应用Illumina MiSeq高通量测序技术分析河西走廊地区盐碱土壤微生物多样性

【目的】以甘肃省河西走廊地区的9个盐碱土壤样品(原生盐碱土、次生盐碱土、农田土)为材料,研究该地区盐碱土壤中微生物群落的多样性。【方法】提取土壤微生物总DNA,应用Illumina Mi Seq高通量测序技术进行分析。【结果】从分布在河西走廊3个流域的9个盐碱土样品中共获得325 089条微生物的16S r RNA基因序列。冗余分析和热图分析表明,原生盐碱土与次生盐碱土、原生盐碱土与农田土微生物群落构成差异较大,次生盐碱土与农田土微生物群落差异较小。土壤p H对微生物群落组成的影响最显著。多样性指数和稀释性曲线分析得出,在9个土壤样品中,S6号Shannon指数最大,S1号Shannon指数最小,S1号Simpson指数最大,S6号Simpson指数最小,说明原生盐碱土的微生物群落多样性最低,次生盐碱土的微生物群落多样性最高。盐碱土壤中主要的微生物群落包括9个门,其中变形菌门占主导地位,其余依次是放线菌门、拟杆菌门、酸杆菌门、浮霉菌门、绿弯菌门、芽单胞菌门、厚壁菌门和疣微菌门。原生盐碱土和农田土中占优势的微生物群落是变形菌门,次生盐碱土中占优势的微生物群落是放线菌门。【结论】河西走廊地区盐碱土壤中微生物多样性非常丰富,存在大量的微生物类群,尤其是在次生盐碱土壤中。     

氮掺杂碳纳米颗粒对稻田根际土壤细菌群落的影响

氮掺杂碳纳米颗粒(N-CNPs)具有较高的农田氮肥增效潜力,但其对稻田根际土壤细菌群落结构和功能的影响尚不明确。本研究以连续3年施用低(1.2%,N-CNPs1)、中(6.7%,N-CNPs2)和高(9.3%,N-CNPs3)氮掺杂碳纳米颗粒的稻田根际土壤为研究对象,采用高通量测序技术和PICRUSt 功能预测方法研究其细菌群落组成和代谢功能变化。结果表明: 连续3年配施N-CNPs能提升稻田根际土壤细菌群落多样性,改变细菌群落功能;不同氮掺杂量水平间存在差异,其中以中氮掺杂量(N-CNPs2)碳纳米颗粒处理变化幅度最大。细菌群落分析结果指出,配施N-CNPs提升了根际土壤中变形菌门、酸杆菌门和疣微菌门的相对丰度,降低了浮霉菌门、绿弯菌门、硝化螺旋菌门和芽单胞菌门的相对丰度。PICRUSt 功能预测结果表明,在二级预测功能分类中,配施N-CNPs处理的氨基酸代谢、碳水化合物代谢和脂类代谢功能得到增强,而其他代谢功能则受到减弱。KEGG 直系同源基因簇丰度热图结果显示,N-CNPs2处理能提升根际土壤碳、氮代谢相关的细菌群落的相对丰度。     

Plant community and soil conditions individually affect soil microbial community assembly in experimental mesocosms

Soils harbor large, diverse microbial communities critical for local and global ecosystem functioning that are controlled by multiple and poorly understood processes. In particular, while there is observational evidence of relationships between both biotic and abiotic conditions and microbial composition and diversity, there have been few experimental tests to determine the relative importance of these two sets of factors at local scales. Here, we report the results of a fully factorial experiment manipulating soil conditions and plant cover on old‐field mesocosms across a latitudinal gradient. The largest contributor to beta diversity was site‐to‐site variation, but, having corrected for that, we observed significant effects of both plant and soil treatments on microbial composition. Separate phyla were associated with each treatment type, and no interactions between soil and plant treatment were observed. Individual soil characteristics and biotic parameters were also associated with overall beta‐diversity patterns and phyla abundance. In contrast, soil microbial diversity was only associated with site and not experimental treatment. Overall, plant community treatment explained more variation than soil treatment, a result not previously appreciated because it is difficult to dissociate plant community composition and soil conditions in observational studies across gradients. This work highlights the need for more nuanced, multifactorial experiments in microbial ecology and in particular indicates a greater focus on relationships between plant composition and microbial composition during community assembly.     

Diversity and distribution of soil fungal communities in a semiarid grassland

The fungal loop model of semiarid ecosystems integrates microtopographic structures and pulse dynamics with key microbial processes. However limited data exist about the composition and structure of fungal communities in these ecosystems. The goal of this study was to characterize diversity and structure of soil fungal communities in a semiarid grassland. The effect of long-term nitrogen fertilization on fungi also was evaluated. Samples of rhizosphere (soil surrounding plant roots) and biological soil crust (BSC) were collected in central New Mexico, USA. DNA was amplified from the samples with fungal specific primers. Twelve clone libraries were generated with a total of 307 (78 operational taxonomic units, OTUs) and 324 sequences (67 OTUs) for BSC and rhizosphere respectively. Approximately 40% of soil OTUs were considered novel (less than 97% identity when compared to other sequences in NCBI using BLAST). The dominant organisms were dark-septate (melanized fungi) ascomycetes belonging to Pleosporales. Effects of N enrichment on fungi were not evident at the community level; however the abundance of unique sequences, sampling intensity and temporal variations may be uncovering the effect of N in composition and diversity of fungal communities. The fungal communities of rhizosphere soil and BSC overlapped substantially in composition, with a Jaccard abundance similarity index of 0.75. Further analyses are required to explore possible functions of the dominant species colonizing zones of semiarid grassland soils.     

Cultivation-independent analysis of Pseudomonas species in soil and in the rhizosphere of field-grown Verticillium dahliae host plants

Despite their importance for rhizosphere functioning, rhizobacterial Pseudomonas spp. have been mainly studied in a cultivation-based manner. In this study a cultivation-independent method was used to determine to what extent the factors plant species, sampling site and year-to-year variation influence Pseudomonas community structure in bulk soil and in the rhizosphere of two Verticillium dahliae host plants, oilseed rape and strawberry. Community DNA was extracted from bulk and rhizosphere soil samples of flowering plants collected at three different sites in Germany in two consecutive years. Pseudomonas community structure and diversity were assessed using a polymerase chain reaction denaturing gradient gel electrophoresis (PCR-DGGE) system to fingerprint Pseudomonas-specific 16S rRNA gene fragments amplified from community DNA. Dominant and differentiating DGGE bands were excised from the gels, cloned and sequenced. The factors sampling site, plant species and year-to-year variation were shown to significantly influence the community structure of Pseudomonas in rhizosphere soils. The composition of Pseudomonas 16S rRNA gene fragments in the rhizosphere differed from that in the adjacent bulk soil and the rhizosphere effect tended to be plant-specific. The clone sequences of most dominant bands analysed belonged to the Pseudomonas fluorescens lineage and showed closest similarity to culturable Pseudomonas known for displaying antifungal properties. This report provides a better understanding of how different factors drive Pseudomonas community structure and diversity in bulk and rhizosphere soils.     

EM堆肥对黑土耕作区中小型土壤动物群落的影响

2012年5、7和9月在哈尔滨市典型黑土农田区,采用定点试验的方法设置空白对照、低浓度、中浓度和高浓度4个处理样地,分析不同浓度EM堆肥处理对中小型土壤动物群落组成、垂直结构、季节性动态和多样性的影响.结果表明: 不同浓度EM堆肥处理下共捕获中小型土壤动物7860只,平均密度49125只·m^-2,隶属于3纲10目,划分为30个类群.EM堆肥处理增加了中小型土壤动物类群数量,低浓度处理中小型土壤动物个体密度低于空白对照样地,但随着EM堆肥浓度的增加,中小型土壤动物个体密度均有所增加;中小型土壤动物群落的类群数和个体密度的垂直分布具有表聚性特征;中小型土壤动物群落存在一定的季节变化特征;不同浓度EM堆肥处理样地中小型土壤动物群落多样性指数均有所增加,土壤有机质对这种多样性的变化影响相对较大;EM堆肥处理下中小型土壤动物对土壤环境因子的响应不同,常见类群和优势类群对土壤环境的变化有较强的适应性,而稀有类群相对敏感,受到特定的环境因子的影响.说明EM堆肥处理可在一定程度上改善黑土区农田中小型土壤动物群落结构、增加其多样性.     

Microsporidian Diversity in Soil,Sand, and Compost of the Pacific Northwest

Microsporidia are intracellular parasites considered to be ubiquitous in the environment. Yet the true extent of their diversity in soils, sand, and compost remains unclear. We examined microsporidian diversity found in the common urban environments of soil, sand, and compost. We retrieved 22 novel microsporidian sequences and only four from described species. Their distribution was generally restricted to a single site and sample type. Surprisingly, one novel microsporidian showed a wide distribution, and high prevalence, as it was detected in five different compost samples and in soil samples collected over 200 km apart. These results suggest that the majority of Microsporidia appear to have a narrow distribution. Our phylogenetic analysis indicated that the Microsporidia detected in this study include representatives from four of the five major microsporidian groups. Furthermore, the addition of our new sequences calls into question the cohesiveness of microsporidian clade II. These results highlight the importance of increasing our knowledge of microsporidian diversity to better understand the phylogenetic relationships and evolutionary history of this important group of emerging parasites.     

Soil Water Content and Organic Carbon Availability Are Major Determinants of Soil Microbial Community Composition

Exploration of environmental factors governing soil microbial community composition is long overdue and now possible with improved methods for characterizing microbial communities. Previously, we observed that rice soil microbial communities were distinctly different from tomato soil microbial communities, despite management and seasonal variations within soil type. Potential contributing factors included types and amounts of organic inputs, organic carbon content, and timing and amounts of water inputs. Of these, both soil water content and organic carbon availability were highly correlated with observed differences in composition. We examined how organic carbon amendment (compost, vetch, or no amendment) and water additions (from air dry to flooded) affect microbial community composition. Using canonical correspondence analysis of phospholipid fatty acid data, we determined flooded, carbon-amended (+C) microcosm samples were distinctly different from other +C samples and unamended (–C) samples. Although flooding without organic carbon addition influenced composition some, organic carbon addition was necessary to substantially alter community composition. Organic carbon availability had the same general effects on microbial communities regardless of whether it was compost or vetch in origin. In addition, flooded samples, regardless of organic carbon inputs, had significantly lower ratios of fungal to bacterial biomarkers, whereas under drier conditions and increased organic carbon availability the microbial communities had higher proportions of fungal biomass. When comparing field and microcosm soil, flooded +C microcosm samples were most similar to field-collected rice soil, whereas all other treatments were more similar to field-collected tomato soil. Overall, manipulating water and carbon content selected for microbial communities similar to those observed when the same factors were manipulated at the field scale.     

The Influence of Tropical Plant Diversity and Composition on Soil Microbial Communities

There is growing interest in understanding the linkages between above- and belowground communities, and very little is known about these linkages in tropical systems. Using an experimental site at La Selva Biological Station, Costa Rica, we examined whether plant diversity, plant community composition, and season influenced microbial communities. We also determined whether soil characteristics were related to differences in microbial communities. Phospholipid fatty acid (PLFA) composition revealed that microbial community composition differed across a plant diversity gradient (plots contained 1, 3, 5, or over 25 species). Plant species identity also was a factor influencing microbial community composition; PLFA composition significantly varied among monocultures, and among three-species combinations that differed in plant species composition. Differences among treatments within each of these comparisons were apparent in all four sampling dates of the study. There was no consistent shift in microbial community composition between wet and dry seasons, although we did see significant changes over time. Of all measured soil characteristics, soil C/N was most often associated with changes in microbial community composition across treatment groups. Our findings provide evidence for human alteration of soil microbial communities via the alteration of plant community composition and diversity and that such changes are mediated in part by changes in soil carbon quality.     

浑善达克沙地夏冬季浅色型生物土壤结皮中古菌的系统发育多样性

【目的】生物土壤结皮(Biological soil crusts,BSCs)对于遏制土壤荒漠化、恢复荒漠地区生态环境起着重要作用。BSCs形成和发展的关键角色是微生物。但关于BSCs中微生物组成的认识还不够全面和系统,特别是对其中的古菌鲜有研究报道。【方法】通过构建和分析古菌16S rRNA基因克隆文库,揭示浑善达克沙地BSCs中古菌多样性和系统发育类型组成,并比较它们夏季和冬季的变化。【结果】BSCs样品颜色为褐色,厚度较薄,所含氮和磷营养养分不高;8月份和11月份的BSCs古菌16S rRNA基因文库覆盖度均达95%以上,代表性强;两个文库共得到可用的142条古菌16S rRNA基因序列,以0.03为Cutoff值、这些序列分入10个OTUs中,两个季节的最优势种群相同;8月份和11月份的古菌均属于奇古菌门,但群落结构存在很大的不同,即各自所独有的种群分别有1个和4个;BSCs中古菌多样性均不高,但11月份的明显高于8月份的。【结论】温带沙地浅色型BSCs中古菌的主要为奇古菌、多样性低,其群落结构随季节变换而有较大变化。本研究为系统认识BSCs古菌的多样性及其生态作用提供了基础。     

林下植被管理措施对杉木大径材林土壤细菌群落结构的影响

林下植被是人工林生态系统的重要组成部分。本研究采用高通量测序技术,分析林下植被保留、林下植被去除和林下套种3种林下植被管理措施对杉木大径材人工林土壤细菌多样性、细菌群落结构组成以及相对丰度的影响,并分析土壤理化性质与细菌群落多样性的关系。结果表明: 林下植被保留处理的土壤细菌群落Chao1指数、Ace指数和Shannon指数高于林下植被去除和林下套种;放线菌门、酸杆菌门和绿弯菌门为本研究区杉木人工林土壤主要优势细菌;与林下植被去除和林下套种处理杉木人工林土壤细菌群落相比,林下植被保留处理土壤变形菌门、浮霉菌门、厚壁菌门和疣微菌门等相对丰度较高,而放线菌门、酸杆菌门和绿弯菌门的相对丰度较低;3种林下植被管理措施之间,土壤厚壁菌门、浮霉菌门、疣微菌门、Parcubacteria门和放线菌门等类群相对丰度差异显著;土壤含水率、全氮、全磷、水解氮和速效磷含量是影响细菌群落结构的重要因子,细菌多样性指数与土壤全氮、全磷、全钾、水解氮和速效钾含量呈显著正相关。     

Spatiotemporal changes in the structure and composition of a less-abundant bacterial phylum (Planctomycetes) in two perialpine lakes

We used fingerprinting and cloning-sequencing to study the spatiotemporal dynamics and diversity of Planctomycetes in two perialpine lakes with contrasting environmental conditions. Planctomycetes, which are less-abundant bacteria in freshwater ecosystems, appeared to be structured in the same way as the entire bacterial community in these ecosystems. They were more diversified and displayed fewer temporal variations in the hypolimnia than in the epilimnia. Like the more-abundant bacterial groups in aquatic systems, Planctomycetes communities seem to be composed of a very small number of abundant and widespread operational taxonomic units (OTUs) and a large number of OTUs that are present at low abundance. This indicates that the concept of "abundant or core" and "rare" bacterial phylotypes could also be applied to less-abundant freshwater bacterial phyla. The richness and diversity of Planctomycetes were mainly driven by pH and were similar in both of the lakes studied, whereas the composition of the Planctomycetes community seemed to be determined by a combination of factors including temperature, pH, and nutrients. The relative abundances of the dominant OTUs varied over time and were differently associated with abiotic factors. Our findings demonstrate that less-abundant bacterial phyla, such as Planctomycetes, can display strong spatial and seasonal variations linked to environmental conditions and suggest that their functional role in the lakes studied might be attributable mainly to a small number of phylotypes and vary over space and time in the water column.     

Microcosm enrichment of 1,3-dichloropropene-degrading soil microbial communities in a compost-amended soil

AIMS: A microcosm-enrichment approach was used to investigate bacterial populations that may represent 1,3-dichloropropene (1,3-D)-degrading micro-organisms in compost-amended soil. METHODS AND RESULTS: After 8 weeks of incubation, with repeated application of 1,3-D, volatilization fluxes were much lower for compost-amended soil (CM) than with the unamended soils, indicating accelerated degradation due to addition of compost, or development of new microbial populations with enhanced degradation capacity. Denaturing gradient gel electrophoresis (DGGE) profiles of the PCR-amplified region of 16S rDNA genes were used to identify dominant bacterial populations in the fumigant-degrading soil. The DGGE results indicated that specific bacterial types had been enriched, and a more diverse fingerprint was observed in the community derived from the compost-amended soil compared with the unamended soil. Fragments from 16 different DGGE bands were cloned, sequenced and compared with published 16S rDNA sequences. Two clones, designated E1 and E4, were unique to all soils to which compost was added, and corresponded to strains of Pseudomonas and Actinomadura, respectively. CONCLUSIONS: The results show that the addition of compost to soil increases specific microbial populations and results in the accelerated degradation of fumigants. SIGNIFICANCE AND IMPACT OF THE STUDY: Application of compost manure to soil can help degrade soil fumigants at a faster rate.     

Shifts in soil bacterial community after eight years of land-use change

The interaction between plants, soil and microorganisms is considered to be the major driver of ecosystem functions and any modification of plant cover and/or soil properties might affect the microbial structure, which, in turn, will influence ecological processes. Assuming that soil properties are the major drivers of soil bacterial diversity and structure within the same soil type, it can be postulated whether plant cover causes significant shifts in soil bacterial community composition. To address this question, this study used 16S rRNA pyrosequencing to detect differences in diversity, composition and/or relative abundance of bacterial taxa from an area covered by pristine forest, as well as eight-year-old grassland surrounded by the same forest. It was shown that a total of 69% of the operational taxonomic units (OTUs) were shared between environments. Overall, forest and grassland samples presented the same diversity and the clustering analysis did not show the occurrence of very distinctive bacterial communities between environments. However, 11 OTUs were detected in statistically significant higher abundance in the forest samples but in lower abundance in the grassland samples, whereas 12 OTUs occurred in statistically significant higher abundance in the grassland samples but in lower abundance in the forest samples. The results suggested the prevalence of a resilient core microbial community that did not suffer any change related to land use, soil type or edaphic conditions. The results illustrated that the history of land use might influence present-day community structure.     

Phylogenetic diversity of nitrogen-fixing bacteria and the nifH gene from mangrove rhizosphere soil

Nine types of nitrogen-fixing bacterial strains were isolated from 3 rhizosphere soil samples taken from mangrove plants in the Dongzhaigang National Mangrove Nature Reserve of China. Most isolates belonged to Gammaproteobacteria Pseudomonas, showing that these environments constituted favorable niches for such abundant nitrogen-fixing bacteria. New members of the diazotrophs were also found. Using a soil DNA extraction and PCR-cloning-sequencing approach, 135 clones were analyzed by restriction fragment length polymorphism (RFLP) analysis, and 27 unique nifH sequence phylotypes were identified, most of which were closely related to sequences from uncultured bacteria. The diversity of nitrogen-fixing bacteria was assessed by constructing nifH phylogenetic trees from sequences of all isolates and clones in this work, together with related nifH sequences from other mangrove ecosystems in GenBank. The nifH diversity varied among soil samples, with distinct biogeochemical properties within a mangrove ecosystem. When comparing different mangrove ecosystems, the nifH gene sequences from a specific site tended to cluster as individual groups. The results provided interesting data and novel information on our understanding of diazotroph community diversity in the mangrove ecosystems.     

黄土丘陵区植物群落多样性及生物量随土壤水分梯度变化特征

了解土壤水分与物种多样性及生物量的关系对探究植物群落特征与分布具有重要意义.以陕北黄土丘陵区吴起、米脂、府谷、定边4个典型区域为研究对象,对比分析降水量影响下的土壤水分梯度对自然恢复植物群落多样性、生物量的影响,为黄土丘陵区植被恢复和生物多样性管理提供科学依据.结果表明:随降水量自东南向西北逐渐减少土壤水分呈降低趋势,...     

Short-term plant species impact on microbial community structure in soils with long-term agricultural history

The goal of our study was to capture the short-term effects of individual plant species on an established microbial community in a soil with a well-defined agricultural history. Using biochemical and molecular techniques we quantified the effects of plant species on changes in the soil microbial community over an 8-week time-course. We conducted a greenhouse experiment using field soil from a site that was managed as a Zea mays monoculture for over 50 years. The conditioned soil provided a baseline from which changes in microbial community composition through the effects of newly introduced plants could be determined. Within a short time frame (8 weeks), introduced plants influenced the soil microbial community in ways unique to each plant. Some species (Fagopyrm esculentum and xTriticosecale spp.) resulted in an increase of total microbial community richness, diversity and the stimulation of new microbial species not associated with the legacy vegetation. Other plants (Vicia villosa and Lolium multiflorum) tended to reduce community diversity. We suggest root surface area is good general predictor of rhizosphere microbial community diversity, but in some cases other plant traits may have dominant influence on plant-induced changes in microbial community composition.     

土壤细菌群落特征对高寒草甸退化的响应

为明确高寒草甸土壤细菌物种组成及功能结构对草地环境恶化的响应规律, 本文采用高通量基因测序技术对高寒草甸未退化、轻度退化、中度退化、重度退化和极重度退化草地土壤细菌的组成、格局和功能进行了研究。结果表明: 高寒草甸土壤优势细菌为酸杆菌门、放线菌门、浮霉菌门、变形菌门和疣微菌门, 在土壤细菌中占比分别为16%‒18%、9%‒12%、12%‒14%、23%‒29%和11%‒12%。退化草地中土壤细菌物种组成明显改变, 变形菌门细菌丰度降低, 酸杆菌门和浮霉菌门丰度增加, 不同草地科水平细菌丰度差异因土层而异。草地退化对细菌Chao1指数无影响, 轻度退化提高了细菌Simpson指数, 重度退化草地土壤细菌Shannon-Wiener指数最高。Faprotax细菌功能分组以化能异养、硝化作用、亚硝酸盐氧化及硫代谢作用为主, 草地退化改变了微生物介导的碳循环、氮循环、硫循环、铁循环和锰循环。重度及极重度退化提高了细菌氨氧化功能作用, 降低了硫化物、亚硝酸盐氧化及尿素水解作用; 草地退化过程中细菌化能异养、芳香族化合物降解及反硝化作用功能等均呈先降低后升高的变化趋势, 中度退化阶段是微生物群落生态功能结构转变的拐点。高寒草甸退化改变了土壤细菌的群落及功能结构, 土壤含水量、pH、总有机碳、全氮、全钾和有效氮磷比是土壤细菌群落及功能结构变化的主要驱动因子。     

Initial soil amendments still affect plant community composition after nine years in succession on a heavy metal contaminated mountainside

Many efforts to restore disturbed landscapes seek to meet ecological goals over timescales from decades to centuries. It is thus crucial to know how different actions available to restoration practitioners may affect ecosystems in the long term, yet few such data exist. Here, we test the effects of seed and compost applications on plant community composition 9 years after their application, by taking advantage of a well‐controlled restoration experiment on a mountainside severely degraded by over 80 years of zinc smelting emissions. We asked whether plots have converged on similar plant communities regardless of initial seed and compost treatments, or if these initial treatments have given rise to lasting differences in whole plant communities or in the richness and abundance of native, exotic, and planted species. We found that compost types significantly affected plant communities 9 years later, but seed mix species composition did not. Observed differences in species richness and vegetative cover were negatively correlated, and both were related to the differences in plant communities associated with different compost types. These observed differences are due primarily to the number and abundance of species not in original seed mixes, of which notably many are native. Our results underscore the importance of soils in shaping the aboveground composition of ecosystems. Differences in soil characteristics can affect plant diversity and cover, which are both common restoration targets. Even in highly polluted and devegetated sites, compost and seed application can reinstate high vegetative cover and allow continued colonization of native species.     

紫花针茅根际和体内真菌群落结构及与土壤环境因子的相关性研究

[目的] 探究青藏高原不同地区高寒草原紫花针茅根际和体内真菌群落的组成、多样性等特征,及与土壤环境因子（理化性质和酶活性）间的相互关系。[方法] 从青藏高原不同地区采集紫花针茅样品,应用土壤化学方法分析根际土壤理化性质和酶活性,并采用Illumina Miseq高通量测序技术,解析根际土壤和体内真菌群落组成和丰度、Alpha多样性和菌群结构,同时分析了紫花针茅根际真菌种群多样性与土壤环境因子的相关性,厘清了影响紫花针茅根际真菌区系的土壤环境因素。[结果] 三个采样地的根际土壤呈中性偏碱,土壤理化性质和酶活性变化各异。高通量测序共得到314801条有效序列和4491个OTUs;XZ样地的紫花针茅真菌多样性和丰富度相对偏低,GS样地最高。在门分类水平上,子囊菌门Ascomycota和担子菌门Basidiomycota是主要内生真菌类群,占总菌群的88.28%。不同采样地区紫花针茅体内真菌群落结构存在明显差异,而根际土壤真菌群落结构差异不大。相关性分析表明,紫花针茅真菌多样性与土壤pH、有效钾、铁、钙、镁、多酚氧化酶、过氧化物酶和脱氢酶呈显著（P<0.05）或极显著（P<0.01）正相关,而与海拔、土壤酸性磷酸酶呈极显著负相关。RDA分析发现,紫花针茅根际土壤真菌不同,影响的土壤环境因子也不同。[结论] 青藏高原高寒草地紫花针茅根际和体内栖息着丰富的真菌群落,其组成和多样性受多种土壤环境因子影响,且影响不同真菌群落的主要土壤环境因子也不同。本研究对于有益微生物资源的开发、利用及保护具有重要意义,并为紫花针茅草原保育和合理开发利用提供科学依据。