1. Introduction

Armillaria is a facultative parasitic fungi with approximately 52 reported species [1,2], of which about 15 species have been identified in China [3]. Most Armillaria species are devastating forest pathogens that cause root rot disease in forests. Only a few of them with low pathogenicity such as Armillaria gallica can form a symbiotic relationship with Gastrodia elata, a mycoheterotrophy plant in the orchid family benefiting from A. gallica [4–9] and a special symbiotic relationship is established [10]. The dried tuber of G. elata is commonly used as a traditional Chinese medicine with high medicinal value in anticonvulsant, memory improving, and other neurological pharmacological effects [11–15].

A. gallica is commonly used as the companion strain for G. elata cultivation. The growth and development of G. elata vary significantly depending on the symbiotic relationship established with different varieties of A. gallica [16]. The cultivation areas of G. elata spans diverse climatic regions in China, such as the Hubei, Guizhou and Tibet, resulting in a broad genetic diversity of A. gallica strains across the different regions [17]. In addition, A. gallica from different habitats was introduced frequently, which can easily lead to homonymy (same name for genetically different strains) or synonymy (same strains with different names) of A. gallica. The efficient identification of A. gallica strains is therefore important.

Investigating the population genetics of A. gallica is complex due to its varied mating systems, including sexual reproduction, clonal (asexual) spread, and diploid–haploid mating [18,19]. The effective identification of A. tobescens, A. ostoyae, and A. mellea was established using intergenic spacer-restriction fragment length polymorphism (IGS-RFLP) [20]. In addition, the ribosomal DNA-internal transcribed spacer (rDNA-ITS) has been used to identify A. mellea, A. gallica, and A. cepistipes [21]. PCR-RFLP identified two types of A. gallica with low or high sugar contents [22]. However, the heredity and variation among populations of A. gallica have not been elucidated, and there is still a lack of suitable methods for the identification of A. gallica.

Simple sequence repeats (SSRs) are DNA segments with repeat motifs of one to six nucleotides. SSRs are widely used in assessments of the genetic diversity of germplasm resources, the construction of population genetic maps, and molecular marker-assisted breeding [23]. SSR polymorphism or variation may affect the evolution of the genome under control of evolutionary forces [24]. Furthermore, impaired DNA mismatch repair was one of the reasons for high mutation rate of SSR, which the polymorphism or variation of SSR may affect genome evolution [25]. SSRs can be categorized into genomic SSRs (gSSR) and expressed sequence tag SSRs (EST-SSR), each derived from genomic DNA sequence and expressed sequence tags, respectively [26]. gSSR generally exhibit higher polymorphism than EST-SSR. The PCR amplified fragments were not affected by introns in the flanking region. SSR variation in intronic SSRs could affect gene transcription, or mRNA splicing. SSRs located in protein-coding regions could lead to functional gene variation via frameshift mutation, contributing to rapid evolutionary changes [27]. Studying SSR patterns across different species might provide insight into genome evolution [28]. Large number of SSRs have been developed for the identification of plants or microorganisms [29,30]. However, the available number of SSR markers is relative limited in Armillaria spp [31,32], with even fewer reported for A. gallica. With the development of genome and transcriptome sequencing have enhanced the efficiency of SSR development, contributing greatly to the identification of Chinese medicinal materials.

Hence, it is particularly important to study the evolution and identification research of A. gallica. In this study, genome data for three Armillaria species were used to analyze the distribution of SSRs in the both genic and intergenic region. The patterns and variations of SSRs in A. gallica were examined. We also collected A. gallica strains from various G. elata production areas and assessed the genetic diversity. We hope our findings would shed light on genome evolution, genetic research and identification of A. gallica.

2. Materials and methods

2.1 Armillaria sources

Three previously published Armillaria genomes including A. gallica (VTST01000000), A. cepistipes (FTRY01000001-FTRY01000182), and A. ostoyae (FUEG01000001-FUEG01000106), were downloaded in this study [33,34]. The three genomes, A. gallica, A. cepistipes and A. ostoyae, had similar genetic background, and the expansion of protein-coding gene pool in Armillaria was similar. A. ostoyae was hard to symbiosis with G. elata due to its strong pathogenicity, A. gallica and A. cepistipes could symbiosis with G. elata, but A. gallica had the best affinity [7,33,35]. The strains of A. gallica that are symbiotic with G. elata were collected from Guizhou, Hubei, Shanxi, Yunnan, and Henan provinces as well as from other G. elata cultivation areas or research institutions. The detailed information of these strains are listed in S1 Table. Three Armillaria genomes were used to analyze the features of SSR motifs.

2.2 IGS identification

An Ezup column fungal genomic DNA extraction kit (Shanghai Sangong Bioengineering Co., Ltd.) was used to extract the total genomic DNA. The rDNA-IGS sequences were amplified and compared with the Armillaria species in GenBank for the interspecific identification of Armillaria [36].

2.3 Development and identification of SSRs

MISA software was used to analyze the SSRs in the reference genome of A. gallica. (http://misaweb.ipk-gatersleben.de/). Parameters were set based on previous study [24,37]. The minimum repeat unit is set to mononucleotide motif containing 10 or more repeats, dinucleotide motif containing 6 or more base repeats, trinucleotide, tetranucleotide, pentanucleotide, hexanucleotide and complex motif containing 5 or more base repeats. When the distance between two SSRs was less than 100 bp, the two SSRs formed a complex motif. The data of each SSR motif were extracted, and the number of mononucleotides, dinucleotides, trinucleotides, tetranucleotides, pentanucleotides, hexanucleotides, complex nucleotides, and multi-complex nucleotides, totaling eight types of SSR motifs, were counted and analyzed to characterize the SSR motifs on the genomes of the three Armillaria.

2.4 SSR distribution in different genomic regions

The genic region (intron, exon) and intergenic region were extracted from GFF files of each Armillaria genome. The genic region (intron, exon) and intergenic region were extracted from GFF files of each Armillaria genome by TBtools. According to the previous study, the quantity and length of SSRs in the different genomic regions were developed to identify [24,38]. And 108 pairs of primers were randomly selected including eight SSR motifs during genic region and intergenic region.

2.5 PCR amplification and genotyping

Primer 3.0 software was used to design flanking primers with the sequences following the detected putative SSRs. The SSR primer pairs were randomly selected during all scaffolds to assess the quantity of the developed SSRs. The SSR primers were synthesized at Sangong Bioengineering (Shanghai) Co., Ltd. The PCR was performed in 10 μL reaction volume containing10×Easy Taq Buffer (10 mM Tris-HCl pH 9.0, 1.5 mM MgCl₂, 50 mM KCl), 0.1 mM High Pure dNTPs, 0.1U Taq DNA polymerase, 0.1 mM each of forward and reverse primers, and 50 ng of genomic DNA was used as template in each PCR reaction. PCR program was as follows: initial denaturation at 95°C for 5 min, These cycles were subsequently followed by 32 cycles of denaturation at 95°C for 30 s with a constant annealing temperature of 58°C for 30 s, and extension at 72°C for 45 s, and a final extension of 72°C for 5 min. The amplified products were separated by 8% non-denatured polyacrylamide gel electrophoresis, stained with 0.1% silver nitrate solution, developed in the developer solution, and photographed for preservation.

2.6 SSR data analysis

The same band type amplified by each pair of SSR primers on the test material was considered an allelic variation, and according to the relative position of the separated bands, those with bands were marked as 1, while those without bands were marked as 0, forming a 0/1 matrix [39].

NTSYS 12.0 software was used to calculate the genetic correlation coefficient and genetic distance was used to cluster the samples based on the unweighted pair-group method with arithmetic means (UPGMA), and the neighbor joining tree was constructed [40]. Popgene32 software was used to calculate the average number of observed alleles (Na), the number of effective alleles (Ne), allele Frequency and the Shannon diversity index (Nei’s genetic identity, I) [41]. The polymorphism information content (PIC) was equal to 1 minus the sum of the squared frequencies of all alleles [42]. The principal coordinates analysis (PCoA) map was obtained based on GenAIEx 6.5 software [43].

The population structure analysis was performed by the Bayesian model-based clustering method in Structure v.2.3.4. The number of populations (K) was from 1 to 10, and each K value was iteratively calculated 10 times. The MCMC value and burn-in value were set to 150,000 and 10,000, respectively [30,44]. The optimal K value was determined by ΔK methodology using the web-based software StructureSelector [45].

3. Results

3.1 Armillaria genomic sequences

The number of SSRs in genomic was identified in A. gallica (4,141) which was much higher when compared with A. cepistipes (3,116), and A. ostoyae (2,336). The data indicated that A. gallica which had the largest genome size contains the highest number of SSRs. Total relative abundance and total relative density was calculated to estimate the SSRs by taking 1 Mb length of each set of sequences. A. cepistipes (41.88 and 647.42) had the maximum frequency of SSRs, while A. gallica had the similar frequency as A. ostoyae (Table 1). Different types of SSR motifs in the three genomes were further analyzed. Finally, expecting the complex and multiple complex type nucleotide, the frequency of repeat motifs decreased as the number of repeat motifs increased (Fig 1A–1F, S2 Table). In addition, in the mononucleotide to hexanucleotide motif, the first two base repeats accounted for the highest proportion, and were the most common in Armillaria genomes and account for more than 60% of the total repeats (Fig 1, S2 Table).

[Figure omitted. See PDF.]

(A) Mononucleotide, (B) Dinucleotide, (C) Trinucleotide, (D) Tetranucleotide, (E) Pentanucleotide, (F) Hexanucleotide, (G) Complex nucleotide, (H) Multiple complex nucleotide.

[Figure omitted. See PDF.]

We further analyzed the percentage of different classes of repeats in their respective genomes. The mono-, di-, and trinucleotide motifs exhibited at least 10 times as abundant as other five motifs (Table 2). We further analyzed the percentage of different classes of repeats in their respective genomes. In A. cepistipes, A. gallica, and A.ostoyae mononucleotide repeats constituted the maximum percentage of SSRs (43.58, 43.25 and 39.51%) followed by trinucleotide repeats (29.85, 31.54 and 32.62%) while hexanucleotide repeats were the least (0.51, 0.27 and 0.47%; Table 2).The average of quantity variation was 0.28% between Armillaria genomes, with genome variation being larger in penta- (0.69%) and complex nucleotides (0.42%) motifs.

[Figure omitted. See PDF.]

3.2 Comparative analysis of the number and density of different SSR motifs in different regions of Armillaria genome

In order to analyze the number of SSRs distributed in different regions in the genomes of the three Armillaria, the distribution of SSRs in the intergenic region and the genetic region (exon and intron region) of the Armillaria were compared. The results showed that the quantity and density of SSRs in intergenic region was more than that in genic region. Among the three genomes, the number of SSRs was the highest in the intergenic region, followed by exons and introns. However, SSR density was the lowest in exon region and highest in the intron region of A. gallica compared with other two genomes (Table 3). The results showed that genic region had large genome-specific variation in A. gallica genome.

[Figure omitted. See PDF.]

To analyze the number and density of different SSR motifs in the three genomes, SSR motif in different genic region was compared and analyzed. For all eight SSR motifs, the difference of SSR quantity and density were mainly in mono-, di-, and trinucleotide motifs among the three regions. For mono- and dinucleotide motifs, the largest and the least SSR quantity and density were distributed in intergenic region and exon region, respectively. However, the trinucleotide motifs mainly distributed in the exon region (Fig 2A and 2B). The results revealed the variation of SSRs with trinucleotide motif was the main reason for large variation in genic region of A. gallica.

[Figure omitted. See PDF.]

The Quantity (A) and Density (B) of eight SSR motifs in three genome regions (**P<0.01).

3.3 DNA polymorphism

Fourteen strains of Armillaria were collected from various G. elata cultivation areas in China. And phylogenetic analysis showed that all the strains had the highest similarity and the closest genetic relationship with A. gallica. This result indicated that the 14 strains belong to A. gallica IGS analysis was used for interspecific identification (Fig 3).

[Figure omitted. See PDF.]

The genome of A. gallica contained different types of SSRs, from mononucleotide to hexanucleotide repeat types. Approximate 108 SSR markers s were randomly selected in the A. gallica genome for genotyping. According to the location in the genome, it was found that 63 SSR markers were in the intergenic region, followed by 45 SSR markers in genic region. They were accounted for 58.3%, 41.7% in total 108 markers, respectively (S3 Table). The results showed that 17 SSR markers were polymorphic (S4 Table), with 12 markers distributed in genic region, and 5 markers in intergenic region. The proportion of polymorphism markers amplified by genic region was 26.7%, which was higher than that of the intergenic region 18.8%. A total of 50 polymorphic loci were observed, of which 42 belong to 9 SSR markers with alleles ranged from two to five, with 42 polymorphic loci and a polymorphism ratio of 84%. The results showed that the proportion of polymorphic SSR markers in genic region was higher than that in intergenic region.

3.4 Genetic diversity analysis of A. gallica

These 17 SSR markers were used to investigate genetic diversity and population structure in 14 strains of A. gallica. The genetic correlation coefficient was between 0.4400 and 1.000 (S5 Table), and the genetic distance (D) was between 0 and 0.8614.The YN4 and BJ1 exhibited the farthest genetic distance of 0.8614. In addition, the average number of observed alleles (Na) was 3, and the average number of effective alleles (Ne) was 1.9149. The average Nei’s diversity index (H) and the average Shannon index (I) were 0.4487and0.7587, respectively. Furthermore, the observed heterozygosity (Obs_Het) ranged from 0 to 0.7143 with an average of 0.3866, and the expected heterozygosity (Exp_Het) ranged from 0.2672to 0.7037 with an average of 0.4653. The expected heterozygosity is lower than the observed heterozygosity, indicating excessive heterozygosity. Polymorphism information content (PIC) can reflect the degree of genetic variation in a population. In the study, among which the highest marker of PIC is 87–30, the maximum PIC mark is 0.6786 and the minimum PIC mark is 0.2577, and the average PIC is 0.4487. Nei’s gene diversity index ranged from 0.2577 to 0.6787 with an average of 0.4487 (Table 4).

[Figure omitted. See PDF.]

The UPGMA analysis revealed that the 14 strains of A. gallica grouped into two clusters were identified. The maximum cluster I consisted groups I, with 7 strains genotypes, respectively. The cluster II contained 7 strains were collected from Hubei and Shanxi Province (Fig 4A), which were in low-altitude G. elata producing areas mainly planted with G. elata Bl. f. elata. While Cluster I included all the strains from Guizhou and Yunnan in high-altitude G. elata producing areas mainly planted with G. elata Bl. f. glauca. The results suggested that the genetic diversity of A. gallica was subject to environmental selection including altitude and the type of G. elata.

[Figure omitted. See PDF.]

(A) UPGMA dendrogram demonstrating genetic relationships among the strains of A. gallica. (B) The Principal Coordinates analysis of the strains of A. gallica. (C) Two-dimensional scatter point map of A. gallica based on population genetic distance. The line graph shows the K value and △K. (D) Genetic structure of the strains of A. gallica as inferred by STRUCTURE based on 17 SSRs.

The PCoA showed that the A. gallica strains could be divided into two subgroups (Fig 4B). PC1 was 49.75% and PC2 was 13.06%. The two subgroups were the same as those in the two clusters identified in the UPGMA analysis. The K and △K value revealed that this population could be divided into two subgroups when the K = 2 (Fig 4C). The genetic structure indicated that most of the strains originated from a single primitive ancestor, due to a few mixed individuals in each subgroup. Two subgroups could be divided with K = 2, which was highly consistent with the UPGMA analysis (Fig 4D).

4. Discussion

The genus Armillaria is known for its high species diversity and significant variability among its members [46]. SSRs may play a role in regulating the rapid adaptation of organisms to new environments, and the variation produced by SSRs may also be the source of rapid protein function evolution [47]. Research indicates that there are notable differences in the relative abundance and density of SSRs among different Armillaria species. Higher relative abundance and density of SSRs were observed in the genomic of the pathogenic A. cepistipes when compared to A. gallica, which grow symbiotically with G. elata and have low pathogenicity (Table 1). This observation is consistent with findings from studies on Aspergillus species, which SSR variability has also been observed in the pathogenic Aspergillus [48]. In addition, SSR quantity and density of exon region and exon region in A. gallica were opposite to those of the other two Armillaria genomes (Table 3). The results suggest that pathogenic fungus may have more SSR variability to adapt to the environment and SSRs could be a valuable marker for understanding the virulence of different Armillaria strains.

Previous studies have shown that repeat sequences are common in genic and intergenic region. SSR quantity in intergenic region was much higher than genic region. SSR density in genic region was much higher than intergenic region, with abundant trinucleotide motifs in maize [24]. In Puccinia striiformis, the SSR markers were mostly abundant in intergenic region [49]. In our research, we found that the SSR quantity was higher in the intergenic region than in the genic region. This result was the same to the maize genomes. However, the SSR density in intergenic region was higher than genic region in three Armillaria genomes and Puccinia striiformis, which was the opposite of maize. There results suggested that fungus had some common features in SSRs formation and structure, which may be a difference between fungal and plant genomes.

Genetic variation is an important evolutionary factor when there is strong selection pressure [24]. Higher degree of SSR variation within exon regioncould more likely cause frame-shift or mutation in protein sequence [27]. Although the SSR density was low in the A. gallica genome, the SSR density in the exon region was higher than other two genomes, and it was lower in exon region, which was rich in trinucleotide motifs (Fig 2). The variation of trinucleotide motifs in exon could cause the variation of gene function. And it may be an important factor for the evolution in A. gallica which is the most common symbiotic fungus of G. elata in China for planting or breeding research [17,50]. Therefore, genetic variation caused by genic region in A. gallica may be one of the main reasons for its evolution to symbiosis with G. elata. And the variation in the exon region may be used as the identification for A. gallica. Our analysis indicates that the proportion of polymorphic SSRs in the genic region was high than intergenic region. This may be related to the high density of SSR variants in genic region of A. gallica genome. It provides a basis for efficient selection of genomic SSR.

A. gallica plays an important role in the production of G. elata, with which it establishes a symbiotic relationship [7]. Previous studies have found that the different biological characteristics of A. gallica resulted in great differences in the growth of G. elata [51,52]. The breeding of high-quality A. gallica has played an important role in the production of G. elata. Collecting Armillaria species resources, analyzing the population genetic structure, and establishing a method for the identification is therefore necessary for the identification and breeding of high-quality A. gallica.

SSR is an important DNA marker in plant breeding, which could be widely used in molecular breeding and variety identification [53,54]. Previous study confirmed that multi-allelic SSRs have a higher discriminatory power than bi-allelic SNP markers to detect structure in populations at a small spatial scale with a systematic and continuous sampling design [32,55]. Sixteen markers in genome-wide SSRs were used to investigate the genetic diversity and population structure of strains in F. virguliforme, which could be grouped into three clusters [56]. In addition, three SSRs were developed to characterize the population structure of Leptosphaeria maculans and L. biglobosa, caused phoma stem canker (blackleg) in oilseed rape [57]. SSRs can effectively identify species. In this study, 17 SSR markers with high polymorphism were obtained, indicating that markers could be used to identify germplasm resources of A. gallica.

5.Conclusion

This study firstly integrated comparative genomic and genomic SSR analysis to investigate the evolution, variation and population genetic pattern of A. gallica. SSRquantity and density was higher in intergenic region than genic region. The variation of SSRs with trinucleotide motif was important for large variation in genic region of A. gallica, which provides the basis for the selection of polymorphic SSR markers. In addition, 17 high polymorphism SSRs of A. gallica genome, were successfully used for population genetic analysis of A. gallica germplasm. Overall, the variation of SSRs provide the basis for SSR markers selection in genome. SSRs will be of great value for the related genetic studies in A. gallica species. These results could be used to genetic research and identification of A. gallica, in turn promoting the production and cultivation of G. elata.

Supporting information

S1 Table. The information of Armillaria gallica in the experiment.

https://doi.org/10.1371/journal.pone.0312114.s001

(XLSX)

S2 Table. Percentage of the eight types of SSR motifs in Armillaria genomes.

https://doi.org/10.1371/journal.pone.0312114.s002

(XLSX)

S3 Table. There were 108 SSRs primers.

https://doi.org/10.1371/journal.pone.0312114.s003

(XLSX)

S4 Table. There were 17 SSRs primers.

https://doi.org/10.1371/journal.pone.0312114.s004

(XLSX)

S5 Table. Genetic distance and genetic correlation coefficient matrix (Below the diagonal is the genetic distance. Above the diagonal are genetic correlation coefficients).

https://doi.org/10.1371/journal.pone.0312114.s005

(XLSX)

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Citation: Li S, Xu J, Hu Y, Ou X, Yuan Q, Li P, et al. (2024) Variation in SSRs at different genomic regions and implications for the evolution and identification of Armillaria gallica. PLoS ONE 19(10): e0312114. https://doi.org/10.1371/journal.pone.0312114

About the Authors:

Shengnan Li

Contributed equally to this work with: Shengnan Li, Jiao Xu

Roles: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Software, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China

Jiao Xu

Contributed equally to this work with: Shengnan Li, Jiao Xu

Roles: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Resources, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China

ORICD: https://orcid.org/0000-0002-1690-6160

Yipu Hu

Roles: Methodology, Software

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China

Xiaohong Ou

Roles: Resources, Writing – review & editing

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China

Qingsong Yuan

Roles: Writing – review & editing

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China

Pengfei Li

Roles: Methodology

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China

Weike Jiang

Roles: Resources, Writing – review & editing

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China

Lanping Guo

Roles: Resources, Supervision, Writing – review & editing

E-mail: [email protected] (LG); [email protected] (TZ)

Affiliation: National Resource Center for Chinese Materia Medica, State Key Laboratory Breeding Base of Dao-di Herbs, China Academy of Chinese Medical Sciences, Beijing, China

Tao Zhou

Roles: Conceptualization, Investigation, Methodology, Resources, Supervision, Validation, Visualization, Writing – review & editing

E-mail: [email protected] (LG); [email protected] (TZ)

Affiliation: Guizhou University of Traditional Chinese Medicine, Guiyang, China