Bacterial diversity in paclobutrazol applied agricultural soils

The aim of this study was to investigate the bacterial communities on paclobutrazol [(2RS, 3RS)-1-(4-Chlorophenyl)-4, 4-dimethyl-2-(1H-1,2,4-triazol-1-yl) pentan-3-ol]–applied agricultural soils by denaturing gradient gel electrophoresis (DGGE) of polymerase chain reaction (PCR) amplified 16S rDNA gene fragments. Three different agricultural soil samples were collected from paclobutrazol applied mango and waxapple orchards, peanut fields and untreated rice fields as a control for DGGE analysis. The DGGE pattern of PCR- generated 16S rDNA gene fragments indicated that the bacterial populations from four paclobutrazol–applied soils of peanut fields were closely related to each other and two paclobutrazol–applied soils of mango and waxapple orchards harbored closely related bacterial communities. But, paclobutrazol–free agricultural soils comprised relatively a different bacterial group. However, the bacterial populations of mango and waxapple orchard are completely different from the bacterial communities of peanut field. Further purification and sequence analysis of 40 DGGE bands followed by phylogenetic tree assay showed similar results that soil bacteria from paclobutrazol applied mango and waxapple orchard are phylogenetically related. Based on the phylogenetic analysis, the clone M-4 was clad 100 % (bootstrap value) with Mycobacterium sp. The Mycobacterium sp. has been proved to degrade the phenolic compounds such as phenol, 4-chlorphenol, 2,4-dichlorophenol and paclobutrazol molecule containing chlorobenzene ring.     

教育与区域经济发展差异--基于江苏和江西的实证分析

本文主要分析了教育对于区域经济发展差异的影响及作用机理。通过对江苏和江西两省的实证分析，提出并验证了教育发晨所引起的地区经济发展的差异，主要有两个方面共同作用的结果：即教育总体发展程度不同所产生的规模效应和不同教育层次发晨的侧重差异所引起的结构效应。最后。对今后区域教育发展战略的进一步完善提出了政策建议。     

Nitrogen deposition alters soil chemical properties and bacterial communities in the Inner Mongolia grassland

Nitrogen deposition has dramatically altered biodiversity and ecosystem functioning on the earth; however, its effects on soil bacterial community and the underlying mechanisms of these effects have not been thoroughly examined. Changes in ecosystems caused by nitrogen deposition have traditionally been attributed to increased nitrogen content. In fact, nitrogen deposition not only leads to increased soil total N content, but also changes in the NH₄⁺-N content, NO₃^--N content and pH, as well as changes in the heterogeneity of the four indexes. The soil indexes for these four factors, their heterogeneity and even the plant community might be routes through which nitrogen deposition alters the bacterial community. Here, we describe a 6-year nitrogen addition experiment conducted in a typical steppe ecosystem to investigate the ecological mechanism by which nitrogen deposition alters bacterial abundance, diversity and composition. We found that various characteristics of the bacterial community were explained by different environmental factors. Nitrogen deposition decreased bacterial abundance that is positively related to soil pH value. In addition, nitrogen addition decreased bacterial diversity, which is negatively related to soil total N content and positively related to soil NO₃^--N heterogeneity. Finally, nitrogen addition altered bacterial composition that is significantly related to soil NH₄⁺-N content. Although nitrogen deposition significantly altered plant biomass, diversity and composition, these characteristics of plant community did not have a significant impact on processes of nitrogen deposition that led to alterations in bacterial abundance, diversity and composition. Therefore, more sensitive molecular technologies should be adopted to detect the subtle shifts of microbial community structure induced by the changes of plant community upon nitrogen deposition.     

梯度负荷下果蔬垃圾厌氧消化性能及微生物群落结构的研究

为优化果蔬垃圾厌氧消化工艺,提高厌氧消化性能,本文通过逐级提高CSTR反应器进料负荷,研究不同负荷下的厌氧消化性能及相应的微生物群落结构变化规律.结果表明,随着进料负荷的增高,容积产气率、甲烷产气量、氨氮、碱度、TCOD、SCOD均逐渐增高,在最高负荷(负荷以VS计)2.50g·L-·1d-1时分别达到最大值:1.22L·L-1d-1,5.10L·d-1,1563.86mg·L-1,7572.23mg·L-1,13283.26mg·L-1,2075.03mg·L-1,甲烷含量及VFA分别稳定在52.46%～54.59%和(879.30±18.69)mg·L-1;同时利用PCR-DGGE技术系统分析了厌氧消化中细菌与古细菌的群落结构,测序结果表明,整个过程中拟杆菌(Bacteroidetes)、甲烷鬃菌(Methanosaeta)及甲烷螺菌(Methanospirillum)为优势微生物,随着负荷的提高,甲烷鬃毛菌(Methanosaeta)活性逐渐降低;聚类分析及主成分分析表明,低负荷条件下(1.50g·L-·1d-1、1.75g·L-·1d-1),微生物种类(细菌、古细菌)差别不明显,且基本处于同一阶段.     

序批式生物反应器填埋场脱氮微生物多样性分析

为探究序批式生物反应器填埋场脱氮过程中的微生物作用机制,本研究采用建立脱氮功能基因(amoA、nosZ)克隆文库及PCR-RFLP技术对序批式生物反应器填埋场垃圾稳定化后期的主要脱氮功能微生物多样性进行分析.结果表明,矿化垃圾反应器中检测到的氨氧化细菌存在高度多样性,大部分为未知类群,且均为不可培养菌或未经分离获得的细菌,经系统发育树分析系统内氨氧化细菌以β-变形菌门中的亚硝化单胞菌属(Nitrosomonas)为主;新鲜垃圾反应器中反硝化细菌种群丰富,主要有β-变形菌纲中的陶厄氏菌属(Thauera)和硫杆菌属(Thiobacillus).Thauera属在好氧条件下具有反硝化特性,Thiobacillus属中的脱氮硫杆菌(Thiobacillus denitrificans)是一种硫自养反硝化菌,可见新鲜垃圾单元稳定化后期以好氧反硝化和自养反硝化的脱氮途径为主.此外文库中检测到的一部分反硝化细菌可能归属于α-变形菌纲的慢生根瘤菌科(Bradyrhizobiaceae).     

深水型水库热分层诱导水质及真菌种群结构垂向演替

水体真菌种群在调控水库生态系统健康过程中发挥重要作用,为探明热分层诱导深水型水库水体真菌种群结构垂向演替特征,采集金盆水库主库区0.5、10、25、40、60和70 m水深水样,分析水质参数、并运用高通量DNA测序技术诊断水库水体真菌种群结构垂向异质性.结果表明,金盆水库表层水温最高为22.33℃,底层最低为7.21℃(P0.05).水体溶解氧(DO)随水深增加显著降低(P0.05),电导率、总磷(TP)和铁含量随着水深增加显著升高(P0.05),垂向形成稳定的变温层、斜温层和等温层结构.水体真菌种群高通量DNA测序共发现1 247个OTUs,隶属4门14纲39属,主要包括接合菌门(Zygomycota)、担子菌门(Basidiomycota)、子囊菌门(Ascomycota)和壶菌门(Chytridiomycota).等温层水体真菌种群Shannon指数和Chao 1多样性指数最高,分别为3.45和360,显著高于斜温层水体(P0.05).红酵母属(Rhodotorula,27.23%)、链格孢属(Alternaria,24.28%)、分子孢子菌属(Cladosporium,22.98%)、链格孢属(Alternaria,32.00%)、亚隔孢壳属(Didymella,17.47%)和分子孢子菌属(Cladosporium,28.17%)分别是0.5、10、25、40、60、70 m的优势菌属,不同水深均存在大量未知真菌(Unclassified).热图(heat map)结果表明,热分层期间金盆水库水体真菌种群结构垂向分布差异显著、不同水层具有不同的真菌种群结构.主成分分析(PCA)表明水温、DO、TP、电导率是调控水体真菌种群结构垂向异质性的主要水质因子.该研究结果为水源水库热分层期间水质与真菌群落的偶联机制提供科学依据.     

秦岭中段北坡不同海拔土壤中细菌群落的分布特征及区域差异比较

为深入理解土壤细菌群落沿海拔梯度的分布特征,以秦岭山脉中段的朱雀国家森林公园朱雀山北坡（简称“朱雀北坡”）与太白山自然保护区太白山北坡（简称“太白山北坡”）为研究区域,海拔梯度上每隔400 m设置采样点,通过高通量测序研究土壤细菌群落的海拔变化规律及其关键影响因素.结果表明:研究区域内,随海拔升高,土壤pH趋于降低（太白山北坡不明显）,w（TC）、w（TN）、w（TOC）均显著升高,w（TP）也趋于升高（朱雀北坡不明显）.两个区域土壤细菌中相对丰度最高的均为变形菌门和酸杆菌门,朱雀北坡随海拔梯度变化显著的细菌主要包括变形菌门、硝化螺旋菌门、浮霉状菌门、酸杆菌门、放线菌门,其中,硝化螺旋菌门相对丰度与海拔呈正相关,放线菌门相对丰度与海拔呈负相关;太白山北坡随海拔梯度变化显著的细菌主要包括放线菌门、疣微菌门、浮霉状菌门、绿弯菌门,其中,放线菌门相对丰度与海拔呈负相关,其余三者相对丰度与海拔呈正相关.两个区域土壤细菌多样性指数（如Shannon-Wiener指数、Chao1指数、observed-species指数、PD_whole_tree指数等）沿海拔梯度均无明显变化规律,但太白山北坡数值整体上高于朱雀北坡.典范对应分析（canonical correlation analysis,CCA）结果显示,影响朱雀北坡和太白山北坡土壤细菌群落结构的主要因素均为pH和w（TOC）.研究显示,不同海拔梯度也是导致秦岭中段北坡土壤细菌群落差异的重要因素.      

甜龙竹不同种植年限对土壤真菌群落的影响

为探究甜龙竹(Dendrocalamus brandisii)种植年限对土壤真菌群落的影响,以不同种植年限(5、 10、 20和40 a)甜龙竹土壤为研究对象,采用高通量测序技术和FUNGuild功能预测相结合的研究方法,分析不同种植年限下甜龙竹土壤真菌群落结构、多样性和功能的差异,揭示驱动土壤真菌群落变化的主要土壤环境因子.结果表明,土壤真菌在门水平上的优势群落为子囊菌门(Ascomycota)、担子菌门(Basidiomycota)、被孢霉门(Mortierellomycota)和毛霉菌门(Mucoromycota);被孢霉门的相对丰度随着种植年限的增加先降低后升高,在不同种植年限差异显著(P<0.05).在纲水平上的优势群落为粪壳菌纲(Sordariomycetes)、伞菌纲(Agaricomycetes)、散囊菌纲(Eurotiomycetes)和被孢霉纲(Mortierellomycetes);粪壳菌纲和座囊菌纲(Dothideomycetes)的相对丰度随着种植年限的增加先降低后升高,在不同种植年限差异显著(P<0.01).土壤真菌Richness指数和Shan...