基于PTN系统分析不同种植地转基因水稻种子 可培养内生真菌菌群的多样性

doi:10.3864/j.issn.0578-1752.2020.11.016

摘要/Abstract

摘要：

【目的】比较不同种植地、不同品种来源的转基因（genetically modified,GM）水稻近等基因系种子内生真菌的丰富度和多样性,探讨变异发生的影响因素,为研究GM水稻种子内生真菌种群结构的非预期变异提供科学基础。【方法】收集转2mG2-epsps抗草甘膦水稻株系（transgenic line,T）,及相应的对照样本亲本品种（parent variety,P）和非转基因组培再生株系（non-transgenic regeneration line from tissue culture,NR）,建立亲本对照-转基因株系-非转基因对照（parent control-transgenic plant line-non-transgenic control,PTN）近等基因系。粳稻品种日本晴亲本（P1）及其相应的T16和NR25组成P1近等基因系（P1 near-isogenic line,P1L）,粳稻品种PJ574亲本（P2）及其相应的T23和NR18组成P2近等基因系（P2 near-isogenic line,P2L）。在海南省（Hainan province,H）和浙江省富阳市（Fuyang,Zhejiang province,F）两地种植并收获水稻种子,采用组织培养法分离内生真菌,通过形态学和分子生物学相结合的方法对菌株分类鉴定。以分离率（isolation rate,IR）、分离频率（isolation frequency,IF）、丰富度指数Margalef（D）、多样性指数Shannon-Wiener（H'）和均匀度指数Evenness（E）反映真菌的结构和分布,以Sorenson相似性系数（Cs）和Fisher精确检验（Fisher's exact test）结果描述水稻样本之间的内生真菌菌群组成差异。【结果】从海南省和浙江省富阳市两地的P1L和P2L近等基因系水稻种子样本中共分离121株内生真菌,鉴定为15个属,其中,Curvularia、Dendryphiella、Epicoccum、Fusarium为优势菌属,Fusarium为两地共有的优势菌属。F地水稻种子内生真菌总IR（4.61%）是H地样本（0.83%）的5.05倍。F地样本内生真菌类群的丰富度指数（2.29）,Shannon-Wiener（H'）多样性指数（1.63）和均匀度指数（0.66）均显著高于H地样本。H地种植的P1L和P2L种子内生真菌菌属组成的相似性系数（Cs）为0.615,F地种植时二者的Cs=0.737,均为中等相似,Fisher精确检验分析表明二者无显著性差异（P>0.05）。除HT16外的GM株系与相应亲本种子内生真菌类群的相似性系数为0.500—0.667,均为中等相似。但与相应亲本相比,GM水稻株系种子内生真菌的IF和菌属数存在显著性非预期变异,其中IF变异方向和幅度因种植地不同而波动。而且FT16增加2个菌属Phaeosphaeria和Nigrospora,HT23增加了1个菌属Letendraea helminthicola,FT23增加了Curvularia和Cladosporium 2个菌属,这些GM株系种子内生真菌菌属增多的变异来源于转基因插入突变,需要关注其安全性。而GM株系种子内生真菌种类减少的变异来源于组织培养无性系变异,较为安全。水稻种子真菌IF变异幅度及排序：P1和P2品种两地之间差异（30.58%）>P1和P2品种之间差异（27.28%）>NR株系变异（23.14%）>GM株系变异（22.32%）。种子内生真菌总属数变异幅度及排序：P1和P2品种两种植地之间差异（9）>P1和P2品种之间差异（8）=NR株系变异（8）=GM株系变异（8）。【结论】水稻种子内生真菌丰富多样,可培养内生真菌绝大多数为子囊菌。不同种植地域水稻种子内生真菌菌群组成存在差异,镰刀菌（Fusarium）为海南省和浙江省富阳市两地水稻种子的共有优势内生菌属。转基因技术和组织培养技术均显著影响水稻种子内生真菌类群的结构,但其非预期变异效应低于种植地域影响和品种差异,其中GM水稻种子内生真菌菌属种类增多的变异主要来源于转基因插入突变效应,需安全性评估。

关键词: 转基因水稻种子, 可培养内生真菌, 非预期变异, PTN系统, 多样性

Abstract:

【Objective】To provide scientific bases for study of the unintended variation in seed endophytic fungi community structure of genetically modified (GM) rice and explore the causing factors of variation, comparative analysis of the richness and biodiversity of seed endophytic fungi were conducted, using GM rice relative near-isogenic lines of different varieties in different cultivation sites as materials. 【Method】 Collect transgenic rice line which harboring the glyphosate resistant 2mG2-epsps gene (T) and its corresponding parent variety (P) and non-transgenic tissue culture regeneration control line (NR) to make parent control-transgenic plant line-non-transgenic control (PTN) near-isogenic line. The parent japonica rice Nipponbare (P1) and its corresponding transgenic line T23 and the NR control line NR18 formed the P1 near-isogenic line (P1L), the P2 near-isogenic line (P2L) composed of parent japonica rice PJ574 (P2) and its corresponding transgenic line T23 and the NR control line NR18. All rice samples were planted in two plantations including Hainan province (H) and Fuyang city of Zhejiang province (F) and the resulting seeds were harvested. The rice endophytic fungi were isolated by tissue separation method, strains were classified and identified with morphology and molecular biology methods. The isolation rate (IR), isolation frequency (IF), richness Margalef index (D), diversity Shannon-Wiener index (H') and Evenness index (E) were used to reflect the structure and distribution of rice seed endophytic fungi, and Sorenson similarity coefficient (Cs) and Fisher’s exact test were employed to describe the composition difference of endophytic fungi between rice samples. 【Result】A total of 121 endophytic fungi strains were isolated from rice seed samples of P1L and P2L near-isogenic lines that harvested in Hainan (H) and Zhejiang (F) plantations, they were identified as 15 genera, of which Curvularia, Dendryphiella, Epicoccum, Fusarium were confirmed as the dominant flora, with Fusarium as the common dominant genus of both H and F plantations. The total RF (4.61%) of endophytic fungi from Zhejiang-grown rice seeds is 5.05 times than that of Hainan-grown rice samples (0.83%). The richness Margalef index (D=2.29), Shannon-Wiener diversity index (H'=1.63) and Evenness index (E=0.66) of endophytic fungi flora from rice seeds in F plantation were higher than that (D=1.67, H'=0.63, E=0.29) of samples in H plantation. The seed endophytic fungi communities of P1L and P2L in H plantation had a similarity coefficient of 0.615, and that was 0.737 in F plantation, showing moderate similarity, and the Fisher’s exact test analysis suggested that there were no significant difference (P>0.05) between them. The GM lines except HT16 showed moderate similarity to their corresponding parent controls referring seed endophytic fungi communities, with similarity coefficient ranged between 0.500 and 0.667. But compared with their corresponding parents, the GM rice lines showed notably unintended variations in IF and genus numbers of endophytic fungi, the variation direction and amplitude of IF varied between different plantations. Also, the GM line FT16 increased 2 additional fungi genera Phaeosphaeria and Nigrospora, HT23 and FT23 respectively added 1 genus Letendraea helminthicola and 2 genera including Curvularia and Cladosporium. These genera increasing variations of endophytic fungi in GM rice seeds were derived from transgenic insertion mutation, whose safety needs to be focused on. While the genera decreasing variations of endophytic fungi in GM rice seeds were derived from somaclonal variation of tissue culture, which were safer. The variation amplitude order of total IF of rice endophytic fungi were as follows. Difference between H and F plantations referring to P1 and P2 (30.58%)>Difference between P1 and P2 varieties (27.28%)>Variation of NR lines (23.14%)>Variation of GM lines (22.32%). The genus number variations of rice endophytic fungi ranked as follows. Difference between H and F plantations referring to P1 and P2 (9)>Difference between P1 and P2 varieties (8) = Variation of NR lines (8) = Variation of GM lines (8). 【Conclusion】Rice seeds have abundant and diverse endophytic fungi, with majority of the culturable stains belong to Ascomycetes. Composition of rice seed endophytic fungi community shows geographical differences, and Fusarium is very common dominant genus in rice seeds grown both in Hainan and Zhejiang. The structure of endophytic fungi flora in rice seeds are affected by transgenic manipulation as well as tissue culture technology, while their unintended variation effects are less than that of rice growing locations and variety differences. The genera increasing variations of endophytic fungi in GM rice seeds are derived from transgenic insertion mutation, and the safety needs to be assessed.

Key words: transgenic rice seed, culturable endophytic fungi, unintended variation, PTN system, diversity

赵艳,王天圻,朱军莉. 基于PTN系统分析不同种植地转基因水稻种子可培养内生真菌菌群的多样性[J]. 中国农业科学, 2020, 53(11): 2305-2320.

ZHAO Yan,WANG TianQi,ZHU JunLi. Diversity of Endophytic Fungi in Transgenic Rice Seeds from Different Planting Sites Based on PTN System[J]. Scientia Agricultura Sinica, 2020, 53(11): 2305-2320.

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图/表 9

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表1

水稻种子可培养内生真菌的鉴定结果"

编号 Number	纲 Class	目 Order	科 Family	属 Genera	比对相似种 Compare similar species	覆盖率 Coverage (%)	相似度 Similarity (%)	比对结果 Comparison result	IR (%)
WF6	Ascomycetes	Pleosporales	Pleosporaceae	Curvularia	Curvularia lunata strain S3-2	97	99	Curvularia lunata strain WF6	0.54
WF44					Curvularia lunata isolate E16	97	99	Curvularia lunata isolate WF44	0.08
				合计Total					0.63
WF17				Pleosporales	Pleosporales sp. strain APBSDSF36	97	100	Pleosporales sp. strain WF17	0.04
				合计Total					0.04
WF22				Phaeosphaeria	Phaeosphaeriopsis musae isolate DFFSCS029	99	99	Phaeosphaeriopsis musae strain WF22	0.04
WF55					Phaeosphaeria papayae isolate LQ122404	98	99	Phaeosphaeria papayae isolate WF55	0.04
				合计Total					0.08
WF40				Setophoma	Setophoma vernoniae strain CPC 23123	92	93	Setophoma vernoniae strain .WF40	0.13
				合计Total					0.13
WF39	Ascomycetes	Pleosporales	Pleosporaceae	Ophiosphaerella	Ophiosphaerella agrostidis strain MFLUCC 11-0152	95	99	Ophiosphaerella agrostidis strain.WF39	0.13
WF58					Ophiosphaerella agrostidis isolate MFLUCC 16-0895	94	99	Ophiosphaerella agrostidis isolate WF58	0.04
				合计Total					0.17
WF41				Dendryphiella	Dendryphiella sp. crri.34	98	99	Dendryphiella sp. WF41	0.83
WF42					Dendryphiella sp. crri.34	97	99	Dendryphiella sp. WF42	0.75
WF45					Dendryphiella sp. crri.34	98	99	Dendryphiella sp.WF45	0.08
WF46					Dendryphiella sp. crri.34	98	99	Dendryphiella sp.WF46	0.08
WF59					Dendryphiella sp. crri.34	98	99	Dendryphiella sp. WF59	0.13
				合计Total					1.88
WF48				Bipolaris	Bipolaris oryzae isolate BO1	97	99	Bipolaris oryzae isolate WF48	0.04
WF62					Bipolaris sorokiniana strain A0606	95	97	Bipolaris sorokiniana strain WF62	0.04
				合计Total					0.08
WF49				Pithomyces	Leptosphaerulina chartarum strain DH08111quan1	98	99	Leptosphaerulina chartarum strain WF49	0.04
				合计Total					0.04
WF43			Didymellaceae	Epicoccum	Epicoccum sorghinum strain BJ-F1	97	99	Epicoccum sorghinum strain.WF43	0.08
WF47					Epicoccum sorghinum isolate M3	98	99	Epicoccum sorghinum isolate WF47	0.13
WF52					Epicoccum sorghinum isolate M3	97	99	Epicoccum sorghinum isolate WF52	0.38
WF53					Epicoccum sorghinum isolate M3	96	99	Epicoccum sorghinum isolate WF53	0.04
				合计Total					0.63
WF51			Leptosphaeriaceae	Leptosphaeria	Leptosphaeria sp. SL14	99	99	Leptosphaeria sp. WF51	0.04
WF61					Leptosphaeria sp. isolate LQ122416	98	99	Leptosphaeria sp. isolate WF61	0.04
WF64					Leptosphaeria sp. isolate LQ122417	98	99	Leptosphaeria sp. isolate WF64	0.04
				合计Total					0.13
WF20		Moniliales	Dematiaceae	Nigrospora	Nigrospora sp. JL4-CGL24	99	99	Nigrospora sp. WF20	0.04
WF57					Nigrospora sp. HCH267	98	99	Nigrospora sp. WF57	0.04
WF60					Nigrospora oryzae strain APBSMLF76	98	99	Nigrospora oryzae strain WF60	0.04
				合计Total					0.13
WF3				Cladosporium	Cladosporium oxysporum isolate DFFSCS018	100	99	Cladosporium sp. WF3	0.04
WF19					Cladosporium oxysporum strain SCAU101	99	99	Cladosporium oxysporum strain WF19	0.04
WF63					Cladosporium xanthochromaticum	98	99	Cladosporium xanthochromaticum WF63	0.08
WF65					Cladosporium tenuissimum strain APBSDSF6	99	99	Cladosporium tenuissimum strain WF65	0.04
				合计Total					0.21
WF4				Alternaria	Alternaria sp. H6_E08_1104035148Q	100	99	Alternaria sp.WF4	0.04
WF18					Alternaria alternata strain EN24	98	100	Alternaria alternata strain WF18	0.04
WF31					Alternaria longissima strain CLB44	98	99	Alternaria longissima strain WF31	0.04
				合计Total					0.13
WF9			Tuberculariaceae	Fusarium	Fusarium chlamydosporum NBAIM:236	98	100	Fusarium chlamydosporum strain WF9	0.04
WF14					Fusarium chlamydosporum isolate LrSF22	99	99	Fusarium chlamydosporum strain WF14	0.04
WF15					Fusarium sp. AL-14 IRH-2012a	98	99	Fusarium sp. WF15	0.04
WF16					Fusarium equiseti strain CP16	99	99	Fusarium equiseti strain WF16	0.04
WF38					Fusarium sp. Z13-09	96	99	Fusarium sp.WF38	0.08
WF50					Fusarium sp. AL-15 IRH-2012b	98	99	Fusarium sp.WF50	0.38
WF54					Fusarium proliferatum isolate MC-23-F	99	99	Fusarium proliferatum isolate WF54	0.04
WF56					Fusarium proliferatum isolate 10R-7	98	99	Fusarium proliferatum isolate WF56	0.04
WF66					Fusarium proliferatum isolate LrBF18	99	99	Fusarium proliferatum isolate WF66	0.04
				合计Total					0.75
WF23	Fungi Imperfecti	Hypocreales	Hypocreaceae	Letendraea helminthicola	Letendraea helminthicola strain B1A0062SNA2CC1081	88	100	Letendraea helminthicola strain WF23	0.04
				合计Total					0.04
总分离率Total IR(%)									5.04

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表5

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图4

参考文献 25

[1]	PARK S Y, KIM J K, JANG J S, LEE S Y, OH S, LEE S M, YANG C I, YEO Y . Comparative analysis of nutritional composition between the disease-resistant rice variety OsCK1 and conventional comparators. Food Science and Biotechnology, 2015,24(1):225-231.
[2]	赵艳, 李燕燕 . 利用PTN系统快速解析转基因水稻种子可溶性蛋白非预期变异的来源. 中国农业科学, 2015,48(22):4397-4407.
	ZHAO Y, LI Y Y . Rapid identify the sources of unintended variations of seed soluble proteins in genetically modified rice by using PTN system. Scientia Agricultura Sinica, 2015,48(22):4397-4407. (in Chinese)
[3]	JIAO Z, SI X X, LI G K, ZHANG Z M, XU X P . Unintended compositional changes in transgenic rice seeds (Oryza sativa L.) studied by spectral and chromatographic analysis coupled with chemometrics methods. Journal of Agricultural and Food Chemistry, 2010,58(3):1746-1754.
[4]	ALMEIDA T T, ORLANDELLI R C, AZEVEDO J L, PAMPHILE J A . Molecular characterization of the endophytic fungal community associated with Eichhornia azurea (Kunth) and Eichhornia crassipes (Mart.) (Pontederiaceae) native to the Upper Paraná River floodplain, Brazil. Genetics & Molecular Research GMR, 2015,14(2):4920-4931.
[5]	WANG X, CAI M Y, ZHOU Y . Biological influence of cry1Ab gene insertion on the endophytic bacteria community in transgenic rice. Turkish Journal of Biology, 2018,42(3):231-239.
[6]	PAN J J, BAUMGARTEN A M, MAY G . Effects of host plant environment and Ustilago maydis infection on the fungal endophyte community of maize (Zea mays). New Phytologist, 2008,178(1):147-156. doi: 10.1111/j.1469-8137.2007.02350.x
[7]	刘月廉, 郭建夫, 袁红旭, 李玥仁, 李伟, 黄永相 . 两个转抗真菌基因水稻根部内生真菌群落变化的分析. 生物过程, 2012,2:105-110.
	LIU Y L, GUO J F, YUAN H X, LI Y R, LI W, HUANG Y X . Analysis of endophytic fungal community changes in roots of two transgenic antifungal genes. Biology Process, 2012,2:105-110. (in Chinese)
[8]	CUI J L, GUO T T, REN Z X, ZHANG N S, WANG M L . Diversity and antioxidant activity of culturable endophytic fungi from alpine plants of Rhodiola crenulata, R. angusta, and R. sachalinensis. PLoS ONE, 2015,10(3):e0118204.
[9]	WEISING K, NYBOM H, PFENNINGER M, WOLFF K, MEYER W . DNA Fingerprinting in Plants and Fungi. Florida: CRC press, 1994.
[10]	柴新义, 柴钢青, 向玉勇, 张微微, 殷培峰 . 青檀叶片内生和附生真菌组成及生态分布. 生态学报, 2016,16:5163-5172. doi: 10.5846/stxb201501290233
	CHAI X Y, CHAI G Q, XIANG Y Y, ZHANG W W, YIN P F . Composition and ecological distribution of endophytic and epiphytic fungi in leaves of P. chinensis. Chinese Journal of Ecology, 2016,16:5163-5172. (in Chinese) doi: 10.5846/stxb201501290233
[11]	李盼盼, 袁晓龙, 李金海, 申国明, 高林, 李青城, 高加明, 张鹏 . 湖北烟草内生真菌生物多样性和种群结构分析. 微生物学报, 2018,58(10):169-179.
	LI P P, YUAN X L, LI J H, SHEN G M, GAO L, LI Q C, GAO J M, ZHANG P . Biodiversity and population structure analysis of endophytic fungi from tobacco in Hubei Province. Acta Microbiologica Sinica, 2018,58(10):169-179. (in Chinese)
[12]	王梦亮, 贾岩, 崔晋龙, 王俊宏 . 锁阳及其寄主白刺内生真菌的生态分布及遗传关系. 应用生态学报, 2017,28(3):815-820.
	WANG M L, JIA Y, CUI J L, WANG J H . Ecological distribution and genetic relationship of endophytic fungi from Cynomorium and its host white thorn. Chinese Journal of Applied Ecology, 2017,28(3):815-820. (in Chinese)
[13]	RAJAGOPAL K, MEENASHREE B, BINIKA D, JOSHILA D, TULSI P S, ARULMATHI R, KATHIRAVAN G, TUWAR A . Mycodiversity and biotechnological potential of endophytic fungi isolated from hydrophytes. Current Research in Environmental and Applie Myclogy, 2018,8(2):172-182.
[14]	TIAN X L, CAO L X, TAN H M, ZENG Q G, JIA Y Y, HAN W Q, ZHOU S N . Study on the communities of endophytic fungi and endophytic actinomycetes from rice and their antipathogenic activities in vitro. World Journal of Microbiology & Biotechnology, 2004,20(3):303-309. doi: 10.1023/B:WIBI.0000023843.83692.3f
[15]	王拱辰, 陈鸿逵 . 水稻恶苗病病原菌的研究. 植物病理学报, 1990,2:93-97.
	WANG G C, CHEN H K . Studies on pathogens of rice blight disease. Chinese Journal of Plant Pathology, 1990,2:93-97. (in Chinese)
[16]	史建荣, 刘馨, 仇剑波, 祭芳, 徐剑红, 董飞, 殷宪超, 冉军舰 . 小麦中镰刀菌毒素脱氧雪腐镰刀菌烯醇污染现状与防控研究进展. 中国农业科学, 2014,47(18):3641-3654. doi: 10.3864/j.issn.0578-1752.2014.18.012
	SHI J R, LIU X, QIU J B, JI F, XU J H, DONG F, YIN X C, RAN J J . Research status and prevention and control of Fusarium toxin deoxynivalenol contamination in wheat. China Agricultural Science, 2014,47(18):3641-3654. (in Chinese) doi: 10.3864/j.issn.0578-1752.2014.18.012
[17]	薛庆婉, 牛永春, 邓晖 . 常见瓜类植物的内生真菌多样性. 菌物学报, 2015,34(2):196-203. doi: DOI: 10.13346/j.mycosystema.140030
	XUE Q W, NIU Y C, DENG H . Endophytic fungal diversity of common melon plants. Journal of the Physiology, 2015,34(2):196-203. (in Chinese) doi: DOI: 10.13346/j.mycosystema.140030
[18]	贾彤, 任安芝, 魏茂英, 尹立佳, 高玉葆 . 不同传播方式的内生真菌感染对羽茅的生理生态影响. 植物生态学报, 2015,39(1):72-80. doi: 10.17521/cjpe.2015.0008
	JIA T, REN A Z, WEI M Y, YIN L J, GAO Y B . Physiological and ecological effects of endophytic fungal infections with different propagation patterns on P. chinensis. Chinese Journal of Plant Ecology, 2015,39(1):72-80. (in Chinese) doi: 10.17521/cjpe.2015.0008
[19]	DANIELSEN L, THURMER A, MEINICKE P, BUEE M, MORIN E, MARTIN F, PILATE G, DANIEL R, POLLE A, REICH M . Fungal soil communities in a young transgenic poplar plantation form a rich reservoir for fungal root communities. Ecology and Evolution, 2012,2(8):1935-1948. doi: 10.1002/ece3.305
[20]	HEUER H, KROPPENSTEDT R M, LOTTMANN J, BERG G, SMALLA K . Effects of T4 lysozyme release from transgenic potato roots on bacterial rhizosphere communities are negligible relative to natural factors. Applied and Environmental Microbiology, 2002,68(3):1325-1335. doi: 10.1128/AEM.68.3.1325-1335.2002
[21]	SILVA R D A, DOURADO M N, FÁVARO L C L, MENDES R, FERREIRA A, ARAUJO W L . Diversity of cultivated fungi associated with conventional and transgenic sugarcane and the interaction between endophytic Trichoderma virens and the host Plant. . PLoS ONE, 2016,11(7):e0158974. doi: 10.1371/journal.pone.0158974
[22]	LEE S H, KIM C G, KANG H . Temporal dynamics of bacterial and fungal communities in a genetically modified (GM) rice ecosystem. Microbial Ecology, 2011,61(3):646-659. doi: 10.1007/s00248-010-9776-5
[23]	RASCHE F, HODL V, POLL C, KANDELER E, GERZABEK M H, ELSAS J D V, SESSITSCH A . Rhizosphere bacteria affected by transgenic potatoes with antibacterial activities compared with the effects of soil, wild-type potatoes, vegetation stage and pathogen exposure. FEMS Microbiology Ecology, 2010,56(2):219-235. doi: 10.1111/fem.2006.56.issue-2
[24]	EMILIA H S, WIETSE D B, JOHANNES V V, KEVIN M C . A 3-year study reveals that plant growth stage, season and field site affect soil fungal communities while cultivar and GM-trait have minor effects. PLoS ONE, 2012,7(4):e33819. doi: 10.1371/journal.pone.0033819
[25]	LIU W, LU H H, WU W, WEI Q K, CHEN Y X, THIES J E . Transgenic Bt rice does not affect enzyme activities and microbial composition in the rhizosphere during crop development. Soil Biology & Biochemistry, 2008,40(2):475-486. doi: 10.1016/j.soilbio.2007.09.017

样本 Samples	海南省Hainan (H)					浙江省富阳市Fuyang, Zhejiang (F)
样本 Samples	菌株数 No. of strains	属数 No. of genus	丰富度指数 Margalef index (D)	多样性指数 Shannon- Wiener index(H')	均匀度指数 Evenness index (E)	菌株数 No. of strains	属数 No. of genus	丰富度指数 Margalef index (D)	多样性指数 Shannon- Wiener Index (H')	均匀度指数 Evenness index (E)
P1	0	0	—	—	—	37	9	1.92	1.32	0.60
T16	7	5	1.82	1.40	0.87	17	6	1.20	0.74	0.41
NR25	2	1	0.00	0.33		11	2	0.24	0.35	0.51
P1L	9	6	1.67	1.14	0.64	65	11	2.17	1.35	0.56
P2	6	5	1.67	1.18	0.73	10	6	1.40	0.80	0.45
T23	3	3	0.83	0.65	0.60	16	6	1.40	1.07	0.60
NR18	2	2	0.42	0.44	0.63	10	3	0.56	0.53	0.49
P2L	11	7	0.30	1.34	0.69	36	8	1.52	0.99	0.48
合计Tatol	20	9	1.67	0.63	0.29	101	12	2.29	1.63	0.66

样本 Samples	海南省Hainan (H)						浙江省富阳市Fuyang, Zhejiang (F)
样本 Samples	P1	T16	NR25	P2	T23	NR18	P1	T16	NR25		P2	T23	NR18
P1	1.00						1.00
T16	0.00	1.00					0.53	1.00
NR25	0.00	0.00	1.00				0.36	0.50	1.00
P2	0.00			1.00			0.67				1.00
T23				0.50	1.00						0.67	1.00
NR18				0.29	0.00	1.00					0.67	0.67	1.00
	HP2L						FP2L
P1L	0.62						0.74
										F
	H									0.57

样本 Samples	海南省Hainan (H)						浙江省富阳市Fuyang, Zhejiang (F)
样本 Samples	P1	T16	NR25	P2	T23	NR18	P1	T16	NR25		P2	T23	NR18
P1	1.00						1.00
T16	—	1.00					0.23	1.00
NR25	—	0.09	1.00				0.38	0.07	1.00
P2	—			1.00			0.33				1.00
T23				1.00	1.00						0.05	1.00
NR18				0.86	1.00	1.00					0.61	0.00	1.00
	HP2L						FP2L
P1L	0.86						0.18
										F
	H									0.00