Abstract

Background

   The entomopathogenic mushroom Cordyceps militaris is an important
   medicinal and food resource owing to its various medicinal components
   and pharmacological effects. However, the high frequency of strain
   degeneration during subculture seriously restricts the large-scale
   production of C. militaris, and the mechanism underlying strain
   degeneration remains unclear. In this study, we artificially cultured
   C. militaris for six generations and compared changes during fruiting
   body growth. The transcriptome of six generations of C. militaris
   strains were sequenced with the Illumine Hiseq4000.

Results

   The subcultured C. militaris strains degenerated beginning at the third
   generation, with incomplete fruiting body growth beginning at the
   fourth generation. Over 9,015 unigenes and 731 new genes were
   identified. In addition, 35,323 alternative splicing (AS) events were
   detected in all samples, and more AS events occurred in the second,
   fourth and sixth generations. Compared with the first generation, the
   third generation (degenerated strain) included 2,498 differentially
   expressed genes (DEGs) including 1,729 up-regulated and 769
   down-regulated genes. This number was higher than the number of DEGs in
   the second (1,892 DEGs), fourth (2,006 DEGs), fifth (2,273 DEGs) and
   sixth (2,188 DEGs) generations. Validation of RNA-seq by qRT-PCR showed
   that the expression patterns of 51 DEGs were in accordance with the
   transcriptome data.

Conclusion

   Our results suggest that the mechanism of C. militaris strain
   degeneration is associated with gene involved in toxin biosynthesis,
   energy metabolism, and DNA methylation and chromosome remodeling.

Introduction

   Cordyceps militaris, a tonic herb used in traditional Chinese medicine,
   is an economically valuable, edible entomopathogenic mushroom that is
   used clinically as a substitute of Cordyceps sinensis owing to its
   similar chemical components and pharmacological activities [[30]1]. C.
   militaris contains several pharmacologically active ingredients, such
   as cordycepin, adenosine, polysaccharide, ergosterol, that exhibit
   significant biological activities known to protect and improve lung and
   kidney function [[31]2], and to immunomodulatory [[32]1,[33]3],
   antioxidant [[34]4], anti-tumor [[35]5,[36]6,[37]7],anti-inflammatory
   [[38]8], and hypotensive effects [[39]9].

   Because naturally occurring C. militaris is rare, cultivated C.
   militaris fruiting bodies are currently commercially available as
   medicinal materials and health food products in China, Korea, and
   Southeast Asia [[40]10]. This artificial cultivation has improved the
   imbalance between the supply and the demand of wild C. militaris
   [[41]11]. However, the high frequency of strain degeneration during
   subculture and preservationof C. militaris has limited its large-scale
   production and industrial process [[42]12]. Strain degeneration results
   in the significant fluctuations in sporulation quantity, deficiencies
   in fruiting body formation, reductions in secondary metabolite yields,
   and other irreversible hereditary phenotypes, leadings to considerable
   economic losses [[43]13].The strain degeneration of C. militaris
   involves complex regulatory processes and involves many factors
   [[44]14]. Studies have shown that mating type change, DNA methylation,
   genetic mutations, harmful substance accumulation, and virus infections
   are all precipitating factors of C. militaris degeneration [[45]15].

   The genome sequence of C. militaris and the transcriptomes of the
   mycelium and fruiting body have been analyzed by next-generation
   sequencing (NGS) [[46]16,[47]17]. However, the molecular mechanism of
   strain degeneration remains unclear. In this study, we cultured C.
   militaris for six generations and compared changes in fruiting body
   growth during subculture. We also analyzed the transcriptomes of
   different generations of C. militaris using Illumine Hiseq4000
   technology. Subsequently, the differentially expressed genes (DEGs) as
   determined by RNA-Seq were analyzed using Gene Ontology (GO) and Kyoto
   Encyclopedia of Genes and Genomes (KEGG) databases and were validated
   by quantitative real-time PCR (qRT-PCR). Our results provide a better
   understanding the transcriptomic changes that occur in C. militaris
   during subculture and the underlying molecular mechanism of strain
   degeneration.

Materials and methods

Strain and sample preparation

   Wild-type of C. militaris, designated YCC, was collected from Maoshan
   hilly area (at altitude 267.5 m) without specific permissions, Jiangsu
   province, China and isolated by tissue separation in the asexual phase
   by the Laboratory of Hi-Tech Processing of Sericultural Resources,
   Sericultural Research Institute, Chinese Academy of Agricultural
   Sciences, China.

   For the collection of different generations following asexual
   development, the strain was inoculated onto potato dextrose agar (PDA)
   plates (20% potato, 2% dextrose, 1.5% agar and 1% peptone, w/v) and
   incubated at 23°C on a shaker at 150 rpm for 7 d in the dark. Mycelia
   were inoculated into rice medium, cultivated in the dark at 23°C for 10
   d, and then kept at 23°C under a 17:7 h dark/light cycle for fruiting
   body production [[48]18]. The mycelia and fruiting body of this strain
   were subcultured for the acquisition of second, third, fourth, fifth,
   and sixth generations, designated YCCZ2, YCCZ3, YCCZ4, YCCZ5, and
   YCCZ6, respectively. Mycelium from all six generations were collected
   for DNA and RNA extraction.

RNA extraction and sequencing

   Total RNA from each sample was extracted using RNeasy Plant Mini kit
   (Qiagen Co. LtD., Beijing, China) and the residual genomic DNA was
   digested using RNase-free DNase I according to the manufacturer’s
   protocol. Poly (A) mRNA was enriched using oligo (dT) beads and
   fragmented using fragmentation buffer. Finally, 100 ng purified and
   enriched mRNA was used to construct a cDNA library for each sample
   using NEBNext® Ultra^TM RNA Library Prep Kit for Illumina (New England
   Biolabs, Ipswich, MA, USA). cDNA fragments of 200 bps (± 25 bps) were
   selected and purified by gel-electrophoresis and used as templates for
   amplification with PCR for end- repair and poly (A) addition. Purified
   library products were evaluated using the Agilent 2200 Tape Station and
   Qubit 2.0 software (Life Technologies, Carlsbad, CA, USA). RNA-Seq was
   performed at Gene Denovo Co., Ltd. (Shenzhen, China) using the HiSeq TM
   4000 (Illumina, San Diego, CA, USA).

Transcriptome assembly and function annotation

   Prior to sequencing, raw data were filtered to produce high-quality
   clean data. Clean reads were then assembled de novo into longer contigs
   based on overlapping regions using the Trinity platform
   ([49]http://trinityrnaseq.sourceforge.net/) [[50]19]. All subsequent
   analyses were performed using clean data. For annotation, clean data
   were mapped to the C. militaris genomic data (BioProject acession no.
   PRJNA225510) from the NCBI transcriptome reference database.

   All splice junction sites of the same gene (≥ 5 reads) were determined
   and compared with the reference splice junction sites (≤ 1 base) using
   TopHat align to distinguish new alternative splicing (AS) events. DEGs
   were filtered and identified according to the edgeR criteria
   ([51]http://www.Bioconductor.org/packages/release/bioc/html/edgeR.html)
   . Functional annotation (GO terms) were downloaded from Uniprot
   database ([52]http://www.uniprot.org/uniprot). For GO enrichment
   analysis, GO annotations for each DEG were retrieved by mapping to GO
   terms in the database at [53]http://www.geneontology.org. For KEGG
   pathway analysis, KEGG orthology terms for DEGs were retrieved from the
   KEGG pathway database ([54]http://www.genome.jp/kegg/). Cluster
   analysis of gene expression patterns was performed using cluster
   software [[55]20] and Java Treeview software [[56]21]. All expressed
   genes in the current transcriptomes were annotated based on BLAST
   homology searches and searched against the Swiss-Prot and TrEMBL
   databases by double-direction BLAST. To further explore the function of
   DEGs in different samples, KEGG enrichment analyses were performed
   using hypergeometric tests with the Blastall software.

Validation of RNA-Seq by quantitative real-time PCR

   qRT-PCR was carried out to validate the quality of RNA-Seq data. Total
   RNA was extracted as described above. Each RNA sample was treated with
   RNase-free DNase I (TaKaRa, Shiga, Japan) following the manufacturer's
   protocol to remove any residual genomic DNA. DNase I-treated RNA (2 mg)
   was subjected to reverse transcriptase using oligo (dT) primer and
   PrimeScript^TM Reverse Transcriptase (TaKaRa, Shiga, Japan) according
   to the manufacturer's protocol. Total RNA (2 μg) was used to synthesize
   cDNA with PrimeScript™ RT reagent Kit (Perfect Real Time, TaKaRa,
   Japan). The C. militaris housekeeping gene, glyceraldehyde-phosphate
   dehydrogenase (Cmgapdh), was used as an internal control for
   normalization. Primers for the qRT-PCR of 51 DEGs were designed with
   Premier 6.0 software and are shown in [57]S1 Table. Three biological
   replicates were performed per sample.

Data analysis

   Sequence similarity was analyzed using Blast software. Multiple
   sequence alignment analysis was carried out with Clustalx W software.
   All experiments were repeated at least three times, and the results are
   expressed as mean ± S.D. Statistical evaluation was done using ANOVA
   (SPSS 18.0), with p < 0.05 considered significant.

Results

Changes in the morphological characteristics of the C. militaris fruiting
body in different generations

   The growth of C. militaris fruiting body is an important morphological
   characteristics in evaluating strain degeneration during subculture. C.
   militaris was subcultured in rice medium for six generations, and
   changes in morphological characteristics of fruiting body were observed
   after 40 days of cultivation ([58]Fig 1). In the third generation, the
   fruiting body became stronger and shorter, while the size of fruiting
   body was significantly reduced in the fourth generation. The strain
   appeared to be completely degenerated in the fifth generation, and only
   mycelia grew in the sixth generation. As shown in [59]Fig 1, the
   subculture of C. militaris induced strain degeneration beginning in the
   third generation.

Fig 1. Changes in the C. militaris fruiting body at different generations.

   [60]Fig 1
   [61]Open in a new tab

Transcriptome sequencing and assembly

   As shown in [62]Table 1, the average number of clean reads per sample
   was 53,118,184. After quality filtering, over 6×10^9 bps of clean data
   was obtained across the different samples ([63]S2 Table), and more than
   98% HQ clean reads were identified ([64]S1 Fig). About 90% reads were
   mapped to the C. militaris genome sequence ([65]S3 Table). In total,
   9,651 genes were detected in all transcriptomes, including 9,015 known
   genes and 731 novel genes. The number of new gene in each generation
   from YCCZ1 to YCCZ6 was 668, 705, 699, 704, 702 and 699, respectively
   ([66]Table 1). The six samples showed similar matching results, with
   ~90% of reads matching the predicted genes in the genome and ~70% being
   unique matches ([67]S2 Fig). The above results revealed that our sample
   data were reasonable with good correlations among biological replicates
   and that sequencing data could be used for following analyses.

Table 1. Summary of sequencing data utilized in this study.

   Sample Clean Reads HQ Clean reads Clean Base Total mapped Total mapped
   Ratio (%) Unique Match(%) Known Gene New Gene All Gene
   YCCZ1 41009930 40623584 6062919977 11603568 70.23 70.12 8586 (88.96%)
   668 9254
   YCCZ2 59291792 58701420 8755948868 11607702 70.30 70.17 8735 (90.51%)
   705 9440
   YCCZ3 47879596 47274196 7052765933 14351858 69.17 69.04 8714 (90.29%)
   699 9413
   YCCZ4 56986574 56336928 8406700715 16735019 69.68 69.54 8745 (90.61%)
   704 9449
   YCCZ5 52911126 52298678 7800954755 15641003 69.90 69.77 8700 (90.15%)
   702 9402
   YCCZ6 60630086 60093188 8971315366 17870079 69.05 68.89 8746 (90.62%)
   699 9445
   [68]Open in a new tab

   Note: Clean Reads = Raw Reads—Adapter—Low Quality–High N rate

   HQ Clean Reads = Raw Reads—Clean Reads

   Known Gene Percentage = number of detected / total genes in reference
   genome.

Analyses of differentially expressed genes (DEGs)

   Compared with YCCZ1, 1,892 DEGs were identified in YCCZ2 (1,253
   up-regulated and 639 down-regulated), 2,498 in YCCZ3 (1,729
   up-regulated and 769 down-regulated), 2,006 in YCCZ4 (1,511
   up-regulated and 495 down-regulated), 2,273 in YCCZ5 (1,437
   up-regulated and 836 down-regulated) and 2,188 in YCCZ6 (1,602
   up-regulated and 586 down-regulated) ([69]Fig 2A). The most DEGs were
   thus observed in the third generation, when the C. militaris fruiting
   body began to experience abnormal growth ([70]Fig 1), indicating that
   these DEGs may play key roles in strain degeneration. In addition, a
   scatter plot was protracted based on DEGs analyses. Compared with
   YCCZ1, difference in expression levels of the DEGs in YCCZ3 and YCCZ5
   was significantly higher than those in YCCZ1 and YCCZ2 ([71]Fig 2B–Fig
   2F). Furthermore, a correlation heat map (CHM) was constructed and
   sample cluster analysis was performed based on DEGs in different
   samples. The heat map of significant DEGs shows the relationship of
   samples YCCZ1 to YCCZ6 ([72]Fig 3). Taken together, all results suggest
   that these specific DEGs may be involved in the strain degeneration
   progress.

Fig 2. Differentially expressed genes (DEGs) analyses.

   [73]Fig 2
   [74]Open in a new tab

   Note: (A) DEGs statistics of different samples. (B) Scatter plot of
   YCCZ1-YCCZ2. (C) Scatter plot of YCCZ1-YCCZ3. (D) Scatter plot of
   YCCZ1-YCCZ4. (E) Scatter plot of YCCZ1-YCCZ5. (F) Scatter plot of
   YCCZ1-YCCZ6.

Fig 3. DEG-based correlation heat map (CHM) and sample cluster analysis.

   Fig 3
   [75]Open in a new tab

GO and KEGG pathway analyses of AS genes

   GO analysis was performed to summarize and explore the functional
   categories of the genes that underwent AS in different samples. GO
   terms were annotated for a total of 5,014 AS genes in YCCZ1, 6,230 in
   YCCZ2, 5,638 in YCCZ3, 6,170 in YCCZ4, 5,951 in YCCZ5 and 6,320 in
   YCCZ6 ([76]S3 Fig). The Intergenic (10,863) and IR (5,222) AS events
   predominated, accounting for 30.8% and 14.8%, respectively, of all AS
   events. The number of AS genes in YCCZ2, YCCZ4 and YCCZ6 was higher
   than those in other samples. The proportions of enriched GO terms among
   AS genes were globally similar between YCCZ1 (wild-type) and YCCZ5
   (degenerated) based on biological process, molecular function, and
   cellular component ontolopies ([77]Fig 4). For the biological processes
   category, genes with AS events were predominantly enriched in GO terms
   that were relevant to cellular process and metabolic process. For the
   molecular function category, most AS genes were annotated with the term
   binding, followed by the term catalytic activity.

Fig 4. GO classification map of YCCZ1 vs. YCCZ5.

   [78]Fig 4
   [79]Open in a new tab

   Moreover, 6,944 AS genes were annotated with KEGG pathways information
   ([80]Table 2, [81]S4 Fig). Enriched pathway analysis showed that these
   genes were significantly enriched in 17 pathways mainly relating to
   antigen processing and presentation, cell adhesion molecules,
   phagosome, endocytosis, and natural killer cell-mediated cytotoxicity.

Table 2. Enrichment KEGG pathway analysis.

   list Pathway DEGs genes with pathway annotion (17) All genes with
   pathway annotation (6944) P value Q value Pathway ID
   1 Antigen processing and presentation 6(35.29%) 81(1.17%) 0.000000
   0.000001 ko04612
   2 Cell adhesion molecules (CAMs) 6(35.29%) 159(2.29%) 0.000001 0.000016
   ko04514
   3 Phagosome 6(35.29%) 168(2.42%) 0.000002 0.000016 ko04145
   4 Endocytosis 6(35.29%) 231(3.33) 0.000012 0.000074 ko04144
   5 Natural killer cell mediated cytotoxicity 5(29.41%) 137(1.97%)
   0.000014 0.000074 ko04650
   6 Complement and coagulation cascades 3(17.65%) 77(1.11%) 0.000797
   0.003454 ko04610
   7 Regulation of actin cytoskeleton 3(17.65%) 216(3.11) 0.014621
   0.054308 ko04810
   8 Pancreatic secretion 2(11.76%) 104(1.5%) 0.026100 0.084825 ko04972
   9 Oxidatie phosphorylation 2(11.76%) 141(2.03%) 0.045622 0.131797
   ko00190
   10 Vitamin digestion and absorption 1(5.88%) 24(0.35%) 0.057223
   0.148780 ko04977
   11 Nicotinate and nicotinnamide metabolism 1(5.88%) 32(0.46%) 0.075602
   0.178696 ko00760
   12 Fat digestion and absorption 1(5.88%) 39(0.56%) 0.091407 0.194538
   ko04975
   [82]Open in a new tab

Validation of DEGs by qRT-PCR

   The expression of 51 DEGs was validated using qPCR, as shown in [83]Fig
   5. According to qRT-PCR, the DEG expression levels were consistent with
   those of obtained using RNA-Seq. Among these genes, 32 genes were
   up-regulated and 13 were down-regulated. Functional relative analysis
   shown that 15 of these genes are involved in toxin biosynthesis and
   detoxification ([84]Fig 5C), 14 genes are related to carbohydrate and
   energy metabolism, nine genes are involved in DNA methylation and
   chromosome remodeling ([85]Fig 5A), eight genes are involved in
   biosynthesis of secondary metabolites ([86]Fig 5B), and six genes are
   involved in fruiting body formation, sexual development and
   light-induced brown film formation ([87]Fig 5D). These results suggest
   that C. militaris strain degeneration involves genes related to toxin
   biosynthesis, energy metabolism, DNA methylation, and chromosome
   remodeling.

Fig 5. Validation of DEGs expression by qRT-PCR.

   [88]Fig 5
   [89]Open in a new tab

   (A) Genes related to DNA methylation, chromosome remodeling, mitosis,
   and meiosis. (B) Genes related to fruiting body formation, sexual
   development, light-induced brown film formation, and secondary
   metabolites biosynthesis. (C) Genes related to toxin biosynthesis and
   detoxification, and transmembrane transport. (D) Genes related to cell
   growth and development, cell apoptosis and autophagy, and macro
   molecular metabolism.

Discussion

   C. militaris,a model fungus belonging to the Ascomycetes,is an
   entomogenous fungus that forms a fruiting body on several types of
   media, such as silkworm pupa, solid rice medium, germinated soybean
   medium, and soybean broth. It also forms mycelia during submerged
   fermentation, producing several bioactive substances [[90]19, [91]22].

   Irreversible C. militaris strain degeneration is a common phenomenon
   that occurs with high frequency during the process of subculture and
   preservation. Such degeneration seriously affects large-scale
   industrialized production of C. militaris, leading to considerable
   economic losses [[92]23]. There are many factors that may lead to
   fungal degeneration, including gene mutations, changes in mating type,
   DNA methylation, and fungal and viral infections [[93]24]. Our previous
   work indicated that mutations in the 18S rRNA gene and mating-type
   (MAT) region, as well as down-regulated of CmMAT gene expression
   levels, may play important roles in C. militaris degeneration [[94]25].
   Quantitative real-time PCR analysis detected no CmMAT1-2-1 gene
   expression in the degenerated strain. Expression levels of the
   CmMAT1-1-1 and CmMAT1-1-2 genes were significantly down-regulated to
   only 7.5% and 4.4%, respectively, that of the wild-type strain.

   The C. militaris genome (147 × coverage) is predicted to have a total
   genome size of 32.2 Mb and over 9,684 genes [[95]17]. In this study,
   9,746 genes were detected, including 731 novel genes, which fulfilled
   the criterion for it being referred to as the C. militaris genome,
   suggesting that the genome size and gene number in C. militaris is
   similar to those of Metarhizium anisopliae (10,582 genes) [[96]26] and
   Metarhizium acridum (9,849 genes) [[97]27]. In addition, over 5,000
   novel AS events of seven AS types were detected in each of the
   subcultured strains, indicating significantly higher rates of AS than
   in that observed in the wild-type strain. AS is an important mechanism
   for regulating gene expression and generating proteome diversity
   [[98]28, [99]29]. Previous studies have shown that AS plays a decisive
   role in the generation of receptor diversity and regulation of growth
   and development [[100]30]. Many genetic diseases have been closely
   linked to higher than normal rates of AS [[101]31]. Therefore, we
   speculated the higher AS rates in filamentous fungi might be involved
   in the progression of strain degeneration.

   Gene mutation [[102]32], methylation modification [[103]33], and DNA
   recombination can alter a strain’s genotype and can induce strain
   degeneration. In this study, we characterized and manually annotated
   the functions of four DEGs involved in methylation modification and in
   DNA recombination and repair. Methyltransferase type 11 (CCM_00251) and
   6-O-methylguanine-DNA methyltransferase (CCM_02107) were significantly
   up-regulated in later generations and are crucial for genome stability,
   preventing mismatch during DNA replication and transcription [[104]34,
   [105]35]. Two DNA repair genes, DNA excision repair protein (CCM_00249)
   and DNA double-strand break repair/VJ recombinationXRCC4 (CCM_04567),
   were also up-regulated in later generations.

   Degenerated strains exhibit traits that are generally heritable,
   including significantly reduced sporulation, inability to form normal
   fruiting bodies, and significantly reduced secondary metabolites
   contents. Fruiting body and light-induced brown film formation
   areimportant characteristics that are altered in C. militaris strain
   degeneration [[106]14]. Here, we analyzed the DEGs involved in fruiting
   body and light-induced brown film formation and found that the
   expression of α-1,3-mannosyltransferaseAlg3 (CCM_04231) was
   up-regulated while that of sexual development activator VeA
   (CCM_04531)was down-regulated. The expression of light-induced brown
   film formation-related genes phosducin I (CCM_05237) and phosducin II
   (CCM_09459) were significantly up-regulated beginning at the second
   generation.

   Cordycepin, adenosine, polysaccharides, and ergosterol are the major
   bioactive constituents important in industrial cultivation [[107]16,
   [108]36] speculated genes encoding ribonucleotide reductase, adenosine
   kinase, AMP deaminase, pyruvate kinase, 5’-nucleotidase among others
   were involved in the putative cordycepin metabolism pathway. This study
   showed that the expression of the genes encoding s-adenosylhomocysteine
   nucleosidase (CCM_02372) and oxidordeuctase (CCM_02761) was
   significantly down-regulated, and that of genes encoding adenine
   nucleotide alpha hydrolases like (CCM_07740) andadenine nucleotide
   alpha hydrolases like (CCM_08422) were significantly up-regulated
   during the degeneration progress. Ergosterol is one of the main
   components of the fungal cell membrane. The genes encoding
   dimethylallyl tryptophan synthase (CCM_04410), cytochrome P450 51
   (CYP51, CCM_05535), cytochrome P450 61(CYP61, CCM_02962) were
   down-regulated, while that encoding lanosterol synthase (CCM_09526) was
   up-regulated during strain degeneration. Dimethylallyl tryptophan
   synthase is a key regulator of ergosterol synthesis [[109]37, [110]38].
   CYP51 and CYP61 are conserved members of P450 family and play important
   role in the biosynthesis of ergosterol [[111]17]. qRT-PCR
   resultssuggested that the biosynthesis of ergosterol reduced with
   strain degenerations. C. militaris polysaccharidesare not only
   important immune regulators, but also exhibit antioxidant,
   antibacterial, antitumor, and antivirus activities in addition to other
   biological activities [[112]1]. Several genes are related to the
   metabolism of C. militaris polysaccharide, including1,4-α-glucan
   branching enzyme(CCM_03369), α-N-acetylglucosaminidase (CCM_04090),
   mannan endo-1,6-α-mannosidase (CCM_05709), sorbitol dehydrogenase
   (CCM_06561), mannosidase MsdS (CCM_08733), and sorbitol utilization
   protein (CCM_09007)[[113]39].

   Toxic substances such as mycotoxins, active oxygen and other
   nonnutritional xenobiotic compounds, naturally exist in the environment
   and can be harmful to organisms [[114]40]. Some scholars have
   speculated that accumulation of toxin and active oxygen molecules may
   cause fungal strain degeneration [[115]14]. Here, the expression of
   several genes involved in detoxification was up-regulated during strain
   degeneration, including that encoding streptothricin-acetyltransferase
   (CCM_00152), which degrades streptothricin [[116]41];
   gamma-glutamyltranspeptidase (CCM_02065), which reduces glutathione
   [[117]41]; MFS multidrug transporter (CCM_02974), which confers
   resistance to antibiotics [[118]42]; glutathione S-transferase
   (CCM_03461), which processes pesticides, heavy metals, fluoride and
   eliminating reactive oxygen species (ROS) [[119]43,[120]44]; 30 kDa
   heat shock protein (CCM_06821), which is involved in stress response,
   signal transduction, and xenobiotic compounds metabolism [[121]45]; and
   alcohol dehydrogenase (CCM_09345), which ameliorates the harmful
   effects of high concentration of ethanol [[122]46]. However, expression
   of the gene encoding heavy metal tolerance protein (CCM_06182), which
   binds heavy metals ions, was down-regulated during strain degeneration
   [[123]47]. In addition, levels of non-nutritional xenobiotic compounds
   increased during strain degeneration induced by subculture.

   In contrast, expression of genes related to the metabolism of
   carbohydrate, lipid, protein, amino acid, nucleic acid, and nucleotide
   was significantly up-regulated during strain degeneration. These
   included the genes encoding mitochondrial hypoxia responsive protein
   (CCM_05400), mitochondrial co-chaperone GrpE (CCM_00863), glycoside
   hydrolase, family 2 (CCM_09220), trypsin-like serine protease
   (CCM_03489), metalloprotease 1 (CCM_07917), acetate transporter
   (CCM_07990), SGT1 and CS protein (CCM_09524), formyltetrahydrofolate
   deformylase (CCM_09394), nucleoside triphosphate hydrolases like
   (CCM_01902), and uracil phosphoribosyltransferase (CCM_07057).

   The subcultured C. militaris strains degenerated beginning at the third
   generation, with incomplete fruiting body growth beginning at the
   fourth generation. Transcriptome analysis on the progress of C.
   militaris subculture degeneration showed that over 9,015 unigenes and
   731 new genes were identified, and 35,323 alternative splicing (AS)
   events were detected. Compared with the first generation, the third
   generation (degenerated strain) included 2,498 differentially expressed
   genes (DEGs) including 1,729 up-regulated and 769 down-regulated genes.
   Validation of RNA-seq by qRT-PCR showed that the expression patterns of
   51 DEGs were in accordance with the transcriptome data. In summary, our
   results indicated the mechanism of C. militaris strain degeneration is
   associated with gene involved in toxin biosynthesis, energy metabolism,
   DNA methylation, and chromosome remodeling.

Supporting information

   S1 Fig. Classification of clean reads.

   (TIF)
   [124]Click here for additional data file.^ (141.1KB, tif)
   S2 Fig. Distribution of gene coverage.

   (TIF)
   [125]Click here for additional data file.^ (176.7KB, tif)
   S3 Fig. Alternative splicing (AS) distribution of the six samples.

   (TIF)
   [126]Click here for additional data file.^ (187KB, tif)
   S4 Fig. KEGG pathway enrichment analysis.

   (TIF)
   [127]Click here for additional data file.^ (362.8KB, tif)
   S1 Table. Primers used for qRT-PCR.

   (TIF)
   [128]Click here for additional data file.^ (291.5KB, tif)
   S2 Table. Sequence numbers of the clean data.

   (TIF)
   [129]Click here for additional data file.^ (163.5KB, tif)
   S3 Table. Sequence numbers of the read data.

   (TIF)
   [130]Click here for additional data file.^ (118.1KB, tif)

Abbreviations

   C. militaris
          Cordyceps militaris

   AS
          alternative splicing

   DEGs
          differentially expressed genes

   GO
          Gene Ontology

   KEGG
          Kyoto Encyclopedia of Genes and Genomes

   qRT-PCR
          quantitative real-time PCR

   YCC
          the strain of C. militaris used in this study

   PDA
          potato dextrose agar

   CmGAPDH
          C. militaris housekeeping gene, glyceraldehyde-phosphate
          dehydrogenase

   CHM
          correlation heat map

   MAT
          mating-type

   CYP51
          cytochrome P450 51

   CYP61
          cytochrome P450 61

   ROS
          reactive oxygen species

Data Availability

   All relevant data are within the paper and its Supporting Information
   files.

Funding Statement

   This research was funded by the Special Fund for Agro-scientific
   Research in the Public Interest of China (No. 201403064).

References