinum, Lecanicillium sp., L. subprimulinum and one new species with yellowish stromata (Fig. 3). This result is also supported by the previous phylogenetic analyses of Lecanicillium species from a combined nrSSU, nrLSU, tef-1 and ITS sequence dataset (Huang et al. 2018). In this clade, L. acerosum was first described by its distinguishing morphological characteristics producing the large straight macroconidia (Zare and Gams 2001). Recently, two species (L. primulinum and L. subprimulinum) producing pastel yellow pigment were added, which were respectively isolated from soil and an ophioceras-like taxon on the dead submerged wood (Kaifuchi et al. 2013;Huang et al. 2018).
Morphologically, the L. primulinum clade is similar to other Lecanicillium species in terms of conidiophores, phialides and two types of conidia (Zare and Gams 2001;Zhou et al. 2018). However, these species of Flavocillium possess yellowish stromata with a furcate terminal branch, contorted fertile parts with yellowish perithecia and colonies that usually produce pastel yellow pigment, are obviously different from other members of the Lecanicillium lineage. In addition, the L. primulinum clade also can be distinguished from these phylogenetically related genera Engyodontium and Parengyodontium based on the morphological characteristics of the latters, both of which usually produce white colonies, conidiiferous rachids with denticles on phialides and terminal fertile regions that are zigzag-shaped (Gams et al. 1984;Tsang et al. 2016). Therefore, the new genus Flavocillium is introduced by the type species F. bifurcatum in order to accomodate the three following new combinations previously treated as members of Lecanicillium. Descriptions and illustrations: Zare and Gams (2001). Distribution: Known from Brazil, Amazon (Zare and Gams 2001).
Five-gene phylogenetic analyses suggest that F. bifurcatum is close to Lecanicillium sp. and F. primulinum. In addition, ITS phylogenetic analyses from more complete sequence data in this clade show that F. bifurcatum is sister to F. subprimulinum. Morphologically, F. bifurcatum is similar to F. subprimulinum and F. primulinum by the yellowish colonies, solitary or whorled phialides, macro-and microconidia aggregate in subglobose to ellipsoidal heads at the apex of phialides (Kaifuchi et al. 2013;Huang et al. 2018). However, the sexual morphs of F. subprimulinum and F. primulinum have not been observed. Flavocillium bifurcatum differs from F. subprimulinum and F. primulinum by its cymbiform macroconidia and longer conidiophores up to 64 µm. Ecologically, F. bifurcatum is parasitic on the larva of Noctuidae buried in soil and is quite different from other congeneric species.
Notes: The type strain of F. primulinum was isolated from soil under an unidentified plant. It is characterized by phialides produced on prostrate aerial hyphae, solitary or in whorls of two to five which taper toward the apex, ellipsoidal to cylindrical macroconidia and oval to ellipsoidal microconidia aggregate in subglobose to ellipsoidal heads at the apex of the phialides, presenting octahedral crystals (Kaifuchi et al. 2013). Phylogenetically, this species is close to F. bifurcatum and F. subprimulinum, but it differs morphologically from F. bifurcatum by the latter's cymbiform macroconidia and smaller microconidia of 2.1-4.2 × 0.9-1.5 µm in size. Notes: Flavocillium subprimulinum is characterized by solitary or two to three phialides on conidiophores arising from hyaline hyphae, with gregarious, ovoid to ellipsoidal conidia (Huang et al. 2018). Ecologically, this species is associated with a sexual morph of an ophioceras-like taxon on submerged wood and is different from those of F. bifurcatum on the larva of Noctuidae and F. subprimulinum isolated from soil. Phylogenetically, F. subprimulinum is sister to F. bifurcatum based on ITS phylogenetic analyses of Lecanicillium lineage, but it differs morphologically from F. bifurcatum because the latter has bifurcate stromata, cymbiform macroconidia and longer conidiophores. Colonies on PDA slow-growing, effuse or stellate, white, usually raising dome-shaped mycelial density with a sunken zone at the centrum, verrucose around the margin. Conidiophores not observed. Phialides lanceolate, occurring directly from the prostrate hyphae, solitary, gradually attenuated toward the apex. Two types of macro-and microconidia, aseptate, smooth-walled, one-celled, both of them existing singly or in pairs at the the apex of phialides. Macroconidia positioned at a right angle to the apex of phialides, straight, oblong-oval to fusiform. Microconidia oval to ellipsoidal.
Notes: Liangia sinensis, isolated from an entomopathogenic fungus B. yunnanensis, represents a well-supported monophyletic lineage in the family Cordycipitaceae (Fig. 1). The new genus Liangia with Lecanicillium-like asexual morph is proposed for the type species Lia. sinensis based on its phylogenetic placement. In this study, it appears more closely related to C. piperis (J.F. Bisch. & J.F. White) D. Johnson et al. and L. psalliotae clades by the five-gene phylogenetic analyses. The genus Liangia is morphologically similar to these two clades which possess asexual morph of Lecanicillium (Zare and Gams 2001;Bischoff and White 2004). However, it differs from the latter two groups by the shape and size of its colonies, phialides and conidia. Etymology: Named after China where the species is distributed.
Holotype: YHH 7455. Sexual morph: Undetermined. Asexual morph: Lecanicillium-like. Strains isolated from the stromata of Beauveria yunnanensis associated with the pupa of Lepidoptera. Colonies on PDA slow-growing, 28-34 mm in diameter after 14 days at 25 °C, effuse or stellate, white, usually raising dome-shaped mycelial density with a sunken zone at the centrum, verrucose around the margin. Reverse pale brown, causing a brown concentric ring outside of the inoculum. Hyphae hyaline, septate, branched, smooth-walled, and 0.7-2.4 µm wide. Phialides lanceolate, occurring directly from the prostrate hyphae, solitary, gradually attenuated toward the apex, 16.7-59.0 µm long, 0.7-1.6 µm wide at the base and 0.3-0.7 µm wide at the apex. Conidia existing in two types, macro-and microconidia, aseptate, hyaline, smooth-walled, one-celled, straight, both existing singly or in pairs at the apex of phialides. Macroconidia positioned at a right angle to the apex of phialides, oblong-oval to fusiform, 4.5-9.3 × 1.2-1.9 µm. Microconidia oval to ellipsoidal, 1.8-3.3 × 1. Notes: Liangia sinensis possesses Lecanicillium-like asexual morph and is characterized by white colonies forming a sunken zone at the centrum of dome-shaped mycelial density and verrucose around the margin, solitary and lanceolate phialides occurring directly from the prostrate hyphae, oblong-oval to fusiform macroconidia, and oval to ellipsoidal microconidia existing singly or in pairs at the apex of phialides.
It is similar to the two phylogenetically more closely related C. piperis and L. psalliotae clades with asexual morph of Lecanicillium (Zare and Gams 2001;Bischoff and White 2004). However, Lia. sinensis differs from C. piperis and L. psalliotae by its distinguished colonies, solitary and lanceolate phialides without conidiophores and oblong-oval to fusiform macroconidia. Cordyceps piperis, originally named T. piperis J.F. Bischoff & J.F. White, was reported to have the sexual morph of Torrubiella with sessile perithecial stromata which covered the corpses of scale insects attached to Piperaceae (Bischoff and White 2004). Lecanicillium psalliotae was originally described as Verticillium psalliotae Treschew which caused diseases of cultivated mushrooms (Treschew 1941), and later were widely discovered from insects, nematodes, soil, mushrooms, Rhopalomyces Corda and other fungi (Dayal and Barron 1970;Zare and Gams 2001;Yang et al. 2005). Liangia sinensis is distinctive for its isolates from the newly described cordycipitoid fungus B. yunnanensis parasitic on the lepidopteran pupa ).
In the five-gene phylogenetic tree, B. yunnanensis (exholotype living culture CCTCC AF 2018010 = YFCC 3105) is closely clustered with B. scarabaeidicola (Kobayasi) S.A. Rehner & Kepler, and remotely related to Lia. sinensis (Fig. 1, 2). In this study, there is no strong hyperparasitic evidence that Lia. sinensis grows on the stromata of B. yunnanensis. However, two strains of Lia. sinensis were truly isolated from the stromata of B. yunnanensis. The possibility that Lia. sinensis is a hyperparasitic fungus of B. yunnanensis requires confirmation.  Etymology: Named after the alpine locations where this species is distributed.
Habitat: On the larvae of Hepialus baimaensis (Hepialidae) buried in soil.
Notes: Samsoniella alpina has Isaria-like asexual morph and is characterized by irregularly branched synnemata, cylindrical or clavate stipes with white powdery heads, white to orange yellow, hairy and floccose colonies with light orange to orange-red colors, solitary or verticillate phialides with cylindrical to narrowly lageniform basal portion, fusiform or oval conidia.
Host: Larvae of Noctuidae. Notes: Samsoniella antleroides is characterized by fasciculate and antler-like stromata with oblate terminal branches, clavate to flake-like fertile parts, orange to orangered, superficial and fusiform perithecia, cylindrical asci with bola-shaped ascospores, light orange to orange-red colonies, having Isaria-like asexual conidiogenous structure, and on the larvae of Noctuidae buried in soil.
Phylogenetic analyses reveal that S. antleroides forms a sister lineage with S. tortricidae and S. cristata. Samsoniella antleroides resembles the latter two species in having stromata with terminal branches, superficial and fusiform perithecia, cylindrical asci with bola-shaped ascospores and Isaria-like asexual morph. However, it differs from S. cristata and S. tortricidae in the production of fasciculate and antler-like stromata with oblate terminal branches, clavate to flake-like fertile parts, conidiophores forming verticillate branches with shorter phialides in whorls of up to nine. Ecologically, S. antleroides is parasitic on the larvae of Noctuidae buried in soil and is different from S. cristata and S. tortricidae, both of which parasitize the pupae of Saturniidae in cocoons buried in soil and the pupae of Tortricidae in cocoons rolled in fallen leaves, respectively. Notes: Samsoniella cardinalis is characterized by scarlet stromata with clavate fertile parts, superficial perithecia, oblong-ovate to fusiform, cylindrical asci, bola-shaped ascospores, crater-shaped colonies with white to pale pink, having Isaria-like asexual conidiogenous structure, and on the pupae of Limacodidae in cocoons buried in soil.
Habitat: On the pupae of Saturniidae in cocoons buried in soil. Notes: Samsoniella cristata is characterized by solitary or two stromata, crista-like, reddish orange fertile parts, superficial and narrowly ovoid perithecia, cylindrical asci, bola-shaped ascospores, crater-shaped colonies with white to light orange colors, Isaria-like asexual conidiogenous structure, and on the pupae of Saturniidae in cocoons.
Host: Larvae and pupae of Lepidoptera. Notes: This fungus, named as Paecilomyces hepiali by Dai et al. (1989), was originally collected from the Baima Snow Mountain in Yunnan Province, China based on isolates from the larvae of H. armoricanus parasitized by O. sinensis. However, the name was effectively, but not formally published due to the failure of the authors to comply with the requirements of the Code for type indication, and the only cited material was a living culture (Dai et al. 2008;Turland et al. 2018). Paecilomyces hepiali was later validly published and the holotype IMM 82-2 was designated using a dried culture from the living culture 82-2 (ICMM 82-2) (Dai et al. 2008(Dai et al. , 2018a. Based on the original description, P. hepiali was morphologically similar to P. xylariiformis (Lloyd) Samson, originally named as I. xylariiformis Lloyd, but it differs in the globose or subglobose conidia with smaller size and the host of hepialid larvae (Dai et al. 1989). In addition, P. hepiali differed from I. farinosa (Holmsk.) Fr., currently recombined into C. farinosa, by the shape and arrangement of phialides, the shape of conidia, its host belonging to the genus Hepialus, and its habitat of an extremely cold area at an altitude of 4000-4500 m (Dai et al. 1989).
Paecilomyces xylariiformis, probably belonging to Isaria, is only known from dried type herbarium material no. 42613, and its phylogenetic analyses have not been conducted (Samson 1974;Luangsa-ard et al. 2005). Its generic status, and even so, higher taxonomic rank remain unresolved. Recent phylogenetic analyses together with our fivegene phylogeny of the family Cordycipitaceae show that C. farinosa belongs to the type genus Cordyceps of this family (Kepler et al. 2017;Mongkolsamrit et al. 2018). In our phylogenetic analyses, the holotype material ICMM 82-2 and seven other samples of P. hepiali were used to determined its systematic position. Our results show that the eight samples of P. hepiali group together with strong statistical support (BP = 80% and PP = 100%), are clustered within the recently established genus Samsoniella of Cordycipitaceae, and form a single clade related to an undescribed taxon Isaria sp. TNS 16333 (Fig. 1, 2). Consequently, P. hepiali is phylogenetically distinguished from C. farinosa which also produces Isaria-like asexual morph. Based on the strong phylogenetic and morphological evidence, a new combination, namely S. hepiali is proposed for P. hepiali.
Here, a redescription of S. hepiali is made on the basis of morphological observations of the ex-holotype living culture ICMM 82-2 and related samples collected in this study. Samsoniella hepiali has Isaria-like asexual morph and is characterized by branched or unbranched synnemata arising from the whole body of lepidopteran insects, cylindrical or clavate stipes with a powdery conidia at the apex, white to yellowish, moderately fast-growing colonies with white to yellowish colors, cottony, solitary conidiophores with cylindrical shape, solitary or verticillate phialides with cylindrical to narrowly lageniform basal portion, fusiform or oval conidia often in chains.
Samsoniella hepiali is morphologically similar to S. alpina and S. yunnanensis in the Isaria-like asexual conidiogenous structure, producing synnemata with powdery conidia at the apex. However, S. hepiali differs from S. alpina by its white to yellowish colonies, solitary conidiophores with phialides in whorls of two to five and longer phialides. It differs from S. yunnanensis because the latter has synnemata with orange to pink stipes, white colonies, solitary or verticillate conidiophores up to 23.5 μm long with phialides in whorls of two to seven. Ecologically, S. hepiali and S. alpina share similar host larvae of Hepialus, whereas S. hepiali has a wider lepidopteran species host range.
Mycobank: MB 833116; Fig. 15 Etymology: Named after the location Kunming City where the species was collected.
Habitat: On the pupa of Lepidoptera buried in soil. Distribution: Kunming City, China.
Notes: Samsoniella kunmingensis is characterized by solitary stromata, bifurcated, clavate fertile parts with reddish orange color, ateral sides usually have a longitudinal ditch without producing perithecia, superficial perithecia, narrowly ovoid to fusiform, and cylindrical asci with bolashaped ascospores.
Habitat: On the pupae of Lepidoptera in cocoons buried in soil.
Habitat: On the pupa of Limacodidae in a cocoon buried in soil.
Notes: Samsoniella ramosa is characterized by fascicular stromata, multi-branched, oblate or flaky stipes, fertile parts with no obvious boundary with stipes, superficial perithecia, narrowly ovoid to fusiform, floccose and crater-shaped colonies, having Isaria-like asexual conidiogenous structure, and on the pupa of Limacodidae in a cocoon buried in soil.
It is similar to its phylogenetically closely related species S. kunmingensis in producing superficial perithecia, narrowly ovoid to fusiform. However, S. ramosa is easily distinguished by its fascicular stromata, multi-branched, oblate or flaky stipes and fertile parts having no obvious boundary with stipes. Etymology: Named after the host belonging to the family Tortricidae (Lepidoptera).
Samsoniella tortricidae resembles the phylogenetic sister species S. cristata in producing stromata with terminal branches, subulate fertile parts, and Isaria-like asexual conidiogenous structure. However, it differs from S. cristata by its gregarious stromata up to 25-60 mm long, unbranched or dichotomous, white to pale pink cottony colonies, sporulating abundantly, longer phialides (3.6-42.4 μm). Ecologically, S. tortricidae is parasitic on the pupae of Tortricidae (Lepidoptera) in cocoons rolled in fallen leaves and is very different from S. cristata, which is parasitic on the pupae of Saturniidae in cocoons buried in soil. Notes: Samsoniella yunnanensis is characterized by gregarious synnemata with terminal branches, clavate to spatulate stipes with orange to pink colors, producing a mass of conidia toward the apex of synnemata, powdery and floccose, loose and hairy colonies, sporulating abundantly, having Isaria-like asexual conidiogenous structure, and it is associated with pupae of Limacodidae and Cordyceps spp.
Phylogenetically, three samples of S. yunnanensis group together with strong statistical support, and form a separate clade at the basal portion of Samsoniella lineage. It is similar to S. alpina and S. hepiali in producing a mass of conidia toward the apex synnemata with terminal branches and Isaria-like asexual conidiogenous structure. Additionally, none of these three fungal sexual morphs have been determined yet. However, it differs from the latter two by its orange to pink stipes, and associations with the pupae of Limacodidae in cocoons, Cordyceps sp. associated with the pupa of Lepidoptera, and C. cicadae associated with the nymphs of Cicadidae buried in soil. Etymology: Named after the location Yunnan Province where this species was collected.
Holotype: YHH 16988 Sexual morph: Undetermined. Asexual morph: Colonies on PDA fast-growing, 39-42 mm diameter in 14 days at 25 °C, convex, white to light yellow, with very low mycelial density, producing hyaline droplets on the felty aerial mycelium, generating radially distributed grooves.
Habitat: On A. waltergamsii associated with the spider on a dead stem.  Notes: Simplicillium yunnanense is characterized by white to light yellow colonies with very low mycelial density, convex, generating radially distributed grooves, solitary phialides, discrete, subulate, produing cylindrical conidia usually in chains at the apex of phialides, and on A. waltergamsii associated with the spider on the dead stem.
In our five-gene phylogenetic analyses (Fig. 1, 2 Gams. However, it differs from the latter two by its shorter phialides with subulate shape and producing cylindrical conidia usually in chains at the apex of phialides. Simplicillium lanosoniveum and Sim. obclavatum have much narrower and longer phialides, producing respectively oval or ellipsoidal to subcylindrical, obclavate to ellipsoidal conidia, and form respectively globose heads and short imbricate chains at the apex of phialides (Zare and Gams 2001). Ecologically, Sim. yunnanense can be differentiated due to its association with synnemata of A. waltergamsii parasitizing the spider.

Discussion
Many high-level phylogenetic classifications for entomopathogenic fungi have been undertaken, thus more and more available molecular data can be efficiently used to facilitate systematics and evolutionary biology of cordycipitoid fungi (Sung et al. 2007;Chaverri et al. 2008;Kepler et al. 2013Kepler et al. , 2014Kepler et al. , 2017Quandt et al. 2014;Maharachchikumbura et al. 2015;Hongsanan et al. 2017;Luangsa-ard et al. 2017;Mongkolsamrit et al. 2018). In this study, we focused on the phylogenetic investigation of the family Cordycipitaceae, with special emphasis on species collected from Yunnan Province, China. Our phylogenetic study supports recognition of the genera Cordyceps, Samsoniella, Lecanicillium and Simplicillium, as previously reported (Kepler et al. 2017;Mongkolsamrit et al. 2018). We proposed two new genera Flavocillium and Liangia, 16 new species and four new combinations in the family Cordycipitaceae.
The genus Flavocillium was erected to accommodate F. bifurcatum, F. acerosium, F. primulinium, and F. subprimulinium. Even though Flavocillium is morphologically similar to other Lecanicillium species in conidiophores, phialides and two types of conidia, the genus is sufficiently distinct by possessing yellowish stromata with a furcate terminal branch, contorted fertile parts, and colonies that usually produce pastel yellow pigment (Zare and Gams 2001;Kaifuchi et al. 2013;Huang et al. 2018;Su et al. 2019). In addition, Flavocillium is distinguished from phylogenetically close relatives Engyodontium and Parengyodontium because the latter two genera usually produce white colonies, conidiiferous rachids with denticles on phialides, and terminal fertile regions that are zigzag-shaped (Gams et al. 1984;Tsang et al. 2016). Liangia is established for the new species Lia. sinensis isolated from the cordycipitoid fungus B. yunnanensis. Liangia is more closely related to C. piperis and L. psalliotae clades in the five-gene phylogenetic analyses. However, this genus differs morphologically from C. piperis that produces the Verticillium-like anamorph with verticillate conidiophores and phialides, subcylindrical conidia aggregating into heads and conjoined polyhedral crystals (Bischoff and White 2004). Liangia is similar to L. psalliotae in sharing the Lecanicillium-like asexual morph, but it differs from the latter that produces erect conidiophores, relatively short verticillate phialides, short-ellipsoidal conidia formed in heads and octahedral crystals (Zare and Gams 2001). The new genera Flavocillium and Liangia can be distinguished from each other by having distinct morphological characteristics and phylogenetic positions.
The economically and medically significant fungus P. hepiali was reexamined and assigned to the genus Samsoniella based on study of the holotype IMM 82-2 and its ex-holotype living culture, as well as seven other samples of P. hepiali. The systematic position of P. hepiali is most appropriate in the genus Samsoniella. Therefore, the new taxonomic combination S. hepiali is proposed for P. hepiali. Collections of unknown identity are found to represent nine new species of Samsoniella, which are named S. alpina, S. antleroides, S. cardinalis, S. cristata, S. kunmingensis, S. lanmaoa, S. ramosa, S. tortricidae and S. yunnanensis. Four new species of Cordyceps are described and named C. subtenuipes, C. shuifuensis, C. chaetoclavata and C. cocoonihabita. Two isolations from A. waltergamsii associated with the spider on the dead stem represent a new species in the genus Simplicillium, viz. Sim. yunnanense. All of the above species are recognized as new members of the family Cordycipitaceae by well-supported morphological and molecular phylogenetic evidence.
The asexual genus Lecanicillium is typified by L. lecanii with the sexual morph T. confragosa and previously contained 32 species Gams 2001, 2008;Sukarno et al. 2009;Crous et al. 2018;Huang et al. 2018;Su et al. 2019;Zhou et al. 2018). However, the recent taxonomic revision rejected L. lecanii, the type species of Lecanicillium, and considered that it was a synonym of Akanthomyces (Kepler et al. 2017). This treatment seeks to harmonize competing names by principles of priority, recognition of monophyletic groups, and the practical usage of the affected taxa. Based on this, Akanthomyces was proposed to be maintained and Lecanicillium was rejected, although the generic name Lecanicillium was still being used thereafter (Crous et al. 2018;Huang et al. 2018;Su et al. 2019;Zhou et al. 2018). Species of different lineages may have similar micromorphological characteristics like those of Lecanicillium in the family Cordycipitaceae. Unfortunately, many species in the Lecanicillium lineage are published with singular gene data, such as ITS sequences. Few multigene sequences are available in online databases. Reconstructing the credible phylogenetic framework of Lecanicillium clades in the family Cordycipitaceae is difficult due to a lack of large-scale multigene sequence sampling. Thus, in this study, the phylogenetic tree of Lecanicillium inferred from ITS sequences includes eight clades, which does not match those of the tree generated from five-gene data because of differentiated available data sampling. To be prudent, we did not make major revisions to the Lecanicillium lineage but only added two genera, Flavocillium and Liangia, based on their monophyly and distinct morphological characteristics in the family Cordycipitaceae. A credible phylogenetic framework of Lecanicillium species, which have not been assigned appropriate generic names, will require more future extensive multigene taxon sampling.
Phylogenetic classifcations of entomopathogenic fungi showed that most diagnostic characteristics used in current classifcations of cordycepitoid fungi (e.g., arrangement of perithecia, ascospores fragmentation, conidiogenous structures, conidial shape and size) are not phylogenetically informative (Sung et al. 2007;Kepler et al. 2013Kepler et al. , 2017Ban et al. 2015;Mongkolsamrit et al. 2018). However, the characteristics that are most consistent with the phylogeny are texture, pigmentation and morphology of the stromata and synnemata. Even so, these macro-and micro-morphological characteristics could aid the identification of Cordyceps, Isaria-like and Lecanicillium-like fungi. Sexual morphs of Cordyceps are characterized by fleshy stromata, red to orange colors, superficial perithecia, asci cylindrical with thickened ascus apex, ascospores usually cylindrical and multiseptate. These are very similar to those of Samsoniella, which mainly have lepidopteran hosts. Previous studies of cordycipitoid fungi as well as our study show that both Samsoniella and Cordyceps species produce similar asexual conidiogenous structures (Samson 1974;Mongkolsamrit et al. 2018). Samsoniella and Cordyceps share similar Isaria-like asexual morphs that produce branched and white to orange synnemata, a dry mass of white to cream conidia on the synnemata, flask-shaped phialides that are produced in whorls, conidia with divergent chains. Therefore, the C. farinosa morphology is not diagnostic and represents a polyphyletic species complex as exemplified by the isolates delimited as S. alboaurantium (G. Sm.) Mongkolsamrit et al. (Kepler et al. 2017;Mongkolsamrit et al. 2018).
A review of the taxonomic history of Cordyceps concluded that Cordyceps is the oldest accepted generic name in the family Cordycipitaceae . Based on the cylindrical shape of stroma, pre-Linnaean literature of the 17th and early eighteenth centuries had recorded C. militaris. It is noteworthy that Cordyceps has a much longer history and culture in China. The famous Chinese medicine monograph "Shennong's Materia Medica" (Qin and Han Dynasties, second century BC) recorded the white muscardin silkworms infected by B. bassiana as a medicine. The archaeology of Haihun marquis (Western Han Dynasty, first century AD) discovered Cordyceps sp. in He Liu's funerary objects, proving that Cordyceps sp. had been used for health care in China as early as 2075 years ago. The "Mister Lei's Treatise on Processing Drugs" (Southern and Northern Dynasties, 5th Century AD) recorded I. cicadae Miq. as a traditional medicine. Tibetan Materia Medica "Medical King's Drugs for Medicine" (Tibetan Empire, 8th Century AD) recorded O. sinensis as a medicine.
In the phylogenetic classification of cordycipitoid fungi, the desire to preserve the term "cordyceps" within the family Ophiocordycipitaceae to reflect the cultural and economic importance of O. sinensis was expressed (Sung et al. 2007). This taxonomic revision ultimately benefits humanity, especially in Asia. Samsoniella hepiali (syn. P. hepiali) is also termed "cordyceps", and it is internationally known. Based on the above, we suggest that the Chinese name "鳞翅虫草 属" (Lín Chì Chóng Cǎo Shǔ), be given to Samsoniella, taking into account the similarity of its morphological and ecological characteristics with Cordyceps and practical usage.
Samsoniella hepiali is a very important fungus to humans, due to its therapeutic effects in cardiovascular, respiratory disorders, immunomodulatory, hyposexuality, hyperglycemia, renal disorder and antitumor conditions (Lou et al. 1986;Huang et al. 1988;Wang and Huang 1988;Dai et al. 1989;Zou and Huang 1993;Xiang et al. 2006;Jiang et al. 2010). The Ministry of Health of the P. R. China issued a new drug certificate (WYZZ2-67 05) in July, 1987 and listed the S. hepiali strain Cs-4 as a protected and confidential strain. The product of strain Cs-4, Jinshuibao capsule, was introduced into the market in 1987. The Ministry of Health of the P. R. China issued File No. 84 on 23 March 2001 and approved S. hepiali mycelia to be used as a stand-alone or a component of health foods (equivalent to dietary supplements in other countries) (Dai et al. 2018b). Thus, S. hepiali is widely used as a medicinal and edible cordycipitoid fungus, creating an annual economic value of approximately 10 billion RMB in China. In addition to the Jinshuibao capsule, over 260 healthcare products have been developed with S. hepiali as a raw material. Its therapeutic effects have been demonstrated and are now widely recognized by doctors and patients. Many companies have put these products into Chinese markets and globally exported them to nearly 80 countries or regions as medicine and dietary supplements, including northeastern and southeastern Asia, the United States of America, Canada, Australia, New Zealand and other countries (Dai et al. 2018b). Samsoniella hepiali is economically, medicinally and culturally important, and share the morphologically and ecologically similar characteristics with Cordyceps. Based on its significant contribution as "cordyceps", here we strongly suggest that the Chinese name "蝙蝠蛾虫草" (Biān Fú É Chóng Cǎo), be given to this cordycipitoid fungus, which will allow for the convenient and unambiguous communication among the biomedical and health industries of China.