转mapk双链RNA干扰表达载体黄瓜对根际土壤细菌多样性的影响

随着RNA干扰技术的发展,通过植物表达病原物特异的dsRNA来防治植物病害的转基因作物越来越多.转根结线虫mapk双链RNA表达载体的黄瓜能够通过RNA干扰作用沉默线虫的mapk基因,对根结线虫具有良好的防治效果.为了评价该转基因黄瓜的安全性,明确mapk双链RNA干扰表达载体转基因黄瓜植株对根际土壤细菌多样性的影响,采用16S rRNA基因克隆文库方法对非转基因黄瓜和转基因黄瓜土壤细菌群落多样性进行分析.结果表明,非转基因黄瓜土壤细菌文库包含124个OTU(可操作分类单元),转基因黄瓜土壤细菌文库包含122个OTU.2个文库共同拥有的OTU为115个.2个文库都包含1 3个类群细菌,Acidobacteria、Actinobacteria、Armatimonadetes、Bacteroidetes、candidate division BRC1、Chloroflexi、Firmicutes、Gemmatimonadetes、Nitrospira、Planctomycetes、Proteobacteria、Verrucomicrobia、unclassified_Bacteria. 其中 Proteobacteria、Bacteroidetes 、Chloroflexi和Acidobacteria是优势菌群.其他细菌类群数量相对较少.在纲分类水平上,两个文库包含的细菌类群一致,且各类群细菌比例差异不大.在Acidobacteria门中,Acidobacteria_Gp6为优势菌群.在Bacteroidetes门中,Sphingobacteria纲细菌数量最多.在Chloroflexi门中,unclassified Chloroflexi细菌最多.在Proteobacteria门中,其中Betaproteobacteria纲的细菌数量最多.从多样性指数角度分析,两种土壤细菌群落的Shannon、Simpson和Chao值差异不大.总体来看,两种土壤细菌类群差异不显著,转基因黄瓜未对根际土壤细菌群落产生明显影响.     

松材线虫伴生细菌多样性的宏基组分析

摘要：【目的】松材线虫是松材线虫病的病原,且与其伴生细菌之间存在互作关系,它们构成一个微生态系统。本研究旨在揭示松材线虫-伴生细菌群落细菌多样性。【方法】采用16S rRNA基因文库和454测序对伴生细菌群落的宏基因组进行初步分析。【结果】依据97％序列相似性划分OTU（Operational Taxonomic Unit）,构建的16S rRNA文库包含25个OTU,分别属于Alphaproteobacteria、Betaproteobacteria、Gammaproteobacteria和Bacter     

松材线虫伴生细菌多样性的宏基因组分析

【目的】松材线虫是松材线虫病的病原,且与其伴生细菌之间存在互作关系,它们构成一个微生态系统。本研究旨在揭示松材线虫-伴生细菌群落细菌多样性。【方法】采用16S rRNA基因文库和454测序对伴生细菌群落的宏基因组进行初步分析。【结果】依据97%序列相似性划分OTU(Operational Taxonomic Unit),构建的16S rRNA文库包含25个OTU,分别属于Alphaproteobacteria、Betaproteobacteria、Gammaproteobacteria和Bacteroidetes,其中优势菌群为Gammaproteobacteria,特别是Stenotrophomonas maltophilia为优势细菌。在伴生细菌优势种群上,454测序结果与16SrRNA基因文库结果基本一致。【结论】松材线虫的伴生细菌多样性较高,这些细菌可能对松材线虫具有一定的生态意义。     

滑桃树不同器官伴生细菌多样性的分子特征

应用不依赖于培养的16S rRNA基因技术,揭示滑桃树根皮、茎皮以及种子伴生细菌的种类多样性,为建立伴生细菌的宏基因组文库奠定基础。基于我们新近发表的植物伴生菌富集方法,建立富集和未富集样品的全长16S rRNA基因文库,随机挑取至少100个克隆进行酶切分型并测序,根据16S rDNA的部分序列推测其所属伴生菌的种类。结果表明,所检测的细菌克隆大部分属于γ-Proteobacteria,有少量来源于α-Proteobacteria或放线菌（Actinobacteria）,也包括不可培养或分类地位不明确的细菌。经过富集,16S rRNA基因文库中细菌克隆的比例和序列多样性显著增加,根皮的伴生细菌种类最为丰富,其次是成熟种子和茎皮;幼嫩种子16S rDNA文库的细菌克隆比例较小（1．18％）,说明幼嫩种子的伴生菌最少。     

柠檬酸废水IC反应器厌氧颗粒污泥真细菌结构分析

目的:分析柠檬酸工业废水IC厌氧反应器处理时产生的厌氧颗粒污泥中真细菌的菌群结构.方法:构建细菌的16S rDNA克隆文库,对文库中的16S rDNA基因序列进行测序,然后Blast比对,并进行分类、建系统发育树.结果:对获得的77个16S rDNA序列进行测序,按序列相似性≥97％的分类标准,这些序列可分为22个OTU,其中4个优势OTU分别与棒杆菌属(Corynebacterium)、梭菌属(Clostridium)、消化球菌属(Peptococcus)、疣微菌属(Verrucomicrobia)最为相近,其余OTU的克隆数较少.颗粒污泥中的真细菌主要为放线菌纲(Actinobacteria)、梭菌纲(Clostridia)、拟杆菌纲(Bacteroidetes)以及δ-变形菌纲(Deltaproteobacteria)的细菌,分别占克隆总数的34/77、31/77、6/77、6/77.结论:该文研究了柠檬酸废水处理过程中产生的厌氧颗粒污泥中细菌的菌群组成和结构,为深入了解柠檬酸废水的厌氧处理过程提供了一定的理论借鉴作用.     

宝天曼落叶阔叶林土壤细菌多样性

土壤微生物在森林生态系统中起着重要作用。高通量测序方法的出现为进一步认识土壤微生物提供了契机。本文利用Illumina Miseq高通量测序技术对宝天曼森林土壤的细菌多样性进行了初步研究。结果显示:在31个采样点内,随着采样点增加,检测出不同分类水平的土壤细菌类群也在增多,当采样点达到31个时,检测出的土壤细菌类群达到45门163纲319目495科785属和42,632个OTU;31个土壤样品中所检测出的细菌类群平均有34.2门114.7纲215.2目323.7科446.6属5,924.7个OTU,其中门、纲、目分类水平上的优势类群(所占比例)分别为变形菌门(Proteobacteria)(38.30%)、α-变形菌纲(α-Proteobacteria)(18.08%)、根瘤菌目(Rhizobiales)(10.62%)。这些初步研究结果表明在一定程度上宝天曼森林土壤有较高的细菌多样性水平,为进一步认识森林土壤细菌多样性与植物多样性关系等奠定了基础。     

可可西里土壤样品中细菌多样性的分析

本实验采用纯培养和免培养相结合的方法对来源于可可西里的一份土壤样品中的细菌多样性进行了初步研究。纯培养实验使用了6种分离培养基, 共得到细菌19株, 其中放线菌7株, 非放线菌细菌12株。这些菌株分别属于叶杆菌属(Phyllobacterium)、贪食菌属(Variovorax)、假单胞菌属(Pseudomonas)、链霉菌属(Streptomyces)、小月菌属(Microlunatus)、原小单胞菌属(Promicromonospora)、韩国生工菌属(Kribbella)和芽孢杆菌属(Bacillus) 8个属。免培养分析采用基于通用引物PCR 扩增的细菌16S rRNA 基因文库的方法以及变性梯度凝胶电泳(DGGE)。16S rRNA基因文库分析结果表明, 该土壤样品细菌群落可划分为19个OTUs, 分属于5个不同纲, 优势顺序为β-Proteobacteria (75%), α-Proteobacteria (9%), γ-Proteobacteria (7%), Actinobacteria (7%), Firmicutes (2%)。变性梯度凝胶电泳分析表明, 该样品细菌多样性指数Shannon-wiener index为2.68, 表明其中微生物多样性较低, 这可能和其所处的极端环境有一定关系。比较纯培养和免培养的实验结果发现, 土壤中的一些优势细菌并没有被有效地分离, 需要在针对特定微生物设计特定培养基及培养条件进行选择性分离上做更多的探索研究。     

昆明盐矿古老岩盐沉积中的原核生物多样性

应用PCR-DGGE和rRNA分析法研究了昆明盐矿古老岩盐沉积中的原核生物多样性。样品的细菌DGGE分析得到27条带,古菌得到18条带。样品与纯培养得到的19个属菌株的DGGE图谱对比分析发现,细菌18个属菌株,只有1个属菌株与样品中的1条带迁移位置都不一致;古菌1个属的菌株不与样品中任何条带迁移位置一致。表明纯培养所得菌株并非该环境中的优势类群。同时,建立了样品细菌和古菌的16S rDNA克隆文库,从中分别挑取36个细菌克隆和20个古菌克隆进行ARDRA分析。细菌可分为10个OTUs,其中3个OTUs是优势类群,分别占38.9%,25.0%,16.7%,其余7个OTUs各含有1个克隆。古菌分为8个OTUs,没有明显的优势类群。每个OTU的代表克隆16S rDNA序列分析表明,细菌分属3大类群:α-Proteobacteria,γ-Proteobacteria和Actinobacteria,以Pseudomonas属菌为优势,含有其它岩盐沉积中没有发现的Actinobacteria。古菌主要是Halorubrum属、Haloterrigena属菌和未培养古菌。本研究表明,昆明盐矿古老岩盐沉积具有较丰富的原核生物多样性,含有大量未知的、未培养或不可培养的原核生物,但在原核生物物种组成和丰度上,免培养与此前的纯培养研究结果存在一定差异。因此,结合使用两类方法才能较全面地认识高盐极端环境微生物的多样性。     

九龙江河口区nirS型反硝化细菌多样性及系统发育学分析

【目的】结合16S rRNA基因克隆文库和nirS基因克隆文库的分析,揭示九龙江河口区nirS型反硝化细菌多样性。【方法】选取九龙江河口区一富营养化采样点,分别采集水样及沉积物样品,进行理化因子的测定并提取细菌总DNA。以水样DNA构建16S rRNA基因克隆文库,以沉积物DNA构建nirS基因克隆文库,分析微生物群落结构的多样性并构建系统发育树。【结果】从16S rRNA基因克隆文库中获得86条有效序列,按97%的序列相似性划分为53个OTU,分别属于Proteobacteria门、Planctomycetes门、Bacteroidetes门、Actinobacteria门、Firmicutes门和Chloroflexi门。其中属于Proteobacteria门OTU的克隆子占克隆数的62.9%,是最优势的类群,分属于Alphaproteobacteria、Betaproteobacteria、Gammaproteobacteria和Deltaproteobacteria纲等。从nirS基因克隆文库中获得190条有效序列,翻译为氨基酸序列后,按82%的序列相似性划分为60个OTU,并定位到属的水平。其中Proteobacteria门是最优势的类群,占文库克隆子总数的71.6%,包括Alphaproteobacteria纲(5.8%)、Betaproteobacteria纲(49.0%)和Gammaproteobacteria纲(16.9%)。nirS基因克隆文库中丰度最高的OTU与GenBank中的一株可培养反硝化菌Thauera sp. R-26906具有100%的序列相似性。【结论】九龙江河口区的微生物以及亚硝酸盐还原酶基因(nirS)具有丰富的多样性。大部分NirS序列在GenBank中的最相似序列来源于河口、海湾等相似的环境。     

秸秆蓝藻混合发酵产沼气过程中微生物群落分析

采用实验室自制秸秆蓝藻混合厌氧反应装置进行沼气发酵实验,利用16S rRNA基因克隆文库的方法,对不同产气阶段的细菌和古菌的优势菌群进行多样性研究。结果表明:(1)不同产气阶段细菌优势种类存在差异,供试秸秆沼气反应器阶段细菌种类较为丰富,分属于6个门:产气初始阶段优势菌群为变形菌门(Proteobacteria),相对丰度为51.76%;产气高峰阶段优势菌群为厚壁菌门(Firmicutes),相对丰度为47.13%;产气结束阶段优势菌群为厚壁菌门(Firmicutes),相对丰度为28.89%;此外,还包括绿弯菌门、螺旋体门、绿菌门的细菌。(2)古菌种类明显少于细菌,均属于甲烷微菌纲(Methanomicrobia)、甲烷杆菌纲(Methanobacteria)和热原体纲(Thermoplasmata)。秸秆蓝藻沼气系统微生物群落结构的阐明具有一定的意义,可为秸秆沼气工程调控提供科学依据。     

Effect of hydrogen on soil bacterial community structure in two soils as determined by terminal restriction fragment length polymorphism

The metabolism of hydrogen evolved from HUP^? legume nodules can alter bacterial community structures in the rhizosphere. Our earlier experiments demonstrated increased hydrogen uptake and appearance of white spots within bacterial colonies in H₂-treated soil. We were also able to isolate hydrogen-oxidizing bacteria from soil samples exposed to hydrogen, but not from samples exposed to air. To further understand the effect of hydrogen metabolism on soil microbial communities, in this study 16S rRNA terminal restriction fragment (TRF) profiles of different soil samples exposed to hydrogen gas under laboratory, greenhouse, and field conditions were analyzed. Relationships between soil bacterial community structures from hydrogen-treated soil samples and controls, illustrated by UPGMA (unpaired group mathematical averages) dendrograms, indicated a significant contribution of hydrogen metabolism to the variation in bacterial community. The intensity variation of TRF peaks includes both hydrogen-utilizing bacteria, whose growth were stimulated by hydrogen exposure, and other bacterial species whose growth was inhibited. Comparison of TRF profiles between laboratory and greenhouse samples showed that T-RFLP is a useful technique in the detection of root-related effects on soil bacterial community structure.     

设施菜田与棚外粮田土壤菌群和反硝化气体产生的比较分析

【目的】对比设施菜田与棚外粮田土壤菌群以及N2O产生模式的差异。【方法】采用变性梯度凝胶电泳(DGGE)和反硝化功能基因(nirS,nosZ)方法分别比较两种土壤细菌群落以及功能基因类群丰度的差异,利用自动连续在线培养监测体系(Robot系统)测定两种土壤在好氧、厌氧阶段N2O等反硝化相关气态产物产生模式,分析N2O/(N2+N2O+NO)产物比。【结果】设施菜田与棚外粮田具有不同的土壤细菌群落结构,并且土壤细菌总量得到了显著的提升,然而两种反硝化功能基因(nirS,nosZ)丰度并没有显著变化。与设施菜田相比,棚外粮田有相对低的N2O积累量以及产物比,并且在厌氧初期气体产生模式有所不同。培养后铵态氮和亚硝态氮含量上升。【结论】设施菜田长期有别于棚外粮田的管理方式造成了土壤细菌群落的显著改变,增大了活跃微生物总量,造成土壤酸化,并导致N2O在气态产物中的比例升高。设施菜田土壤微生物进行了与棚外粮田不同的硝酸盐呼吸过程,异化硝酸盐还原成铵(DNRA)过程有可能贡献了两种土壤的部分厌氧N2O产生量。     

Bacterial Diversity in Rhizospheres of Nontransgenic and Transgenic Corn

Bacterial diversity in transgenic and nontransgenic corn rhizospheres was determined. In greenhouse and field studies, metabolic profiling and molecular analysis of 16S rRNAs differentiated bacterial communities among soil textures but not between corn varieties. We conclude that bacteria in corn rhizospheres are affected more by soil texture than by cultivation of transgenic varieties.     

Bacterial diversity in rhizospheres of nontransgenic and transgenic corn

Bacterial diversity in transgenic and nontransgenic corn rhizospheres was determined. In greenhouse and field studies, metabolic profiling and molecular analysis of 16S rRNAs differentiated bacterial communities among soil textures but not between corn varieties. We conclude that bacteria in corn rhizospheres are affected more by soil texture than by cultivation of transgenic varieties.     

A Greenhouse Assay on the Effect of Applied Urea Amount on the Rhizospheric Soil Bacterial Communities

The rhizospheric bacteria play key role in plant nutrition and growth promotion. The effects of increased nitrogen inputs on plant rhizospheric soils also have impacted on whole soil microbial communities. In this study, we analyzed the effects of applied nitrogen (urea) on rhizospheric bacterial composition and diversity in a greenhouse assay using the high-throughput sequencing technique. To explore the environmental factors driving the abundance, diversity and composition of soil bacterial communities, the relationship between soil variables and the bacterial communities were also analyzed using the mantel test as well as the redundancy analysis. The results revealed significant bacterial diversity changes at different amounts of applied urea, especially between the control treatment and the N fertilized treatments. Mantel tests showed that the bacterial communities were significantly correlated with the soil nitrate nitrogen, available nitrogen, soil pH, ammonium nitrogen and total organic carbon. The present study deepened the understanding about the rhizospheric soil microbial communities under different amounts of applied urea in greenhouse conditions, and our work revealed the environmental factors affecting the abundance, diversity and composition of rhizospheric bacterial communities.

Electronic supplementary material

The online version of this article (doi:10.1007/s12088-015-0551-7) contains supplementary material, which is available to authorized users.     

小叶章生态系统根际土壤微生物及CO2、CH4、N2O动态

研究了培养 4 5 d的小叶章根际土壤微生物和二氧化碳 ,甲烷及氧化亚氮产生与消耗之间的关系。结果表明好氧微生物与厌氧微生物的空间分布与甲烷 ,二氧化碳及氧化亚氮的产生和氧化有着密切的关系。好氧微生物与甲烷产生呈负相关 ,与二氧化碳和氧化亚氮的产生呈正相关关系。厌氧微生物与甲烷的产生呈正相关 ,与二氧化碳和氧化亚氮的产生呈负相关关系     

过量施肥对设施菜田土壤菌群结构及N2O产生的影响

【背景】N_2O是一种很强的温室气体,其温室效应强度大约是CO_2的265倍。土壤氮肥施加量是影响N_2O排放的重要因素,而厌氧条件下微生物反硝化则是N_2O产生的重要途径。【目的】研究过量施肥条件下蔬菜大棚土壤菌群结构变化及其对N_2O气体排放的影响。【方法】利用自动化培养与实时气体检测系统(Robot)监测土壤厌氧培养过程中N_2O和N_2排放通量,比较过量施肥和减氮施肥模式下土壤N_2O排放模式的差异。通过Illumina二代测序平台对这2种不同施肥处理的土壤微生物群落进行高通量测序,研究不同施肥量对土壤菌群组成的影响。【结果】过量施肥土壤中硝酸盐的含量大约是减氮施肥土壤的2倍,通过添加硝酸盐使2种土壤的硝酸盐含量均为60 mg/kg或为200 mg/kg时,过量施肥土壤在厌氧培养前期N_2O气体的产生量及产生速度都明显高于减氮施肥土壤。另外,过量施肥导致土壤菌群结构发生显著改变,并且降低了土壤微生物的多样性。相对于减氮施肥,过量施肥方式富集了Rhodanobacter属的微生物。PICRUSt预测结果显示,传统施肥没有显著改变反硝化功能基因相对丰度。【结论】长期过量氮肥施用显著增加了土壤N_2O的排放,可能原因是施肥改变了包括氮转化相关微生物在内的土壤菌群组成,从而影响了土壤N_2O气体的形成与还原过程。     

Bacterial communities associated with the rhizosphere of transgenic Bt 176 maize (Zea mays) and its non transgenic counterpart

The effect of transgenic Bt 176 maize on the rhizosphere bacterial community has been studied with a polyphasic approach by comparing the rhizosphere of Bt maize cultivated in greenhouse with that of its non transgenic counterpart grown in the same conditions. In the two plants the bacterial counts of the copiotrophic, oligotrophic and sporeforming bacteria, and the community level catabolic profiling, showed no significant differences; differences between the rhizosphere and bulk soil bacterial communities were evidenced. Automated ribosomal intergenic spacer analysis (ARISA) showed differences also in the rhizosphere communities at different plant ages, as well as between the two plant types. ARISA fingerprinting patterns of soil bacterial communities exposed to root growth solutions, collected from transgenic and non transgenic plants grown in hydroponic conditions, were grouped separately by principal component analysis suggesting that root exudates could determine the selection of different bacterial communities.     

Soil pH and electrical conductivity are key edaphic factors shaping bacterial communities of greenhouse soils in Korea

Soil microorganisms play an essential role in soil ecosystem processes such as organic matter decomposition, nutrient cycling, and plant nutrient availability. The land use for greenhouse cultivation has been increasing continuously, which involves an intensive input of agricultural materials to enhance productivity; however, relatively little is known about bacterial communities in greenhouse soils. To assess the effects of environmental factors on the soil bacterial diversity and community composition, a total of 187 greenhouse soil samples collected across Korea were subjected to bacterial 16S rRNA gene pyrosequencing analysis. A total of 11,865 operational taxonomic units at a 97% similarity cutoff level were detected from 847,560 sequences. Among nine soil factors evaluated; pH, electrical conductivity (EC), exchangeable cations (Ca²⁺, Mg²⁺, Na⁺, and K⁺), available P₂O₅, organic matter, and NO₃-N, soil pH was most strongly correlated with bacterial richness (polynomial regression, pH: R² = 0.1683, P < 0.001) and diversity (pH: R² = 0.1765, P < 0.001). Community dissimilarities (Bray-Curtis distance) were positively correlated with Euclidean distance for pH and EC (Mantel test, pH: r = 0.2672, P < 0.001; EC: r = 0.1473, P < 0.001). Among dominant phyla (> 1%), the relative abundances of Proteobacteria, Gemmatimonadetes, Acidobacteria, Bacteroidetes, Chloroflexi, and Planctomycetes were also more strongly correlated with pH and EC values, compared with other soil cation contents, such as Ca²⁺, Mg²⁺, Na⁺, and K⁺. Our results suggest that, despite the heterogeneity of various environmental variables, the bacterial communities of the intensively cultivated greenhouse soils were particularly influenced by soil pH and EC. These findings therefore shed light on the soil microbial ecology of greenhouse cultivation, which should be helpful for devising effective management strategies to enhance soil microbial diversity and improving crop productivity.     

Responses of Bacterial Communities to Simulated Climate Changes in Alpine Meadow Soil of the Qinghai-Tibet Plateau

The soil microbial community plays an important role in terrestrial carbon and nitrogen cycling. However, microbial responses to climate warming or cooling remain poorly understood, limiting our ability to predict the consequences of future climate changes. To address this issue, it is critical to identify microbes sensitive to climate change and key driving factors shifting microbial communities. In this study, alpine soil transplant experiments were conducted downward or upward along an elevation gradient between 3,200 and 3,800 m in the Qinghai-Tibet plateau to simulate climate warming or cooling. After a 2-year soil transplant experiment, soil bacterial communities were analyzed by pyrosequencing of 16S rRNA gene amplicons. The results showed that the transplanted soil bacterial communities became more similar to those in their destination sites and more different from those in their “home” sites. Warming led to increases in the relative abundances in Alphaproteobacteria, Gammaproteobacteria, and Actinobacteria and decreases in Acidobacteria, Betaproteobacteria, and Deltaproteobacteria, while cooling had opposite effects on bacterial communities (symmetric response). Soil temperature and plant biomass contributed significantly to shaping the bacterial community structure. Overall, climate warming or cooling shifted the soil bacterial community structure mainly through species sorting, and such a shift might correlate to important biogeochemical processes such as greenhouse gas emissions. This study provides new insights into our understanding of soil bacterial community responses to climate warming and cooling.