不同生境沙氏鹿茸草根际土壤细菌群落结构和多样性分析

doi:10.11707/j.1001-7488.LYKX20240002

摘要/Abstract

摘要：

目的: 分析江西省内野生和人工栽培沙氏鹿茸草根际土壤细菌群落结构和多样性及其与土壤理化性质的关系，为构建沙氏鹿茸草健康的根际微环境，进一步探究沙氏鹿茸草仿野生栽培模式提供理论依据。方法: 应用高通量测序技术，比较油茶、栀子、马尾松林下野生以及人工栽培2种生境下沙氏鹿茸草根际土壤细菌群落结构和多样性，结合根际土壤理化性质进行相关性分析。结果: 2种生境下，沙氏鹿茸草根际土壤理化性质差异显著，人工仿野生栽培的根际微生物Alpha多样性最高，但在各林分类型间差异未达显著水平；各生境下优势菌门均为变形菌门、酸杆菌门、绿弯菌门、放线菌门，共有优势属包括卡氏伯克霍尔德菌属、慢生根瘤菌属、Candidatus_Solibacter、Occallatibacter、苔藓杆菌属和uncultured bacterium等有益菌；野生生境和人工栽培土壤细菌群落结构存在明显差异，人工栽培生境下变形菌门丰度最高；野生生境特有优势菌属（嗜酸栖热菌属、FCPS473、丛毛单胞菌属、酸杆菌属、未培养酸杆菌属、uncultured_forest_soil_bacterium等）的丰度在人工栽培生境下显著降低，而人工栽培生境特有优势细菌属（鞘脂单胞菌属、粒状胞菌属、嗜盐囊菌属、 Mucilaginibacter）的丰度较野生生境增加明显。冗余分析表明，根际细菌群落与土壤全氮、速效钾、碱解氮、有机质含量密切相关。结论: 在野生和人工栽培生境间，沙氏鹿茸草根际土壤理化性质、细菌群落结构具有显著差异，但野生生境沙氏鹿茸草根际细菌群落之间的相似性较高。土壤全氮、速效钾、碱解氮和有机质含量是影响细菌群落结构的主要环境因子。

关键词: 沙氏鹿茸草, 土壤细菌, 群落结构, 生境

Abstract:

Objective: In this study, the structure and diversity of rhizosphere bacterial communities in both wild and artificially cultivated Monochasma savatieri Franch ex Maxim. in Jiangxi Province were investigated to explore their relationship with soil physical and chemical properties. The aim of this study is to offer a theoretical basis for further studies on wild-simulated cultivation modes for constructing a healthy rhizosphere microenvironment for M. savatieri. Method: Rhizosphere soil bacteria originating two distinct habitats, the first being natural forests such as Camellia oleifera, Gardenia jasminoides and Pinus massoniana, and the second being artificially cultivated, were selected as research objects. The community structure characteristics of soil bacteria from different habitats were compared and analyzed by using field investigation, Illumina Miseq sequencing, and RDA analysis. Result: The results indicated that there were significant differences in the physico-chemical properties of the rhizosphere soil of M. savatieri between two distinct habitats. The Alpha diversity of artificial bionic cultivation was highest, but there was no significant difference in the alpha diversity among different forest types. In two habitats, Proteobacteria, Acidobacteriota, Chloroflexi and Actinobacteriota were the dominant bacteria phyla. At the genus level, the common dominant genera included Burkholderia-Caballeronia-Paraburkholderia, Bradyrhizobium, Candidatus_Solibacter, Occallatibacter, Bryobacter and uncultured bacterium. There were significant differences in the structure of the bacterial communities between wild and artificial bionic cultivation, with the highest abundance of Proteobacteria in artificial bionic cultivated habitats. The dominant genera unique to wild habitats, including Acidothermus, FCPS473, Conexibacter, Acidibacter, uncultured Acidobacteria_bacterium, uncultured_forest_soil bacterium, all significantly decreased in abundance in the artificial bionic cultivation habitats, while the abundance of dominant bacterial genera unique to artificially cultivated habitats (such as Sphingomonas, Granulicella, Haliangium and Mucilaginibacter), showed a significantly increased abundance in the artificial bionic cultivated habitat. Redundancy analysis (RDA) showed that total nitrogen, available potassium, alkali-hydrolyzable nitrogen, and organic matter were closely related to the composition of soil dominant bacterial communities. Conclusion: There are significant differences in the physico-chemical properties of the rhizosphere soil of M. savatieri between wild and cultivated habitats, as well as significant differences in the structure of bacterial communities. The similarity of the rhizosphere bacterial communities of M. savatieri from different wild habitat conditions is relatively high. The main environmental factors affecting bacterial community structure are soil total nitrogen, available potassium, alkaline nitrogen, and organic matter. This study provides a reference basis for the resource utilization of rhizosphere micoorganisms of M. savatieri.

Key words: Monochasma savatieri, soil bacterial, community structure, habitats

中图分类号:

S714.3

李峰卿,刘素贞,罗桂生,邹玉玲,黄维,曾满生. 不同生境沙氏鹿茸草根际土壤细菌群落结构和多样性分析[J]. 林业科学, 2025, 61(1): 47-56.

Fengqing Li,Suzhen Liu,Guisheng Luo,Yuling Zou,Wei Huang,Mansheng Zeng. Analysis of Bacterial Community Structure and Diversity in Rhizosphere Soil of Monochasma savatieri in Different Habitats[J]. Scientia Silvae Sinicae, 2025, 61(1): 47-56.

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参考文献 0

	陈　冉, 刘志强, 王丹丹. 基于高通量测序比较不同产地药用银杏根际土壤微生物多样性. 药用生物技术, 2021, 28 (2): 117- 122.
	Chen R, Liu Z Q, Wang D D. Microbial diversity of rhizosphere soil of Ginkgo biloba from different habitats was compared based on high-throughput sequencing. Pharmaceutical Biotechnology, 2021, 28 (2): 117- 122.
	丁新景, 敬如岩, 黄雅丽, 等. 黄河三角洲刺槐根际与非根际细菌结构及多样性. 土壤学报, 2017, 54 (5): 1293- 1298.
	Ding X J, Jing R Y, Huang Y L, et al. Bacterial structure and diversity of rhizosphere and bulk soil of Robinia pseudoacia forests in Yellow River Delta. Acta Pedologica Sinica, 2017, 54 (5): 1293- 1298.
	丁新景, 敬如岩, 黄雅丽, 等. 基于高通量测序的 4 种不同树种人工林根际土壤细菌结构及多样性. 林业科学, 2018, 54 (1): 81- 89.
	Ding X J, Jing R Y, Huang Y L, et al. Bacterial structure and diversity of rhizosphere soil of four tree species in Yellow River Delta based on high-throughput sequencing. Scientia Silvae Sinicae, 2018, 54 (1): 81- 89.
	郭兰萍, 周良云, 康传志, 等. 药用植物适应环境胁迫的策略及道地药材“拟境栽培”. 中国中药杂志, 2020, 45 (9): 1969- 1974.
	Guo L P, Zhou L Y, Kang C Z, et al. Strategies for medicinal plants adapting environmental stress and “simulative habitat cultivation” of Dao-di herbs. China Journal of Chinese Materia Medica, 2020, 45 (9): 1969- 1974.
	郭子武, 杨丽婷, 林　华, 等. 坡位对毛竹林下黄花远志生物量积累与分配及其异速生长关系的影响. 南京林业大学学报(自然科学版), 2020, 44 (6): 79- 84.
	Guo Z W, Yang L T, Lin H, et al. Effects of slope positions on growth and biomass accumulation, allocation and allometry of Polygala fallax in Phyllostachys edulis forest. Journal of Nanjing Forestry University (Natural Sciences Edition), 2020, 44 (6): 79- 84.
	胡蒙爱, 马嘉伟, 张雪艳. 生物炭引入蚯蚓粪和草炭对基质环境, 黄瓜植株生长和果实品质特性的影响. 江西农业大学学报, 2022, 44 (4): 852- 861.
	Hu M A, Ma J W, Zhang X Y. Effects of introducing biochar into vermicompost and peat on substrate environment, cucumber growth and quality characteristics. Acta Agriculturae Universitatis Jiangxiensis, 2022, 44 (4): 852- 861.
	李　毳, 刘　怡, 刘晋仙. 药用植物根际细菌群落多样性驱动因素分析. 生态环境学报, 2020, 29 (10): 1988- 1993.
	Li C, Liu Y, Liu J X. Analysis of driving factors of rhizosphere bacterial community diversity in three genuine medicine plants. Ecology and Environmental Sciences, 2020, 29 (10): 1988- 1993.
	李　岩, 何学敏, 杨晓东, 等. 不同生境黑果枸杞根际与非根际土壤微生物群落多样性. 生态学报, 2018, 38 (17): 5983- 5995.
	Li Y, He X M, Yang X D, et al. The microbial community diversity of the rhizosphere and bulk soils of Lycium ruthenicum in different habitats. Acta Ecologica Sinica, 2018, 38 (17): 5983- 5995.
	蔺玉红, 马嘉伟, 张雪艳. 蚯蚓粪, 草炭与生物炭混合对基质理化性质和细菌群落组成、代谢的影响. 中国农业大学学报, 2022, 27 (7): 84- 94.
	Lin Y H, Ma J W, Zhang X Y. Effects of peat or vermicompost mixed with biochar on the physical and chemical properties of the substrate and composition and metabolism of bacterial communities. Journal of China Agricultural University, 2022, 27 (7): 84- 94.
	罗夫来, 郭巧生, 王长林, 等. 寄主对半寄生植物百蕊草影响的综合评价研究. 中国中药杂志, 2012, 37 (9): 1174- 1179.
	Luo F L, Guo Q S, Wang C L, et al. Complex evaluation for influence of hosts on hemipatasite Thesium chinense. China Journal of Chinese Materia Medica, 2012, 37 (9): 1174- 1179.
	裴怀弟, 宿兵兵, 李　琦, 等. 人参果生育期根际土壤细菌结构对施氮量的响应. 植物营养与肥料学报, 2023, 29 (6): 1125- 1134.
	Pei H D, Su B B, Li Q, et al. Response of rhizosphere bacterial community structure to nitrogen application rate during ginseng fruit (Solanum muricatum Aiton) growth stages. Journal of Plant Nutrition and Fertilizers, 2023, 29 (6): 1125- 1134.
	孙　倩, 吴宏亮, 陈　阜, 等. 基于高通量测序的几种不同作物根际土壤细菌群落结构和多样性分析. 农业生物技术学报, 2020, 28 (8): 1490- 1498.
	Sun Q, Wu H L, Chen F, et al. Analysis of bacterial community structure and diversity in rhizosphere soil of several different crops based on high-throughput sequencing. Journal of Agricultural Biotechnology, 2020, 28 (8): 1490- 1498.
	施咏滔, 朱再标, 郭巧生, 等. 人为干扰对野生沙氏鹿茸草群落结构的影响. 中药材, 2022, 45 (03): 561- 567.
	Shi Y T, Zhu Z B, Guo Q S, et al. effects of human disturbance on the population structure of wild Monochasma savatieri. Journal of Chinese Medicinal Materials, 2022, 45 (03): 561- 567.
	王豪吉, 官会林, 王　勇, 等. 2023. 自然林下与田间根腐三七根际微生物群落特征及比较分析. 微生物学通报, 50(5): 1988−2001.
	Wang H J, Guan H L, Wang Y et al, 2023. Comparison of rhizosphere microbial community of Panax notoginseng with root rot under natural forest and in the field. Microbiology China. 50(5): 1988−2001. ［in Chinese］
	王　雪, 接伟光, 蔡柏岩. 不同生境黄檗 AM 真菌菌群结构分析. 林业科学, 2012, 48 (9): 99- 107. doi: 10.11707/j.1001-7488.20120916
	Wang X, Jie W G, Cai B Y. Community composition of the AM fungi of Phellodendron amurense in different habitats. Scientia Silvae Sinicae, 2012, 48 (9): 99- 107. doi: 10.11707/j.1001-7488.20120916
	王　艳, 郭良栋, 程虎印, 等. 不同生境重楼内生真菌及土壤真菌多样性比较. 微生物学通报, 2020, 47 (9): 2867- 2876.
	Wang Y, Guo L D, Cheng H Y, et al. Comparison of endophytic and soil fungi of Paris Polyphylla diversity from different habitat. Microbiology China, 2020, 47 (9): 2867- 2876.
	王　钰, 谭均, 伍晓丽, 等. 自然林和人工搭棚种植模式下黄连根际土壤真菌群落结构变化. 中国中药杂志, 2020, 45 (21): 5160- 5168.
	Wang Y, Tan J, Wu X L, et al. Variation in fungal community structures in rhizosphere soil of Coptis chinensis with cropping mode under natural forest and artificial shed. China Journal of Chinese Materia Medica, 2020, 45 (21): 5160- 5168.
	辛晓静, 刘　磊, 申俊芳, 等. 羊草基因型数目与氮添加对土壤微生物群落的交互影响. 生态学报, 2016, 36 (13): 3923- 3932.
	Xin X J, Liu L, Shen J F, et al. Interactions between genotypic number and nitrogen addition on soil microbial communities in the population of Leymus chinensis. Acta Ecologica Sinica, 2016, 36 (13): 3923- 3932.
	薛银刚, 刘　菲, 周璐璐, 等. 基于高通量测序的工业园区地下水和土壤细菌群落结构比较研究. 生态毒理学报, 2017, 12 (6): 107- 115.
	Xue Y G, Liu F, Zhou L L, et al. Comparison study of bacterial community structure between groundwater and soil in industrial park based on high throughput sequencing. Asian Journal of Ecotoxicology, 2017, 12 (6): 107- 115.
	杨尚东, 郭　霜, 任奎喻, 等. 甘蔗宿根矮化病感病与非感病株根际土壤生物学性状及细菌群落结构特征. 植物营养与肥料学报, 2019, 25 (6): 910- 916.
	Yang S D, Guo S, Ren K Y, et al. Soil biological properties and bacterial community structures in rhizosphere soil of canes infected and non-infected by ratoon stunting disease. Journal of Plant Nutrition and Fertilizers, 2019, 25 (6): 910- 916.
	杨泽良, 任建行, 况园园, 等. 桂西北喀斯特不同植被演替阶段土壤微生物群落多样性. 水土保持研究, 2019, 26 (3): 185- 191.
	Yang Z L, Ren J H, Kuang Y Y, et al. Dynamics of soil microbial communities along vegetation restoration gradient in Karst area. Research of Soil and Water Conservation, 2019, 26 (3): 185- 191.
	张　香, 高佳琪, 袁　媛, 等. 基于Hiseq测序分析沉香不同层的细菌分布特征. 中国中药杂志, 2020, 45 (10): 2374- 2381.
	Zhang X, Gao J Q, Yuan Y, et al. Analysis of bacteria distribution characteristics in different layers of agarwood based on Hiseq sequencing. China Journal of Chinese Materia Medica, 2020, 45 (10): 2374- 2381.
	赵芸晨, 刘　畅, 闫　刚, 等. 连续施用猪粪对辣椒根际有益细菌与产量的影响. 蔬菜, 2023, (9): 34- 40.
	Zhao Y C, Liu C, Yan G, et al. Effects of continuous application of pig manure on rhizosphere beneficial bacteria and yield of pepper. Vegetables, 2023, (9): 34- 40.
	周倩怡, 李　屹, 韩　睿, 等. 根际促生菌缓解园艺作物连作障碍的研究进展. 生态学杂志, 2022, 41 (9): 1845- 1852.
	Zhou Q Y, Li Y, Han R, et al. Research progress of using plant growth promoting rhizobacteria to alleviate continuous cropping obstacles of horticultural crops. Chinese Journal of Ecology, 2022, 41 (9): 1845- 1852.
	Begum N, Qin C, Ahanger M A, et al. Role of arbuscular mycorrhizal fungi in plant growth regulation: implications in abiotic stress tolerance. Frontiers in Plant Science, 2019, 10, 1068. doi: 10.3389/fpls.2019.01068
	de Vries F T, Griffiths R I, Knight C G, et al. Harnessing rhizosphere microbiomes for drought-resilient crop production. Science, 2020, 368 (6488): 270- 274. doi: 10.1126/science.aaz5192
	Hooper D U, Bignell D E, Brown V K, et al. Interactions between aboveground and belowground biodiversity in terrestrial ecosystems: patterns, mechanisms, and feedbacks. BioScience, 2000, 50 (12): 1049. doi: 10.1641/0006-3568(2000)050[1049:IBAABB]2.0.CO;2
	Huang W J, Long C L, Lam E. Roles of plant-associated microbiota in traditional herbal medicine. Trends in Plant Science, 2018, 23 (7): 559- 562. doi: 10.1016/j.tplants.2018.05.003
	Jiang Y N, Wang W X, Xie Q J, et al. Plants transfer lipids to sustain colonization by mutualistic mycorrhizal and parasitic fungi. Science, 2017, 356 (6343): 1172- 1175. doi: 10.1126/science.aam9970
	Kurth F, Zeitler K, Feldhahn L, et al. Detection and quantification of a mycorrhization helper bacterium and a mycorrhizal fungus in plant-soil microcosms at different levels of complexity. BMC Microbiology, 2013, 13 (1): 205. doi: 10.1186/1471-2180-13-205
	Li Y C, Li Z, Li Z W, et al. Variations of rhizosphere bacterial communities in tea (Camellia sinensis L. ) continuous cropping soil by high‐throughput pyrosequencing approach. Journal of Applied Microbiology, 2016, 121 (3): 787- 799. doi: 10.1111/jam.13225
	Liu Y L, He W J, Mo L, et al. Antimicrobial, anti-inflammatory activities and toxicology of phenylethanoid glycosides from Monochasma savatieri Franch. ex Maxim. Journal of Ethnopharmacology, 2013, 149 (2): 431- 437. doi: 10.1016/j.jep.2013.06.042
	Luan F G, Zhang L L, Lou Y Y, et al. Analysis of microbial diversity and niche in rhizosphere soil of healthy and diseased cotton at the flowering stage in southern Xinjiang. Genetics and Molecular Research, 2015, 14 (1): 1602- 1611. doi: 10.4238/2015.March.6.7
	Mateos-Rivera A, Yde J C, Wilson B, et al. The effect of temperature change on the microbial diversity and community structure along the chronosequence of the sub-arctic glacier forefield of Styggedalsbreen (Norway). FEMS Microbiology Ecology, 2016, 92 (4): 1- 13.
	Nacke H, Thürmer A, Wollherr A, et al. Pyrosequencing-based assessment of bacterial community structure along different management types in German forest and grassland soils. PLoS One, 2011, 6 (2): e17000. doi: 10.1371/journal.pone.0017000
	Nemat H, Ali Shah A, Akram W, et al. Ameliorative effect of co-application of Bradyrhizobium japonicum EI09 and Se to mitigate chromium stress in Capsicum annum L. International Journal of Phytoremediation, 2020, 22 (13): 1396- 1407. doi: 10.1080/15226514.2020.1780412
	Pendergast T H IV, Burke D J, Carson W P. Belowground biotic complexity drives aboveground dynamics: a test of the soil community feedback model. New Phytologist, 2013, 197 (4): 1300- 1310. doi: 10.1111/nph.12105
	Rodríguez-Blanco A, Sicardi M, Frioni L. Plant genotype and nitrogen fertilization effects on abundance and diversity of diazotrophic bacteria associated with maize (Zea mays L. ). Biology and Fertility of Soils, 2015, 51 (3): 391- 402. doi: 10.1007/s00374-014-0986-8
	Shi S J, Nuccio E, Herman D J, et al. Successional trajectories of rhizosphere bacterial communities over consecutive seasons. MBio, 2015, 6 (4): 1- 8..
	Stewart A J, Chapman W, Jenkins G I, et al. 2001. The effect of nitrogen and phosphorus deficiency on flavonol accumulation in plant tissues. Plant, Cell & Environment, 24(11): 1189−1197.
	Su J M, Wang Y Y, Bai M, et al. Soil conditions and the plant microbiome boost the accumulation of monoterpenes in the fruit of Citrus reticulata ‘Chachi’. Microbiome, 2023, 11 (1): 61. doi: 10.1186/s40168-023-01504-2
	Uroz S, Ioannidis P, Lengelle J, et al. Functional assays and metagenomic analyses reveals differences between the microbial communities inhabiting the soil horizons of a Norway spruce plantation. PLoS One, 2013, 8 (2): e55929. doi: 10.1371/journal.pone.0055929
	Yang Y, He J, Liu Y X, et al. Assessment of Chinese suitable habitats of Zanthoxylum nitidum in different climatic conditions by Maxent model, HPLC, and chemometric methods. Industrial Crops and Products, 2023, 196, 116515. doi: 10.1016/j.indcrop.2023.116515
	Yuan Y L, Si G C, Wang J, et al. Bacterial community in alpine grasslands along an altitudinal gradient on the Tibetan Plateau. FEMS Microbiology Ecology, 2014, 87 (1): 121- 132. doi: 10.1111/1574-6941.12197
	Zhang M H, Chen Y L, Ouyang Y, et al. The biology and haustorial anatomy of semi-parasitic Monochasma savatieri Franch. ex Maxim. Plant Growth Regulation, 2015, 75 (2): 473- 481. doi: 10.1007/s10725-014-0010-1
	Zhang Y Y, Chen Y L, Zhang X H, et al. Adventitious shoot induction from internode and root explants in a semiparasitic herb Monochasma savatieri franch ex maxim. Journal of Plant Growth Regulation, 2017, 36 (3): 799- 804. doi: 10.1007/s00344-017-9681-y
	Zhou Y, Yang Z, Liu J, et al. Crop rotation and native microbiome inoculation restore soil capacity to suppress a root disease. Nature Communications, 2023, 14 (1): 8126. doi: 10.1038/s41467-023-43926-4

生境 Habitat	林分类型 Stand type	采集地 Site	样本名称Name	样本 Sample	经纬度 Longitude and latitude	经营类型 Management type
野生 Wild	油茶 C. oleifera	江西信丰 Xinfeng，Jiangxi	XF	根际土 Rhizosphere soil	114.96°E, 25.09°N	粗放经营，即连续5年未进行经营管理 Extensive management, that is, no operation for 5 consecutive years
	马尾松 P. massoniana	江西安福 Anfu，Jiangxi	AF	根际土 Rhizosphere soil	114.18°E, 27.82°N	轻度经营，即每年施肥、抚育各1次Light management, that is, fertilization and tending once a year
	栀子 G. jasminoides	江西分宜 Fenyi，Jiangxi	FY	根际土 Rhizosphere soil	114.76°E, 27.86°N	强度经营，即每年修枝、施肥2~3次Intensity management, that is, pruning and fertilizing 2–3 times a year
人工仿野生栽培 Artificial bionic cultivation	针阔混交 Coniferous-broad leaved mixed stand	江西宜春 Yichun，Jiangxi	YC	根际土 Rhizosphere soil	114.44°E, 27.84°N	重度经营，全垦，全年除草、施肥4~5次Heavy management, full reclamation, weeding and fertilization 4–5 times a year

生境 Habitat	林分类型 Stand type	pH	全量养分含量 Content of total nutrient/(g·kg^?1)				速效养分含量 Content of available nutrient/(mg·kg^?1)
生境 Habitat	林分类型 Stand type	pH	有机质 Organic matter	全氮 Total nitrogen	全磷 Total phosphorus	全钾 Total potassium	碱解氮 Alkali-hydrolyzable nitrogen	速效磷 Available phosphorus	速效钾 Available potassium
野生 Wild	油茶 C. oleifera	5.24±0.15a	28.41±1.39b	1.04±0.08c	0.38±0.04a	21.02±1.10a	151.13±4.56a	2.58±0.27a	62.66±3.37a
	马尾松 P. massoniana	4.68±0.08b	41.36±7.43a	1.64±0.13ab	0.27±0.01b	12.46±0.49d	106.18±20.37b	0.46±0.10c	73.36±5.35a
	栀子 G. jasminoides	4.51±0.36b	47.64±6.72a	1.53±0.19b	0.32±0.07b	13.73±1.04c	126.71±24.18ab	1.79±0.73b	54.88±8.93a
人工仿生栽培 Artificial bionic cultivation	针阔混交 Coniferous-broad leaved mixed stand	4.48±0.06b	39.82±7.09a	2.10±0.17a	0.25±0.02b	17.32±0.70b	103.33±11.44b	0.74±0.06c	67.83±8.97a

生境 Habitat	林分类型 Stand type	丰富度指数 Richness index (Chao 1)	香农-维纳指数 Shannon-Wiener’s index	物种数 Observed species
野生 Wild	马尾松P. massoniana	2393.8±109.89a	8.53±0.27a	1980.20±97.40a
	栀子G. jasminoides	2670.9±302.51a	8.81±0.25a	2096.43±211.28a
	油茶C. oleifera	2034.8±483.83a	8.22±0.51a	1600.25±364.72a
人工仿生栽培 Artificial bionic cultivation	针阔混交 Coniferous-broad leaved mixed stand	2678.4±424.91a	8.86±0.84a	2153.70±441.60a

R	P	置换次数 Number of permutations	群组 Group
1.0000	0.028	999	YC-AF
0.9896	0.026	999	YC-FY
1.0000	0.022	999	YC-XF
0.5729	0.025	999	AF-FY
0.6667	0.024	999	AF-XF
0.5625	0.053	999	FY-XF
0.7309	0.001	999	全部All

属 Genus	相对丰度 Relative abundance（%）
属 Genus	AF	FY	XF	YC
伯克霍尔德氏菌-卡巴拉氏菌- 拟伯克霍尔德氏菌属 Burkholderia-Caballeronia-Paraburkholderia	1.73	2.22	1.07	7.43
慢生根瘤菌属 Bradyrhizobium	2.32	3.49	1.78	2.91
红游动菌属 Rhodoplanes	1.72	1.69	1.08	1.01
鞘脂单胞菌属Sphingomonas	0.62	0.67	0.32	1.69
念珠菌固体杆菌属Candidatus_Solibacter	2.70	2.50	1.57	2.88
uncultured bacterium	6.20	5.60	4.08	2.08
苔藓杆菌属 Bryobacter	1.69	2.06	2.09	1.25
Occallatibacter	1.01	1.12	2.23	1.93
酸杆菌属 Acidibacter	1.23	2.20	1.47	0.62
粒状胞菌属 Granulicella	0.62	0.61	0.46	1.65
Mucilaginibacter	0.12	0.12	0.09	1.39
嗜酸栖热菌属 Acidothermus	7.84	9.50	10.18	0.24
丛毛单胞菌属 Conexibacter	1.82	1.98	2.55	0.37
FCPS473	5.23	1.23	8.05	0.04
Feb-21	3.36	0.23	2.54	0.01
uncultured_forest_soil_bacterium	1.85	1.85	2.97	0.65
未培养酸杆菌门菌属 uncultured_Acidobacteria_bacterium	1.81	1.20	1.02	0.72
HSB OF53-F07	1.09	0.45	4.81	0.05
嗜盐囊菌属 Haliangium	0.41	0.53	0.18	1.36