Diversity and communities of culturable endophytic fungi from different tree peonies (geoherbs and non-geoherbs), and their biosynthetic potential analysis

Yang, Guodong; Li, Peng; Meng, Lifen; Xv, Keyi; Dong, Faming; Qiu, Yan; He, Lei; Lin, Lin

doi:10.1016/j.bjm.2018.06.006

Abstract

To know more about the potential roles of endophytic fungi in the formation mechanism of Daodi medicinal material, diversity and communities of culturable endophytic fungi in three types of tree peonies were investigated. Endophytic fungi of three types of tree peonies were isolated and identified. The diversity was analyzed. Bayesian trees constructed by MrBayes 3.2.6 after phylogenetic analysis of the ITS sequences. The endophytic fungi potential for synthesis of natural products was assessed by means of detecting NRPS and PKS gene sequences. In total, 364 endophytic fungi isolates representing 26 genera were recovered from Paeonia ostii ‘Feng Dan’, Paeonia ostii ‘Luoyang Feng Dan’, and Paeonia suffruticosa ‘Luoyang Hong’. More culturable endophytic fungi appeared in P. suffruticosa ‘Luoyang Hong’ (206) compared with P. ostii ‘Feng Dan’ (60) and P. ostii ‘Luoyang Feng Dan’ (98). The fungal community of P. ostii ‘Feng Dan’ had the highest richness and diversity. PKSs and NRPS detection rates of endophytic fungi from P. ostii ‘Feng Dan’ are both the highest among the three types of tree peonies. Results indicate that endophytic fungus is an important factor of Daodi Cortex Moutan forming, and endophytic fungi in peony are related to genuineness of Cortex Moutan.

Keywords
Endophytic fungi; PKS; NRPS; Cortex Moutan; Daodi medicinal material

Introduction

Some traditional Chinese medicinal materials that are produced in specific geographic regions with designated natural conditions and ecological environment, and widely recognized as having better beneficial clinical therapeutic effects are called Daodi medicinal materials or geoherbs.¹1 Zhao ZZ, Guo P, Brand E. The formation of daodi medicinal materials. J Ethnopharmacol. 2012;140:476-481. As the essence of Chinese medicinal materials, Daodi medicinal materials have enjoyed a good reputation and have been playing an important role in treating disease and preserving health for thousands of years. From a biological point of view, heterogeneous individuals of the same species can be classified as either geoherbs or non-geoherbs, with their unique chemical constituents resulting from the interaction between minor polygenes and differential ecology.²2 Guo L, Wang S, Zhang J, et al. Effects of ecological factors on secondary metabolites and inorganic elements of Scutellaria baicalensis and analysis of geoherblism. Science China: Life Sci. 2013;56:1047-1056. For instance, Paeonia suffruticosa Andrews, commonly called the tree peony, belongs to the Ranunculaceae family. The root bark of P. suffruticosa is called Cortex Moutan, which is a famous Chinese medicinal material and widely used in traditional Chinese medicine. Cortex Moutan produced from Paeonia ostii ‘Feng Dan’ in Tongling city, located in Anhui Province is considered a Daodi medicinal material (also called geoherbs). However, Cortex Moutan, which produced from P. ostii ‘Feng Dan’ that were transplanted in other regions of China or from other peony varieties, are called non-Daodi medicinal material (also called non-geoherbs). In recent years, researchers have studied the formation mechanism of Daodi Cortex Moutan from the perspectives of processing technique, environmental conditions, geochemistry, rhizosphere soil microorganism, trace elements, metabolism in animals, and obtained a series of important achievements. But the dominant factors of Daodi Cortex Moutan forming are not yet clear, the formation mechanism of Cortex Moutan needs further research.

Endophytic fungi are a group of diverse, fungal microorganisms that spend the whole or part of their life cycle in living plant tissues without causing any noticeable symptom of disease.³3 Kusari S, Pandey SP, Spiteller M. Untapped mutualistic paradigms linking host plant and endophytic fungal production of similar bioactive secondary metabolites. Phytochemistry. 2013;91:81-87.^,⁴4 Tan R, Zou W. Endophytes: a rich source of functional metabolites. Nat Prod Rep. 2001;18:448-459. It is noteworthy that endophytic fungi are ubiquitous in plant species that exist on the earth, and the endophytic colonization differs from tissues to tissues.⁵5 Strobel G, Daisy B. Bioprospecting for microbial endophytes and their natural products. Microbiol Mol Biol Rev. 2003;67:491-502.^,⁶6 Sun X, Guo L-D. Endophytic fungal diversity: review of traditional and molecular techniques. Mycology. 2012;3:65-76. They play important roles in the process of host plant growth and systematic evolution. Studies have shown that endophytic fungi have the capability to produce many kinds of identical or similar biologically active constituents as their host plants. These active constituents include antineoplastic paclitaxel,⁷7 Stierle A, Strobel G, Stierle D. Taxol and taxane production by Taxomyces andreanae, an endophytic fungus of Pacific yew. Science. 1993;260:214. camptothecin,⁸8 Satish Chander P, Vijeshwar V, Touseef A, Ghulam Nabi Q, Michael S. An endophytic fungus from Nothapodytes foetida that produces camptothecin. J Nat Prod. 2005;68:1717-1719. deoxypodophyllotoxin,⁹9 Kusari S, Lamshöft M, Spiteller M. Aspergillus fumigatus Fresenius, an endophytic fungus from Juniperus communis L. Horstmann as a novel source of the anticancer prodrug deoxypodophyllotoxin. J Appl Microbiol. 2009;107:1019-1030. the hypericin, etc.¹⁰10 Kusari S, Lamshoft M, Zühlke S, Spiteller M. An endophytic fungus from Hypericum perforatum that produces hypericin. J Nat Prod. 2008;71:159-162. Polyketide synthetases (PKS) and non-ribosomal peptide synthetases (NRPS) are multifunctional enzymes catalyzing the biosynthesis of structurally diverse bioactive natural products. Polyketides and non-ribosomal peptides have been immensely concerned over the past decades, and numbers of various novel polyketide and non-ribosomal peptide compounds have been found from endophytic fungi. The presence of PKS and NRPS in fungi suggest their potential in producing related compounds and guides in producing related natural products.¹¹11 Wang Y, Gao BL, Li XX, Zhang ZB, Yan RM, Yang HL, Zhu D. Phylogenetic diversity of culturable endophytic fungi in Dongxiang wild rice (Oryza rufipogon Griff), detection of polyketide synthase gene and their antagonistic activity analysis. Fungal Biol. 2015;119:1032-1045.^–¹³13 Cho WCS, Miller KI, Qing C, Sze DMY, Neilan BA. Investigation of the biosynthetic potential of endophytes in traditional Chinese anticancer herbs. PLoS ONE. 2012;7:e35953. Endophytic fungi are widely distributed in healthy plant tissues. In addition, endophytic fungi can produce secondary metabolites that are also biosynthesized by their host plants. Is there an interrelationship between endophytic fungi and the formation of Daodi medicinal material? Is there a difference in diversity and communities of endophytic fungi between Daodi medicinal material and non-Daodi medicinal material?

In this study, with the aim to know more about the tree peony endophytic fungal diversity and find evidence for the potential roles of endophytic fungi in the formation mechanism of Daodi medicinal material, our objectives were therefore to (1) isolate and identify genetically and morphologically filamentous endophytic fungi of tree peonies from two different regions, (2) investigate the variation in the diversity and communities of the endophytic fungi population of tree peonies (geoherbs and non-geoherbs), (3) the potential of endophytic fungi in producing bioactive natural products was estimated based on the detection of PKS and non-ribosomal peptide synthetases (NRPS) genes.

Materials and methods

Plant sample collection

P. ostii ‘Feng Dan’ belongs to the section Moutan of the genus Paeonia and the family Paeoniaceae.¹⁴14 Peng LP, Cai CF, Zhong Y, et al. Genetic analyses reveal independent domestication origins of the emerging oil crop Paeonia ostii, a tree peony with a long-term cultivation history. Sci Rep. 2017;7:5340. Five-year-old P. ostii ‘Fen Dan’ plants, which were considered as the raw material of Daodi medicinal material, were collected from Phoenix Mountain Peony Garden, Tongling city, Anhui Province, China.

P. ostii ‘Feng Dan’ seedlings had grown in Anhui province for two years, and then the two-year-old seedlings have been transplanted in Luoyang city for three years. These five-year-old peony samples were collected from peony cultivation base of National Flower Park of China, Luoyang, Henan, China. In order to distinguish them from the above peony variety, we named them as P. ostii ‘Luoyang Feng Dan’. In essence, P. ostii ‘Luoyang Feng Dan’ and P. ostii ‘Feng Dan’ are the same peony varieties, but their growing regions are different. P. ostii in Tongling city and Luoyang city were named after P. ostii ‘Feng Dan’ and P. ostii ‘Luoyang Feng Dan’ respectively in the following narrative.

P. suffruticosa ‘Luoyang Hong’, a typical purplish red-flowered cultivar of Chinese traditional P. suffruticosa cultivars, is particularly appreciated by Chinese. In our study, P. suffruticosa ‘Luoyang Hong’ was also collected in peony cultivation base of National Flower Park of China, Luoyang city, Henan Province, China. The three types of tree peonies were collected in October 2014. A total of 30 individuals of each kind of tree peonies were collected. All plant materials were immediately brought to the laboratory, stored at 4 °C in refrigerator and preprocessed within 24 h. The tree peonies endophytic fungi were isolated according to the surface sterilization method described by Li Peng et al.¹⁵15 Li P, Yang GD, Qiu Y, Lin L, Dong F. Paeonol produced by Chaetomium sp., an endophytic fungus isolated from Paeonia suffruticosa. Phytochem Lett. 2015;13:334-342.

Isolation and identification of endophytic fungi

The endophytic fungi were incubated on potato dextrose agar (PDA: 200 g scrubbed and diced potatoes, 15 g dextrose, 20 g agar, and 1 L distilled water) plates at 25 °C in the dark until the colonies reached the rim of the dishes (9 cm in diameter). All fungi isolates were examined periodically, and were classified into morphotypes based on their growth rates and morphological and microscopic characteristics (including shape of the mycelium, texture of the mycelium surface, production of spores (conidia, blastospores, sporangiospores or ascospores), color of the fungi, production of pigments and their diffusion into the medium). A total of 156 morphotypes were then identified based on the ITS sequence data. Mycelia of the fungal endophytes were ground completely with liquid nitrogen in a sterile mortar, and Genomic DNA extraction from all endophytic fungi was performed using a DN41 rapid DNA extraction kit (Aidlab Biotechnologies Co. Ltd., Beijing, PR China) following the manufacturer's recommendations for fungi. The internal transcribed spacer (ITS) region was amplified with universal primers ITS1(5′TCCGTTGGTGAAC CTGCGG3′) and ITS4(5′TCCTCCGGTTATTGATATGC3′). PCR mixture contained 12.5 µL 2× Taq PCR Master Mix (Taq DNA Polymerase, Buffer, MgCl₂ and deoxynucleotide triphosphates (dNTPs) were contained), 1 µL DNA sample, 1 µL of each primer and 9.5 µL double distilled water. The PCR reaction conditions were as follows: initial pre-heating at 94 °C for 3 min, 30 cycles of 94 °C for 30 s, 58 °C for 30 s, 72 °C for 30 s, and a final extension at 72 °C for 10 min. After amplification, the PCR products were analyzed by electrophoresis on a 1.2% agarose gel stained with ethidium bromide (0.5 ng/mL agarose) by stirring gently for 15 min; the products were then visualized under UV light. The PCR products were separated on 1% (w/v) agarose gel and purified using a DNA Gel Exaction Kit (AXYGEN, Suzhou, PR China). The resulting DNA was sequenced directly using the same primers (Beijing Honor Tech Co. Ltd., Beijing, PR China).

The ITS sequence data of the endophytic fungi were submitted to the GenBank database. The ITS sequence was compared with that of the most closely-related fungal species (identity values higher than 95%) in the NCBI database (http://www.ncbi.nlm.nih.gov/) using the BLAST program, in consultation with observed colony and spore morphology to confirm the taxonomic status of the investigated fungal isolate. The sequence of Psilocybe cubensis was used as an outgroup. Bayesian trees constructed by PAUP 4.0b10 and MrBayes 3.2.6 after phylogenetic analysis of the ITS sequence data.

Screening of PKS and NRPS genes in tree peonies endophytic fungi

The highly conserved sequences of β-ketoacyl synthase (KS) domains are shared among all PKSs; thus, the KS domains are useful in screening for PKSs in fungi. Therefore, LC series primers (Table 1) were used to detect PKS genes in the fungal isolates.¹⁶16 Zhou K, Zhang X, Zhang F, Li Z. Phylogenetically diverse cultivable fungal community and polyketide synthase (PKS), non-ribosomal peptide synthase (NRPS) genes associated with the South China Sea Sponges. Microb Ecol. 2011;62:644-654. Similarly, the most conserved A domain can be used for PCR primer design to survey NRPSs gene diversity. Primers AUG003 and AUG007 (Table 1) were used for amplification of NRPS genes.¹⁷17 Rédou V, Navarri M, Meslet-Cladière L, Barbier G, Burgaud G, Brakhage AA. Species richness and adaptation of marine fungi from deep-subseafloor sediments. Appl Environ Microbiol. 2015;81:3571-3583. The PCR reaction conditions were as follows: initial pre-heating at 94 °C for 5 min, 35 cycles of 95 °C for 1 min, 55 °C for 1.5 min, 72 °C for 3 min, and a final extension at 72 °C for 10 min. After amplification, the PCR products were inspected by electrophoresis on a 1.2% agarose gel stained with ethidium bromide (0.5 ng/mL agarose) by stirring gently for 15 min; the products were then visualized under UV light. Prior to cloning, PCR products were purified with DNA Gel Extraction Kit (San Prep SK8131, PR China). The sequences encoding the PKS or NRPS were cloned into a pUCm-T cloning vector (Sangon SK2211, PR China) and transformed into competent Escherichia coli cell (B529303 Ultra-Competent Cell Preps Kit, PR China) according to the manufacturer's protocol. The purified plasmid (using SanPrep Column Plasmid Mini-Preps Kit B518191, PR China) was sequenced.

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Table 1
Primer information of PKS and NRPS.

Date analysis

The colonization rate (CR) was calculated according to the method of Hata and Futai,¹⁸18 Hata K, Futai K. Endophytic fungi associated with healthy pine needles and needles infested by the pine needle gall midge. Thecodiplosis japonensis. Can J Bot. 1995;73:384-390. CR = NCOL/Nt where NCOL is the number of segments colonized by each endophytic fungi; N _t is the total number of segments. The isolation rate (IR) was calculated as follow: IR = the number of EF isolated/the total number of fragments incubated.¹⁹19 Saucedo-García A, Anaya AL, Espinosa-García FJ, González MC. Diversity and communities of foliar endophytic fungi from different agroecosystems of Coffea arabica L. in two regions of Veracruz, Mexico. PLoS ONE. 2014;9:e98454. The Shannon diversity index (H′) and the Simpson's diversity index (D) were used to analyze the diversity of endophytic fungi and calculated as follows: Shannon diversity index, Simpson's diversity index, where k is the total number of fungal taxon, and P_i is the relative abundance of taxon i. Evenness values were calculated following Pielou's Evenness Index. Pielou's Evenness Index J = H/log (S), where H is the Shannon–Weaver diversity index and S is the number of species (species richness).²⁰20 Wang J, Meier S, Soininen J, et al. Regional and global elevational patterns of microbial species richness and evenness. Ecography. 2016;39:1-10. Statistical analyses were performed using IBM SPSS Statistics Software (Version 20). The fungal phylotypes richness, the detection rates of PKSs and NRPS were subjected to ANOVA to test for significant differences between different types of tree peonies.

Results

Abundance and diversity of endophytic fungi

A total of 364 endophytic fungal isolates were isolated from asymptomatic leaf, stem, and root segments of tree peonies plants following a standard isolation protocol. Results showed that P. suffruticosa ‘Luoyang Hong’ exhibited the highest number of endophytic fungi (206 isolates), followed by P. ostii ‘Luoyang Feng Dan’ (98 isolates), P. ostii ‘Feng Dan’ (60 isolates) (p < 0.05) (Table 2). The colonization rate of P. suffruticosa ‘Luoyang Hong’ was the highest, flowed by P. ostii ‘Luoyang Feng Dan’, while P. ostii ‘Feng Dan’ is the lowest. A similar situation exists with the IR. The isolation rate of P. suffruticosa ‘Luoyang Hong’ was significant higher than that of P. ostii ‘Luoyang Feng Dan’ and P. ostii ‘Feng Dan’. The 364 isolated endophytic fungi were assigned to 156 morphospecies. All the morphotypes were identified based on the morphological characteristics and ITS sequence data (Table 3). Multiple alignment of the ITS sequence data was performed by Clustal W of MEGA ver. 6. MrModeltest 2.1 was used to choose the substitution model that best fit the data using the AIC criterion. The best model computed for Bayesian analysis was GTR + G. Bayesian analyses used one cold and three heated Monte Carlo Markov chains in two simultaneous runs. Bayesian analyses was computed with MrBayes 3.2.6 and carried out using 1.5 × 10⁷ generations and a sample frequency of 100. The burn-in ratio was set at 0.25 (Fig. 1).

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Table 2
Colonization and isolation rate, species richness of tree peonies endophytic fungi.

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Table 3
Taxonomic affinities of tree peonies endophytic fungi.

Fig. 1
Phylogenetic tree based on the ITS1, 5.8S and ITS2 region of rDNA obtained from endophytic fungi of three types of tree peonies. The tree was constructed via the Bayesian inference method. An individual of each taxon isolated was used in the construction of the clustering together with a reference sequence retrieved from GenBank (●). The fungus Psilocybe cubensis was used as outgroup for the construction of the tree.

To characterize the biodiversity of our samples, we calculated Species richness (S), Shannon diversity index (H′), Simpson's diversity index (D), and Pielou evenness index (J). The values obtained by these tests (17, 2.5757, 0.9006, and 0.9091, based on P. ostii ‘Feng Dan’; 9, 1.7730, 0.7876, and 0.8069, based on P. ostii ‘Luoyang Feng Dan’; 10, 1.3458, 0.6125, and 0.5845, based on P. suffruticosa ‘Luoyang Hong’, respectively) were shown in Table 2.

Community composition of endophytic fungi

In each of the three types of tree peonies, the composition of the endophytic fungi communities exhibited a high degree of variability. Among those detected, for P. ostii ‘Feng Dan’, a total of 17 different genera of endophytic fungi were isolated, Phomopsis was the dominant genus with relative frequency of 19.2%, followed by Nigrospora, Alternaria and Pestalotiopsis with relative frequencies of 15.4%, 7.7% and 7.7%, respectively; for P. ostii ‘Luoyang Feng Dan’, a total of 9 different genera of endophytic fungi were isolated, Fusarium was the dominant genus with relative frequency of 27.4%, followed by Phoma, Alternaria and Paraconiothyrium with relative frequencies of 23.5%, 19.6%, and 9.8%, respectively; for P. suffruticosa ‘Luoyang Hong’, a total of 10 different genera of endophytic fungi were isolated, Alternaria was the dominant genus with relative frequency of 55.7%, followed by Fusarium and Pestalotiopsis with relative frequencies of 25.7% and 5.8%, respectively (Fig. 2). A total of 26 different fungal genera were recovered from three types of tree peonies, of which, ten (38.5%) were exclusively isolated from P. ostii ‘Feng Dan’, four (15.4%) were only recovered from P. ostii ‘Luoyang Feng Dan’, four (15.4%) were merely obtained from P. suffruticosa ‘Luoyang Hong’, and eight (30.8%) were jointly found in the three types of tree peonies (Fig. 2). On the whole, the stems of tree peonies exhibited the highest number of endophytic fungi (221 isolates), followed by the leaves (85 isolates) and roots (58 isolates).

Fig. 2
Pie charts show the relative abundance of the dominant culturable endophytic fungi phyla in three types of tree peonies. Venn's diagrams showing unique and shared genus in culturable endophytic fungi of P. ostii ‘Feng Dan’, P. ostii ‘Luoyang Feng Dan’ and P. suffruticosa ‘Luoyang Hong’ samples.

Identification of genes encoding bioactivity in tree peonies endophytic fungi

Degenerate PCRs were used to detect putative NRPS and PKS gene sequences originating from fungal endophytes in the DNA extracts. Amplification of fungal KS domains and A domains was confirmed via sequencing and BLASTX (translated) analysis. Based on the BLASTX analysis, a total of 69 endophytic fungi isolated from the three types of tree peonies were detected to contain fungal KS domain sequences (∼700 bp). The amplified sequences possessed between 90% and 100% amino acid identity to known fungal PKSs. The detection rates of P. ostii ‘Feng Dan’ endophytic fungi, P. ostii ‘Luoyang Feng Dan’ endophytic fungi, P. suffruticosa ‘Luoyang Hong’ are 48.15%(13/27), 41.07%(23/56), and 44.59%(33/74) (p < 0.05), respectively (Table 4). A total of 8 endophytic fungi isolated from the three types of tree peonies were detected to contain fungal A domains sequences (∼1500 bp). The amplified sequences possessed between 64% and 75% amino acid identity to known fungal NRPS. The detection rates of P. ostii ‘Feng Dan’ endophytic fungi, P. ostii ‘Luoyang Feng Dan’ endophytic fungi, P. suffruticosa ‘Luoyang Hong’ endophytic fungi are 11.11% (3/27), 7.14% (4/56), and 1.35% (1/74) (p < 0.05), respectively (Table 5).

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Table 4
PKS genes identified with degenerate PCR primers.

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Table 5
NRPS genes identified with degenerate PCR primers.

Discussion

In this study, endophytic fungal isolated from three types of tree peonies were identified, and their communities’ composition were analyzed. The research results indicate that the biodiversity of fungal endophytes in the three types of tree peonies exhibited a high degree of difference. P. ostii ‘Feng Dan’ yielded low abundance strains and showed lower CR and IR, yet the Species richness (S), Shannon diversity index (H′), Simpson's diversity index (D) of P. ostii ‘Feng Dan’ were all higher than that of P. ostii ‘Luoyang Feng Dan’ and P. suffruticosa ‘Luoyang Hong’ (Table 2). There are altogether 26 different fungal genera recovered from three types of tree peonies, of which, 10 different fungal genera were exclusively isolated from P. ostii ‘Feng Dan’, 4 different fungal genera were only recovered from P. ostii ‘Luoyang Feng Dan’, 4 different fungal genera were merely obtained from P. suffruticosa ‘Luoyang Hong’, and 8 different fungal genera were jointly found in the three types of tree peonies. Compared with P. ostii ‘Luoyang Feng Dan’ and P. suffruticosa ‘Luoyang Hong’, P. ostii ‘Feng Dan’ which is the raw material of Daodi Cortex Moutan has more types of endophytic fungi. The diversity of P. ostii ‘Feng Dan’ endophytic fungi is the highest, flowed by that of P. ostii ‘Luoyang Feng Dan’, the diversity of endophytic fungi from the P. suffruticosa ‘Luoyang Hong’ is the lowest. In this study, P. ostii ‘Feng Dan’ and P. ostii ‘Luoyang Feng Dan’ are essentially the same variety of tree peonies, they just grow in the different geographical environment. But the diversity of P. ostii ‘Feng Dan’ endophytic fungi is significantly higher than that of P. ostii ‘Luoyang Feng Dan’ endophytic fungi. P. ostii ‘Luoyang Feng Dan’ and P. suffruticosa ‘Luoyang Hong’ are the different varieties of tree peonies, they grow in the same geographical environment. There is not much difference between the endophytic fungi diversity of P. ostii ‘Luoyang Feng Dan’ and P. suffruticosa ‘Luoyang Hong’. The results of the above studies suggest that, compared with the variety of tree peonies, geographical environment plays a more important role in affecting the diversity of tree peonies endophytic fungi.

From the perspective of endophytic fungi community composition, all the three types of tree peonies have different dominant genera. Ecological or environmental conditions, such as temperature, humidity, illumination, geographic location, and vegetation significantly affected the distribution pattern and population structure of the endophytic fungi.²¹21 Jia M, Chen L, Xin H-L, et al. A friendly relationship between endophytic fungi and medicinal plants: a systematic review. Front Microbiol. 2016;7:906.Phomopsis is the dominant genus in the endophytic fungi community of P. ostii ‘Feng Dan’. That may have relevance to soil nutrition and geochemistry characteristic of Tongling city, Anhui Province, China. The study on the soil Cu, Cd, Pb and Zn at the copper-tailings reservoir of Tongling City showed that the Cu and Cd contents in soil were 4.36–14.43 and 3.67–3.86 times of the 2nd China national standard for soil environmental quality, respectively.²²22 Shen Z, Wang Y, Wang G, Yan M, Li Z, Liu D. Heavy metals pollution of Paeonia ostii land at copper-tailings reservoir of Tongling city: a preliminary study. Ying Yong Sheng Tai Xue Bao. 2005;16:673-677.^,²³23 Wang Y, Zhang L, Shen Z, Li J, Liu D. Chemical forms of heavy metals in the soils and plants of copper tailings yard. Chin J Appl Ecol. 2005;16:2418-2422.Phomopsis sp. is an ascomycete, that has attracted researcher's attention as a potential tool for heavy metal (copper, lead, zinc, etc.) contamination remediation. Research results indicate that after 24 h contact time, up to 870 mmol/g of lead, 390 mmol/g of copper, 230 mmol/g of cadmium, 150 mmol/g of zinc and 110 mmol/g of nickel ions are adsorbed into Phomopsis sp. biomaterial.²⁴24 Sutjaritvorakul T, Whalley AJS, Roengsumran S, Sihanonth P. Solubilization and accumulation of insoluble zinc and lead compounds by fungi isolated from zinc mine. J Pure Appl Microbiol. 2013;7:1043-1046.^,²⁵25 Saiano F, Ciofalo M, Cacciola SO, Ramirez S. Metal ion adsorption by Phomopsis sp. biomaterial in laboratory experiments and real wastewater treatments. Water Res. 2005;39:2273-2280. In addition, endophytic fungi of Phomopsis sp. are excellent potential sources of novel, bioactive natural products for exploitation in medicine, agriculture, and industry.²⁶26 Krohn K, Farooq U, Hussain H, et al. Novel highly substituted biaryl ethers, isolated from the endophytic fungus Phomopsis sp. from Ligustrum vulgare. Nat Prod Commun. 2011;6:1907-1912.^,²⁷27 Verma VC, Kharwar RN, Strobel GA. Chemical and functional diversity of natural products from plant associated endophytic fungi. Nat Prod Commun. 2009;4:1511-1532.Fusarium and Alternaria are the dominant genera in the endophytic fungi community of P. ostii ‘Luoyang Feng Dan’ and P. suffruticosa ‘Luoyang Hong’. They are the major plant pathogenic genera and the common genera in plant endophytic fungi community.²⁸28 Grube S, Schonling J, Prange A. Evaluation of a triplex real-time PCR system to detect the plant-pathogenic molds Alternaria spp., Fusarium spp. and C. purpurea. J Microbiol Meth. 2015;119:180-188.^–³¹31 Macia-Vicente JG, Jansson HB, Abdullah SK, Descals E, Salinas J, Lopez-Llorca LV. Fungal root endophytes from natural vegetation in Mediterranean environments with special reference to Fusarium spp. FEMS Microbiol Ecol. 2008;64:90-105.

Over centuries of treating disease and attempting to preserve health, ancestors of the Chinese people developed the traditional Chinese medicine (TCM). In addition, China also has abundant natural resources of medicinal materials, which are the material basis for the application of TCM theory in preventing and treating disease. As the essence of Chinese medicinal materials, Daodi medicinal material has been playing an important role in treating disease and preserving health for thousands of years.¹1 Zhao ZZ, Guo P, Brand E. The formation of daodi medicinal materials. J Ethnopharmacol. 2012;140:476-481. Cortex Moutan, which was produced from P. ostii ‘Feng Dan’ in Tongling city, located in Anhui Province, is considered as Daodi medicinal material. However, Cortex Moutan, which was produced from P. ostii ‘Feng Dan’ that were transplanted in other regions of China or from other peony varieties, is called non-Daodi medicinal material. To date, the dominant factor of Daodi Cortex Moutan forming is not yet clear. Bioactive components are the material basis for Daodi medicinal material to exert positive effect in preventing and treating disease. The most intrinsic difference between Daodi medicinal material and non-Daodi medicinal material is the difference in the types and amounts of bioactive components in medicinal plant. The NRPS and PKS are responsible for synthesizing many secondary metabolites that exhibit an important biological activity and may be valuable drugs.³²32 Graça AP, Calisto R, Lage OM. Planctomycetes as novel source of bioactive molecules. Front Microbiol. 2016;7:1241. NRPS and PKS genomic analysis of the endophytic fungus reveals its potential for synthesis of natural products.³²32 Graça AP, Calisto R, Lage OM. Planctomycetes as novel source of bioactive molecules. Front Microbiol. 2016;7:1241.^,³³33 Wang X, Zhang X, Liu L, et al. Genomic and transcriptomic analysis of the endophytic fungus Pestalotiopsis fici reveals its lifestyle and high potential for synthesis of natural products. BMC Genomics. 2015;16:28. In this study, NRPS and PKS gene sequences originating from fungal endophytes of three types of tree peonies were detected by Degenerate PCRs. As can be seen from the results (Tables 4 and 5), the PKSs and NRPS detection rates of endophytic fungi from P. ostii ‘Feng Dan’, which is the raw material of Daodi Cortex Moutan, are both the highest among the three types of tree peonies. The results of the above studies indicate that the endophytic fungi from P. ostii ‘Feng Dan’ have bigger potential for synthesis of natural products.

Acknowledgements

The authors wish to acknowledge the National Natural Science Foundation of China for financial support (project number 31302133).

References

¹
Zhao ZZ, Guo P, Brand E. The formation of daodi medicinal materials. J Ethnopharmacol 2012;140:476-481.
²
Guo L, Wang S, Zhang J, et al. Effects of ecological factors on secondary metabolites and inorganic elements of Scutellaria baicalensis and analysis of geoherblism. Science China: Life Sci 2013;56:1047-1056.
³
Kusari S, Pandey SP, Spiteller M. Untapped mutualistic paradigms linking host plant and endophytic fungal production of similar bioactive secondary metabolites. Phytochemistry 2013;91:81-87.
⁴
Tan R, Zou W. Endophytes: a rich source of functional metabolites. Nat Prod Rep 2001;18:448-459.
⁵
Strobel G, Daisy B. Bioprospecting for microbial endophytes and their natural products. Microbiol Mol Biol Rev 2003;67:491-502.
⁶
Sun X, Guo L-D. Endophytic fungal diversity: review of traditional and molecular techniques. Mycology 2012;3:65-76.
⁷
Stierle A, Strobel G, Stierle D. Taxol and taxane production by Taxomyces andreanae, an endophytic fungus of Pacific yew. Science 1993;260:214.
⁸
Satish Chander P, Vijeshwar V, Touseef A, Ghulam Nabi Q, Michael S. An endophytic fungus from Nothapodytes foetida that produces camptothecin. J Nat Prod 2005;68:1717-1719.
⁹
Kusari S, Lamshöft M, Spiteller M. Aspergillus fumigatus Fresenius, an endophytic fungus from Juniperus communis L. Horstmann as a novel source of the anticancer prodrug deoxypodophyllotoxin. J Appl Microbiol 2009;107:1019-1030.
¹⁰
Kusari S, Lamshoft M, Zühlke S, Spiteller M. An endophytic fungus from Hypericum perforatum that produces hypericin. J Nat Prod 2008;71:159-162.
¹¹
Wang Y, Gao BL, Li XX, Zhang ZB, Yan RM, Yang HL, Zhu D. Phylogenetic diversity of culturable endophytic fungi in Dongxiang wild rice (Oryza rufipogon Griff), detection of polyketide synthase gene and their antagonistic activity analysis. Fungal Biol 2015;119:1032-1045.
¹²
Evans BS, Robinson SJ, Kelleher NL. Surveys of non-ribosomal peptide and polyketide assembly lines in fungi and prospects for their analysis in vitro and in vivo. Fungal Genet Biol 2011;48:49-61.
¹³
Cho WCS, Miller KI, Qing C, Sze DMY, Neilan BA. Investigation of the biosynthetic potential of endophytes in traditional Chinese anticancer herbs. PLoS ONE 2012;7:e35953.
¹⁴
Peng LP, Cai CF, Zhong Y, et al. Genetic analyses reveal independent domestication origins of the emerging oil crop Paeonia ostii, a tree peony with a long-term cultivation history. Sci Rep 2017;7:5340.
¹⁵
Li P, Yang GD, Qiu Y, Lin L, Dong F. Paeonol produced by Chaetomium sp., an endophytic fungus isolated from Paeonia suffruticosa Phytochem Lett 2015;13:334-342.
¹⁶
Zhou K, Zhang X, Zhang F, Li Z. Phylogenetically diverse cultivable fungal community and polyketide synthase (PKS), non-ribosomal peptide synthase (NRPS) genes associated with the South China Sea Sponges. Microb Ecol 2011;62:644-654.
¹⁷
Rédou V, Navarri M, Meslet-Cladière L, Barbier G, Burgaud G, Brakhage AA. Species richness and adaptation of marine fungi from deep-subseafloor sediments. Appl Environ Microbiol 2015;81:3571-3583.
¹⁸
Hata K, Futai K. Endophytic fungi associated with healthy pine needles and needles infested by the pine needle gall midge. Thecodiplosis japonensis Can J Bot 1995;73:384-390.
¹⁹
Saucedo-García A, Anaya AL, Espinosa-García FJ, González MC. Diversity and communities of foliar endophytic fungi from different agroecosystems of Coffea arabica L. in two regions of Veracruz, Mexico. PLoS ONE 2014;9:e98454.
²⁰
Wang J, Meier S, Soininen J, et al. Regional and global elevational patterns of microbial species richness and evenness. Ecography 2016;39:1-10.
²¹
Jia M, Chen L, Xin H-L, et al. A friendly relationship between endophytic fungi and medicinal plants: a systematic review. Front Microbiol 2016;7:906.
²²
Shen Z, Wang Y, Wang G, Yan M, Li Z, Liu D. Heavy metals pollution of Paeonia ostii land at copper-tailings reservoir of Tongling city: a preliminary study. Ying Yong Sheng Tai Xue Bao 2005;16:673-677.
²³
Wang Y, Zhang L, Shen Z, Li J, Liu D. Chemical forms of heavy metals in the soils and plants of copper tailings yard. Chin J Appl Ecol 2005;16:2418-2422.
²⁴
Sutjaritvorakul T, Whalley AJS, Roengsumran S, Sihanonth P. Solubilization and accumulation of insoluble zinc and lead compounds by fungi isolated from zinc mine. J Pure Appl Microbiol 2013;7:1043-1046.
²⁵
Saiano F, Ciofalo M, Cacciola SO, Ramirez S. Metal ion adsorption by Phomopsis sp. biomaterial in laboratory experiments and real wastewater treatments. Water Res 2005;39:2273-2280.
²⁶
Krohn K, Farooq U, Hussain H, et al. Novel highly substituted biaryl ethers, isolated from the endophytic fungus Phomopsis sp. from Ligustrum vulgare Nat Prod Commun 2011;6:1907-1912.
²⁷
Verma VC, Kharwar RN, Strobel GA. Chemical and functional diversity of natural products from plant associated endophytic fungi. Nat Prod Commun 2009;4:1511-1532.
²⁸
Grube S, Schonling J, Prange A. Evaluation of a triplex real-time PCR system to detect the plant-pathogenic molds Alternaria spp., Fusarium spp. and C. purpurea J Microbiol Meth 2015;119:180-188.
²⁹
Summerell BA, Leslie JF, Liew ECY, et al. Fusarium species associated with plants in Australia. Fungal Divers 2011;46:1-27.
³⁰
Tao G, Liu ZY, Hyde KD, Liu XZ, Yu ZN. Whole rDNA analysis reveals novel and endophytic fungi in Bletilla ochracea (Orchidaceae). Fungal Divers 2008;33:101-122.
³¹
Macia-Vicente JG, Jansson HB, Abdullah SK, Descals E, Salinas J, Lopez-Llorca LV. Fungal root endophytes from natural vegetation in Mediterranean environments with special reference to Fusarium spp. FEMS Microbiol Ecol 2008;64:90-105.
³²
Graça AP, Calisto R, Lage OM. Planctomycetes as novel source of bioactive molecules. Front Microbiol 2016;7:1241.
³³
Wang X, Zhang X, Liu L, et al. Genomic and transcriptomic analysis of the endophytic fungus Pestalotiopsis fici reveals its lifestyle and high potential for synthesis of natural products. BMC Genomics 2015;16:28.

Edited by

Associate Editor: Derlene Attili de Angelis

Publication Dates

Publication in this collection
Nov 2018

History

Received
14 Mar 2018
Accepted
14 June 2018
Published
17 Aug 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

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Satish Chander P, Vijeshwar V, Touseef A, Ghulam Nabi Q, Michael S. An endophytic fungus from Nothapodytes foetida that produces camptothecin. J Nat Prod 2005;68:1717-1719.

[9] ⁹
Kusari S, Lamshöft M, Spiteller M. Aspergillus fumigatus Fresenius, an endophytic fungus from Juniperus communis L. Horstmann as a novel source of the anticancer prodrug deoxypodophyllotoxin. J Appl Microbiol 2009;107:1019-1030.

[10] ¹⁰
Kusari S, Lamshoft M, Zühlke S, Spiteller M. An endophytic fungus from Hypericum perforatum that produces hypericin. J Nat Prod 2008;71:159-162.

[11] ¹¹
Wang Y, Gao BL, Li XX, Zhang ZB, Yan RM, Yang HL, Zhu D. Phylogenetic diversity of culturable endophytic fungi in Dongxiang wild rice (Oryza rufipogon Griff), detection of polyketide synthase gene and their antagonistic activity analysis. Fungal Biol 2015;119:1032-1045.

[12] ¹²
Evans BS, Robinson SJ, Kelleher NL. Surveys of non-ribosomal peptide and polyketide assembly lines in fungi and prospects for their analysis in vitro and in vivo. Fungal Genet Biol 2011;48:49-61.

[13] ¹³
Cho WCS, Miller KI, Qing C, Sze DMY, Neilan BA. Investigation of the biosynthetic potential of endophytes in traditional Chinese anticancer herbs. PLoS ONE 2012;7:e35953.

[14] ¹⁴
Peng LP, Cai CF, Zhong Y, et al. Genetic analyses reveal independent domestication origins of the emerging oil crop Paeonia ostii, a tree peony with a long-term cultivation history. Sci Rep 2017;7:5340.

[15] ¹⁵
Li P, Yang GD, Qiu Y, Lin L, Dong F. Paeonol produced by Chaetomium sp., an endophytic fungus isolated from Paeonia suffruticosa Phytochem Lett 2015;13:334-342.

[16] ¹⁶
Zhou K, Zhang X, Zhang F, Li Z. Phylogenetically diverse cultivable fungal community and polyketide synthase (PKS), non-ribosomal peptide synthase (NRPS) genes associated with the South China Sea Sponges. Microb Ecol 2011;62:644-654.

[17] ¹⁷
Rédou V, Navarri M, Meslet-Cladière L, Barbier G, Burgaud G, Brakhage AA. Species richness and adaptation of marine fungi from deep-subseafloor sediments. Appl Environ Microbiol 2015;81:3571-3583.

[18] ¹⁸
Hata K, Futai K. Endophytic fungi associated with healthy pine needles and needles infested by the pine needle gall midge. Thecodiplosis japonensis Can J Bot 1995;73:384-390.

[19] ¹⁹
Saucedo-García A, Anaya AL, Espinosa-García FJ, González MC. Diversity and communities of foliar endophytic fungi from different agroecosystems of Coffea arabica L. in two regions of Veracruz, Mexico. PLoS ONE 2014;9:e98454.

[20] ²⁰
Wang J, Meier S, Soininen J, et al. Regional and global elevational patterns of microbial species richness and evenness. Ecography 2016;39:1-10.

[21] ²¹
Jia M, Chen L, Xin H-L, et al. A friendly relationship between endophytic fungi and medicinal plants: a systematic review. Front Microbiol 2016;7:906.

[22] ²²
Shen Z, Wang Y, Wang G, Yan M, Li Z, Liu D. Heavy metals pollution of Paeonia ostii land at copper-tailings reservoir of Tongling city: a preliminary study. Ying Yong Sheng Tai Xue Bao 2005;16:673-677.

[23] ²³
Wang Y, Zhang L, Shen Z, Li J, Liu D. Chemical forms of heavy metals in the soils and plants of copper tailings yard. Chin J Appl Ecol 2005;16:2418-2422.

[24] ²⁴
Sutjaritvorakul T, Whalley AJS, Roengsumran S, Sihanonth P. Solubilization and accumulation of insoluble zinc and lead compounds by fungi isolated from zinc mine. J Pure Appl Microbiol 2013;7:1043-1046.

[25] ²⁵
Saiano F, Ciofalo M, Cacciola SO, Ramirez S. Metal ion adsorption by Phomopsis sp. biomaterial in laboratory experiments and real wastewater treatments. Water Res 2005;39:2273-2280.

[26] ²⁶
Krohn K, Farooq U, Hussain H, et al. Novel highly substituted biaryl ethers, isolated from the endophytic fungus Phomopsis sp. from Ligustrum vulgare Nat Prod Commun 2011;6:1907-1912.

[27] ²⁷
Verma VC, Kharwar RN, Strobel GA. Chemical and functional diversity of natural products from plant associated endophytic fungi. Nat Prod Commun 2009;4:1511-1532.

[28] ²⁸
Grube S, Schonling J, Prange A. Evaluation of a triplex real-time PCR system to detect the plant-pathogenic molds Alternaria spp., Fusarium spp. and C. purpurea J Microbiol Meth 2015;119:180-188.

[29] ²⁹
Summerell BA, Leslie JF, Liew ECY, et al. Fusarium species associated with plants in Australia. Fungal Divers 2011;46:1-27.

[30] ³⁰
Tao G, Liu ZY, Hyde KD, Liu XZ, Yu ZN. Whole rDNA analysis reveals novel and endophytic fungi in Bletilla ochracea (Orchidaceae). Fungal Divers 2008;33:101-122.

[31] ³¹
Macia-Vicente JG, Jansson HB, Abdullah SK, Descals E, Salinas J, Lopez-Llorca LV. Fungal root endophytes from natural vegetation in Mediterranean environments with special reference to Fusarium spp. FEMS Microbiol Ecol 2008;64:90-105.

[32] ³²
Graça AP, Calisto R, Lage OM. Planctomycetes as novel source of bioactive molecules. Front Microbiol 2016;7:1241.

[33] ³³
Wang X, Zhang X, Liu L, et al. Genomic and transcriptomic analysis of the endophytic fungus Pestalotiopsis fici reveals its lifestyle and high potential for synthesis of natural products. BMC Genomics 2015;16:28.

Primer pair	Primer sequence (5'-3')	Amplification gene type
AUG003	CCGGCACCACCGGNAARCCHAA	NRPS
AUG007	GCTGCATGGCGGTGATGSWRTSNCCBCC	NRPS
LC1-R	GAYCCIMGITTYTTYAAYATG	PKS
LC2C-F	GTICCIGTICCRTGCATYTC	PKS
LC3-R	GCIGARCARATGGAYCCICA	PKS
LC5C-F	GTIGAIGTICRTGIGCYTC	PKS

Endophytic fungi	Species	Similarity %	Accession no.	Host plant^a a Fengdan, Paeonia ostii 'Feng Dan'; Luoyang Fengdan, Paeonia ostii 'Luoyang Feng Dan'; Luoyang Hong, Paeonia suffruticosa 'Luoyang Hong'.
A3G2	Peyronellaea	100%	KT343354.1	Fengdan
A5J2-08	Schizophyllum	100%	KT343355.1	Fengdan
A5J6F1	Pestalotiopsis	99%	KT343356.1	Fengdan
A5J2F2	Cladosporium	99%	KT343357.1	Fengdan
A5J8F3-2	Curvularia	100%	KT343358.1	Fengdan
A5J10B1	Chaetomium	100%	KT375580.1	Fengdan
A5J2F3	Seimatosporium	99%	KT375581.1	Fengdan
A5J8F1	Nectriaceae sp.	99%	KT375582.1	Fengdan
A5J6C1-2	Phomopsis	99%	KT375583.1	Fengdan
A5J1A1	Phomopsis	99%	KT375584.1	Fengdan
A5J6F3	Phomopsis	99%	KT375585.1	Fengdan
A5G10D1	Penicillium	99%	KT375586.1	Fengdan
A5J9F1-1-1	Phomopsis	99%	KT375587.1	Fengdan
A5J10F1	Sordariomycetes	100%	KT375588.1	Fengdan
A5J7F1-1	Nigrospora	99%	KT375589.1	Fengdan
A5J2B1-1-2	Nigrospora	99%	KT375590.1	Fengdan
A5J2B1-1	Nigrospora	99%	KT375591.1	Fengdan
A5J6D1	Phomopsis	99%	KT375592.1	Fengdan
A5J6C1-1-1	Nigrospora	99%	KT375593.1	Fengdan
A5J7F2	Pestalotiopsis	99%	KT375594.1	Fengdan
A5J3F1	Alternaria	99%	KT375595.1	Fengdan
A5J2B1-2	Alternaria	99%	KT375596.1	Fengdan
A3J1-01	Diaporthe	99%	KT375599.1	Fengdan
A7G2-12	Fusarium	98%	KT375601.1	Fengdan
A3J1-03	Ceratobasidium	99%	KT375600.1	Fengdan
A5J2-06	Talaromyces	98%	KT375597.1	Fengdan
A7J2-01	Fusarium	100%	KT375598.1	Fengdan
J6F1	Alternaria	100%	KT375676.1	Luoyang Fengdan
J1B1-2	Fusarium	99%	KT375677.1	Luoyang Fengdan
J₄D₁	Paraconiothyrium	97%	KT375678.1	Luoyang Fengdan
G1B1	Fusarium	99%	KT375679.1	Luoyang Fengdan
J₁C_1-2	Phoma	99%	KT375680.1	Luoyang Fengdan
J₉E₅	Alternaria	99%	KT375681.1	Luoyang Fengdan
J2A1	Paraconiothyrium	99%	KT375682.1	Luoyang Fengdan
G₉A₁	Fusarium	99%	KT375683.1	Luoyang Fengdan
G₈A₁	Fusarium	100%	KT375684.1	Luoyang Fengdan
J₄F_1-2	Fusarium	99%	KT375685.1	Luoyang Fengdan
J₁F₁	Botryosphaeria	99%	KT375686.1	Luoyang Fengdan
J₄C₁	Phoma	99%	KT375687.1	Luoyang Fengdan
J₉E₁	Fusarium	99%	KT375688.1	Luoyang Fengdan
J₁₀C₁	Botryosphaeria	99%	KT375689.1	Luoyang Fengdan
J₁A_1-2	Paraconiothyrium	99%	KT375690.1	Luoyang Fengdan
J₄E₁	Alternaria	99%	KT375691.1	Luoyang Fengdan
J₇A_1-1	Phoma	99%	KT375692.1	Luoyang Fengdan
G₇D₁	Fusarium	100%	KT375693.1	Luoyang Fengdan
S₃B_1-2	Fusarium	100%	KT375694.1	Luoyang Fengdan
G₆D₁	Fusarium	100%	KT375695.1	Luoyang Fengdan
S₁C₁	Phoma	99%	KT375696.1	Luoyang Fengdan
J13C1	Phoma	99%	KT375697.1	Luoyang Fengdan
J7C1	Botryosphaeria	99%	KT375698.1	Luoyang Fengdan
J1F	Botryosphaeria	99%	KT375699.1	Luoyang Fengdan
J₁₁A_1-1	Alternaria	100%	KT375700.1	Luoyang Fengdan
G₄A₁	Alternaria	100%	KT375701.1	Luoyang Fengdan
S₃C_1-2	Alternaria	100%	KT375702.1	Luoyang Fengdan
S₃B_1-3	Fusarium	99%	KT375703.1	Luoyang Fengdan
J₄C_1-1	Phoma	99%	KT375704.1	Luoyang Fengdan
J₁₂C₁	Phoma	99%	KT375705.1	Luoyang Fengdan
J₈D₁	Alternaria	100%	KT375706.1	Luoyang Fengdan
J1B1-1	Alternaria	99%	KT375724.1	Luoyang Fengdan
J6E1	Phoma	95%	KT375708.1	Luoyang Fengdan
J11B1	Phoma	99%	KT375709.1	Luoyang Fengdan
G9C1	Fusarium	100%	KT375710.1	Luoyang Fengdan
J12B1	Phoma	100%	KT375711.1	Luoyang Fengdan
J7A1-2	Paraconiothyrium	99%	KT375712.1	Luoyang Fengdan
G8C1	Fusarium	99%	KT375713.1	Luoyang Fengdan
G5-3	Phialophora	95%	KT375714.1	Luoyang Fengdan
J4C1-2	Phoma	99%	KT375715.1	Luoyang Fengdan
J4F1	Fusarium	99%	KT375716.1	Luoyang Fengdan
J6C1	Phoma	99%	KT375717.1	Luoyang Fengdan
J6D1	Phoma	99%	KT375718.1	Luoyang Fengdan
S3B1-1	Fusarium	99%	KT375719.1	Luoyang Fengdan
G10B1	Fusarium	99%	KT375720.1	Luoyang Fengdan
J7B1	Alternaria	100%	KT375721.1	Luoyang Fengdan
FJ2D1	Alternaria	99%	KT375722.1	Luoyang Fengdan
G3-5	Schizophyllum	99%	KT375723.1	Luoyang Fengdan
J1B1-1-1	Alternaria	99%	KT375724.1	Luoyang Fengdan
J3B1	Fusarium	99%	KT375725.1	Luoyang Fengdan
G10A1-1	Ilyonectria	99%	KT375726.1	Luoyang Fengdan
Y3-1	Chaetomium	99%	KT375727.1	Luoyang Fengdan
G1-4	Schizophyllum	99%	KT375728.1	Luoyang Fengdan
J1-2	Chaetomium	99%	KP994323.1	Luoyang Fengdan
G1-1	Fusarium	99%	KT375729.1	Luoyang Fengdan
LY₂A₁	Alternaria	99%	KT375602.1	Luoyang Hong
LG₆B₁	Cephalosporium	95%	KT375603.1	Luoyang Hong
LY₃A_1-2	Fusarium	95%	KT375604.1	Luoyang Hong
LJ₂G₁	Alternaria	99%	KT375605.1	Luoyang Hong
LY₄E_1-3	Alternaria	99%	KT375606.1	Luoyang Hong
LJ₁₄F₁	Nigrospora	99%	KT375607.1	Luoyang Hong
LG₁C₁	Pilidium	99%	KT375608.1	Luoyang Hong
LJ₁₁A₁	Pestalotiopsi	99%	KT375609.1	Luoyang Hong
LJ₄B₁	Fusarium	99%	KT375610.1	Luoyang Hong
LJ₁₂G₁	Alternaria	99%	KT375611.1	Luoyang Hong
LJ₁₄E₁	Fusarium	99%	KT375612.1	Luoyang Hong
LG₁₂B₁	Arthopyreniaceae	98%	KT375652.1	Luoyang Hong
LY₁F₁	Fusarium	97%	KT375613.1	Luoyang Hong
LJ₁₂B₁	Alternaria	99%	KT375614.1	Luoyang Hong
LJ₉C_1-2	Phomopsis	99%	KT375615.1	Luoyang Hong
LY₃B_1-1	Fusarium	99%	KT375616.1	Luoyang Hong
LJ₇H_1-2	Alternari	99%	KT375617.1	Luoyang Hong
LJ₁₃F₁	Botryosphaeria	99%	KT375618.1	Luoyang Hong
LJ₁₁H₁	Fusarium	99%	KT375619.1	Luoyang Hong
LJ₁₂J_1-1	Fusarium	99%	KT375620.1	Luoyang Hong
LY₃D_1-2	Fusarium	99%	KT375621.1	Luoyang Hong
LJ₄D_1-1	Fusarium	99%	KT375622.1	Luoyang Hong
LG₂G₁	Pilidium	100%	KT375623.1	Luoyang Hong
LG₅C₁	Fusarium	99%	KT375624.1	Luoyang Hong
LY₆C₁	Alternaria	100%	KT375625.1	Luoyang Hong
LG₁₃B₁	Alternaria	99%	KT375626.1	Luoyang Hong
LJ₉B₁	Alternaria	100%	KT375627.1	Luoyang Hong
LA₂A₁	Alternaria	100%	KT375628.1	Luoyang Hong
LY₁B₁	Alternaria	99%	KT375629.1	Luoyang Hong
LY₃C₁	Alternaria	100%	KT375630.1	Luoyang Hong
LY₁₂F₁	Pestalotiopsis	100%	KT375631.1	Luoyang Hong
LY₅A₁	Pestalotiopsis	100%	KT375632.1	Luoyang Hong
LY₂C₁	Alternaria	99%	KT375633.1	Luoyang Hong
LY₂E₁	Alternaria	99%	KT375634.1	Luoyang Hong
LJ₁₁F₁	Alternaria	99%	KT375635.1	Luoyang Hong
LY₄D₁	Alternaria	99%	KT375636.1	Luoyang Hong
LY₁G₁	Alternaria	99%	KT375637.1	Luoyang Hong
LY4E1-1	Alternaria	99%	KT375638.1	Luoyang Hong
LY3G1	Alternaria	99%	KT375639.1	Luoyang Hong
LY7A1	Alternaria	99%	KT375640.1	Luoyang Hong
LJ8C1	Alternaria	99%	KT375641.1	Luoyang Hong
LG3E1	Fusarium	100%	KT375642.1	Luoyang Hong
LJ12D1-2	Alternaria	100%	KT375643.1	Luoyang Hong
LY6A1	Nigrospora	99%	KT375644.1	Luoyang Hong
LJ5F1	Alternaria	99%	KT375645.1	Luoyang Hong
LJ3D1-1	Fusarium	99%	KT375646.1	Luoyang Hong
LJ5I1	Alternaria	99%	KT375647.1	Luoyang Hong
LJ1D1	Alternaria	99%	KT375648.1	Luoyang Hong
LJ14D1	Alternaria	99%	KT375649.1	Luoyang Hong
LY4B1	Alternaria	100%	KT375650.1	Luoyang Hong
LJ13A1	Alternaria	99%	KT375651.1	Luoyang Hong
LY3E1	Alternaria	100%	KT375653.1	Luoyang Hong
LJ3-5	Fusarium	99%	KT375654.1	Luoyang Hong
LY1C1-1	Alternaria	100%	KT375655.1	Luoyang Hong
LA3A1	Alternaria	99%	KT375656.1	Luoyang Hong
LJ3-3	Fusarium	99%	KT375657.1	Luoyang Hong
LY4E1-2	Alternaria	99%	KT375658.1	Luoyang Hong
LJ14C1	Alternaria	100%	KT375659.1	Luoyang Hong
LJ4F1	Fusarium	100%	KT375660.1	Luoyang Hong
LJ9C1-1	Pestalotiopsis	99%	KT375661.1	Luoyang Hong
LJ8D1	Alternaria	99%	KT375662.1	Luoyang Hong
LY5C1	Pilidium	100%	KT375663.1	Luoyang Hong
LG15C1	Fusarium	100%	KT375664.1	Luoyang Hong
LY6B1	Alternaria	99%	KT375665.1	Luoyang Hong
LY2B1	Alternaria	99%	KT375666.1	Luoyang Hong
LY1A1	Fusarium	99%	KT375667.1	Luoyang Hong
LD13D1	Alternaria	99%	KT375668.1	Luoyang Hong
LJ6A1	Alternaria	100%	KT375669.1	Luoyang Hong
LY1D1	Alternaria	99%	KT375670.1	Luoyang Hong
LY4E	Alternaria	99%	KT375671.1	Luoyang Hong
LY5B1-1	Alternaria	100%	KT375672.1	Luoyang Hong
LA2B1	Alternaria	99%	KT375673.1	Luoyang Hong
LG5B1	Fusarium	99%	KT375674.1	Luoyang Hong
LJ1-1-1	Phyllosticta	99%	KT375675.1	Luoyang Hong

Endophtic fungi	Host plant^a a Fengdan, Paeonia ostii 'Feng Dan'; Luoyang Fengdan, Paeonia ostii 'Luoyang Feng Dan'; Luoyang Hong, Paeonia suffruticosa 'Luoyang Hong'.	BLASTX match	Identity (%)	Accession no.
A5J9F1-1-1	Fengdan	Dothiorella aegiceri putative PKS	99	ABS85549.1
A7J201	Fengdan	Dipiodia seriata putative PKS	99	KKY20157.1
A5J1A1	Fengdan	Dothiorella aegiceri putative PKS	99	ABS85549.1
A5J3F1	Fengdan	Alternaria alternata PKS	100	AEH76763.1
A5J7F2	Fengdan	Cladosporium phlei non-reducing PKS	99	AFP89389.1
A5J6C1-2	Fengdan	Dothiorella aegiceri putative PKS	99	ABS85549.1
A5J2B1-1	Fengdan	Alternaria alternata PKS	100	AEH76763.1
A5J6D1	Fengdan	Dothiorella aegiceri putative PKS	98	ABS85549.1
A5J2B1-1-2	Fengdan	Pestalotiopsis malicola PKS	94	AGT56219.1
A5J10F1	Fengdan	Ascochyta anemones PKS	99	AGF50217.1
A5G10D1	Fengdan	Talaromyces marneffei ATCC 18224 conidial PKS	98	XP 002147717.1
A5J8F3-2	Fengdan	Bipolaris maydis PKS	99	AAR90272.1
A5J6F3	Fengdan	Dothiorella aegiceri putative PKS	99	ABS85549.1
J13C1	Luoyang Fengdan	Phoma sp. F41 PKS	98	AFH77855.1
J6D1	Luoyang Fengdan	Ascochyta anemones PKS	99	AGF50217.1
J4E1	Luoyang Fengdan	Alternaria alternata PKS	99	AEH76763.1
J6F1	Luoyang Fengdan	Alternaria alternata PKS	99	AEH76763.1
J12B1	Luoyang Fengdan	Ascochyta rabiei 1,3,6,8-tetrahydroxynaphthalene PKS	99	ACS74449.1
J9E5	Luoyang Fengdan	Alternaria alternata PKS	99	AEH76763.1
J10C1	Luoyang Fengdan	Diplodia seriata putative PKS	98	KKY20157.1
J4C1-2	Luoyang Fengdan	Ascochyta rabiei 1,3,6,8-tetrahydroxynaphthalene PKS	98	ACS74449.1
J2A1	Luoyang Fengdan	Bipolaris maydis PKS	97	AAR90272.1
J6C1	Luoyang Fengdan	Ascochyta rabiei 1,3,6,8-tetrahydroxynaphthalene PKS	99	ACS74449.1
J4D1	Luoyang Fengdan	Bipolaris maydis PKS	97	AAR90272.1
J1F1	Luoyang Fengdan	Diplodia seriata putative PKS	98	KKY20157.1
J1A1-2	Luoyang Fengdan	Bipolaris maydis PKS	97	AAR90272.1
J1B1-2	Luoyang Fengdan	Diplodia seriata putative PKS	99	KKY20157.1
J4C1	Luoyang Fengdan	Ascochyta rabiei 1,3,6,8-tetrahydroxynaphthalene PKS	99	ACS74449.1
G5-3	Luoyang Fengdan	Marssonina brunneaf sp. 'multigermtubi' MB-m1 PKS	94	XP007295542.1
J7C1	Luoyang Fengdan	Diplodia seriata putative PKS	99	KKY20157.1
J11B1	Luoyang Fengdan	Ascochyta rabiei 1,3,6,8-tetrahydroxynaphthalene PKS	98	ACS74449.1
S3C1-2	Luoyang Fengdan	Alternaria alternata PKS	99	AEH76763.1
J8D1	Luoyang Fengdan	Alternaria alternata PKS	100	AEH76763.1
J4C1-1	Luoyang Fengdan	Ascochyta rabiei 1,3,6,8-tetrahydroxynaphthalene PKS	99	ACS74449.1
G4A1	Luoyang Fengdan	Alternaria alternata PKS	99	AEH76763.1
J6E1	Luoyang Fengdan	Ascochyta rabiei 1,3,6,8-tetrahydroxynaphthalene PKS	98	ACS74449.1
LJ14F1	Luoyang Hong	Trichoderma sp. CBMAI 1018 PKS	93	ADY75766.1
LJ12B1	Luoyang Hong	Conidial yellow piqment biosynthesis PKS	99	XP001933656.1
LJ13F1	Luoyang Hong	Dipiodia seriata putative PKS	99	KKY20157.1
LY4B1	Luoyang Hong	Alternaria sp. ALF3-2 PKS	100	AIR77264.1
LY7A1	Luoyang Hong	Alternaria alternata putative 6-MSA-type PKS	93	BAG80613.1
LJ9B1	Luoyang Hong	Conidial yellow piqment biosynthesis PKS	99	XP001933656.1
LY1G1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY2A1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY4E1-1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LJ8D1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY4E1-3	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LJ12G1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY2E1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LA2A1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY1C1-1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY4D1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LJ12D1-2	Luoyang Hong	Humicolopsis cephalosporioides PKS	90	AGH27151.1
LG1C1	Luoyang Hong	Humicolopsis cephalosporioides PKS	90	AGH27151.1
LJ7H1-2	Luoyang Hong	Alternaria alternata PKS	100	AEH76763.1
LA3A1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LJ13A1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY6C1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LJ2G1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LG2G1	Luoyang Hong	Humicolopsis cephalosporioides PKS	90	AGH27151.1
LY5C1	Luoyang Hong	Humicolopsis cephalosporioides PKS	90	AGH27151.1
LJ8C1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY3G1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LG12B1	Luoyang Hong	Dipiodia seriata putative PKS	98	KKY20157.1
LJ9C1-2	Luoyang Hong	Dothiorella aegiceri putative PKS	99	ABS85549.1
LY2C1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LY1B1	Luoyang Hong	Alternaria alternata PKS	99	AEH76763.1
LJ11H1	Luoyang Hong	Dipiodia seriata putative PKS	98	KKY20157.1
LY3C1	Luoyang Hong	Alternaria alternata PKS	100	AEH76763.1

Endophtic fungi	Host plant^a a Fengdan, Paeonia ostii 'Feng Dan'; Luoyang Fengdan, Paeonia ostii 'Luoyang Feng Dan'; Luoyang Hong, Paeonia suffruticosa 'Luoyang Hong'.	BLASTX match	Identity (%)	Accession no.
LJ14F1	Luoyang Hong	Thielavia terrestris NRRL 8126 NRPS	75	XM_003651133.1
A5J6D1	Fengdan	Talaromyces stipitatus ATCC 10500 NRPS	70	XM_002483235.1
A5J6F3	Fengdan	Metarhizium robertsii ARSEF 23 NRPS Mrna	72	XM_007827951.1
A5J1A1	Fengdan	Myceliophthora thermophila ATCC 42464 NRPS	72	XM_003666434.1
J1B1-2	Luoyang Fengdan	Thielavia terrestris NRRL 8126 NRPS	64	XM_003651133.1
J7C1	Luoyang Fengdan	Thielavia terrestris NRRL 8126 NRPS	67	XM_003651133.1
J1F1	Luoyang Fengdan	Thielavia terrestris NRRL 8126 NRPS	75	XM_003651133.1
G1B1	Luoyang Fengdan	Aspergillus niger CBS 513.88 NRPS	69	XM 001392310.2

Brasil

Brasil

Diversity and communities of culturable endophytic fungi from different tree peonies (geoherbs and non-geoherbs), and their biosynthetic potential analysis

Abstract

Introduction

Materials and methods

Plant sample collection

Isolation and identification of endophytic fungi

Screening of PKS and NRPS genes in tree peonies endophytic fungi

Date analysis

Results

Abundance and diversity of endophytic fungi

Community composition of endophytic fungi

Identification of genes encoding bioactivity in tree peonies endophytic fungi

Discussion

Acknowledgements

References

Edited by

Publication Dates

History

Parameters	Paeonia ostii 'Feng Dan'	Paeonia ostii 'Luoyang Feng Dan'	Paeonia suffruticosa 'Luoyang Hong'
No. of fragments incubated	78	78	78
No. of fragments colonized	36	44	40
Total number of isolates	60	98	206
Colonization rate (CR)	0.4872	0.5641	0.8846
Isolation rate (IR)	0.7692	1.2564	2.64
Species richness (S)	17	9	10
Shannon diversity index (H')	2.5757	1.7730	1.3458
Simpson's diversity index (D)	0.9006	0.7876	0.6125
Pielou's Evenness Index (J)	0.9091	0.8069	0.5845