对虾综合养殖生态系底泥细菌的数量动态

1997年5～9月于山东海阳市黄海集团公司养虾场,用5个实验围隔研究了对虾综合养殖生态系底泥细菌的数量动态.结果表明,底泥细菌数量波动在4.10×108～12.36×108cells·g-1之间,平均为8.09×108±2.17×108cells·g-1.随着养殖时间的推移,底泥细菌数量逐渐增加.底泥细菌数量最大值出现在表层1cm之内,2～3cm以下泥层。

东湖通道工程对沿线底泥细菌群落结构和多样性的影响

为调查东湖通道工程对沿线底泥细菌群落结构和多样性可能造成的影响,随着隧道施工的进程,在东湖通道沿线的3个湖区中的19个采样点进行了3次采样,通过PCR-DGGE结合分子克隆技术,分析了细菌群落的群落结构及多样性。3批样品共检出细菌类群分别为5门18属、6门17属、5门11属。在门水平上,底泥中的优势菌是变形菌门,但其在总量中的比例随施工进程逐渐下降,依次为86%、80.6%和43.9%。在属水平上,施工初期的优势菌是埃希氏杆菌属,施工后期却是Steroidobacter。通道施工初期,汤菱湖、郭郑湖的湖心区域在属水平上的群落结构相似性较高,与团湖差异显著;接近施工区样点与远离施工区样点的底泥细菌群落存在显著差异;因施工形成的临时封闭水域与敞水区除均有埃希氏杆菌属外,其他菌属类群差异显著。施工后期的汤菱湖、郭郑湖及团湖的湖心区的底泥微生物群落结构趋于相似;接近施工区样点与远离施工区样点的底泥细菌群落差异不显著;封闭区和敞水区有相似的细菌群落结构。施工期间,细菌群落的多样性指数的最高点都有出现在靠近施工区的位置。各批次样点的Simpson_1-D指数、Shannon_H指数、Margalef指数,均随着施工进程而逐渐增加。因此,东湖通道修建对通道沿线近距离的底泥细菌的群落结构和多样性产生了较显著的影响,这种影响是暂时性还是持续性的,尚需通道完工回填后的长期评估。研究将为进一步探讨通道修建等人为强干扰活动对浅水湖泊的可能环境影响和制定合理的生态修复策略提供理论基础和数据支撑。

大神堂海域人工鱼礁投放对底泥细菌的影响

为探究人工鱼礁投放对底泥细菌群落结构和功能的影响,于2018年9月对2014年投礁人工鱼礁区、2018年6月新投礁区和对照区进行表层沉积物细菌16S rRNA基因测序和环境因子测定。利用高通量测序技术对细菌16S rRNA基因V4~V5区进行测序,并结合环境因子分析细菌群落的结构变化和影响因子。结果表明,投礁2个月后,新投礁区的细菌群落结构逐渐与鱼礁区趋于一致,鱼礁区和新投礁区细菌物种数和多样性指数均高于对照区,且差异显著(P<0.05)。从门类上看,变形菌门是渤海湾沉积物中丰度最高的菌种,对照区变形菌门和拟杆菌门丰度低于其他2个区域,厚壁菌门和蓝细菌丰度显著高于其他2个区域。从种类上看,对照区细菌种类明显多于其他2个区域,鱼礁投放使细菌种类发生了聚集,硫氧化菌丰度显著降低,海洋伍斯菌和脱硫细菌丰度显著升高。环境因子检测表明,与本底值和对照区相比,人工鱼礁的投放使海域底泥的粒径变小,夏季溶解氧和硫化物含量降低。功能基因和影响因子相关分析表明,鱼礁区底泥细菌的硫还原反应影响了礁区的环境,同时礁区环境的改变也影响了菌群的结构。

典型高原湖滨带底泥细菌群落结构及多样性特征

【背景】高原湖泊的富营养化日趋严重,而湖滨带作为湖泊的保护屏障对外源污染物具有拦截净化等作用,水环境变化则会对底泥细菌产生深刻影响。【目的】探究高原湖滨带底泥细菌群落结构特征及与水体富营养化之间的联系。【方法】基于16S rRNA基因高通量测序技术分析了阳宗海南岸湖滨带8个不同样点的底泥细菌群落结构及多样性,并结合样品水体环境因子,采用主成分分析(PCA)和冗余分析(redundancy analysis,RDA)探讨了水体富营养化对底泥细菌群落结构及丰富度的影响。【结果】湖滨带底泥细菌与水体富营养化程度存在响应关系,在水体富营养化程度高的区域(S3)细菌丰富度较高,操作分类单元(operationaltaxonomicunits,OTU)高达1473。反之,在富营养化程度低的区域(S1)细菌丰富度较低,OTU为730。阳宗海南岸湖滨带底泥中主要优势菌门为变形菌门(Proteobacteria)和绿弯菌门(Chloroflexi),含有少量的放线菌门(Actinobacteria)、酸杆菌门(Acidobacteria)和厚壁菌门(Firmicutes);绿弯菌门(Chloroflexi)与水体富营养化程度具有相关性,在中度富营养化区域,绿弯菌门(Chloroflexi)的比重高达44.1%,而在轻度富营养化区域绿弯菌门(Chloroflexi)的比重仅为15.6%。通过环境因子分析发现,阳宗海湖滨底泥细菌受总磷(TP)、叶绿素a(Chla)和总氮(TN)影响较强。【结论】研究结果明确了高原湖泊湖滨带底泥细菌种群的结构、变化特征及其对于水体富营养化的响应,加深了高原湖泊底泥细菌的了解,为高原湖泊水体富营养化的防治提供理论基础。

一种水质改良保持制剂对黑臭水体底泥的影响研究

为考察一种水质改良保持制剂对黑臭水体底泥细菌群落结构和多样性可能造成的影响,在北京大兴区南苑灌渠汇入新凤河的长约6公里的支流中采用水质改良保持制剂进行了为期6个月的间歇投加,期间对支流的两个点进行了4次采样,通过PCR-DGGE结合分子克隆技术,分析了不同样品细菌群落的群落结构及多样性,从而进一步分析了水质改良保持制剂对底泥的影响。

Isolation and Genetic Analysis of Halophilous Bacteria from Marine Sediment Collected at Tianjin Port, China

[Objective] Marine sediment from Tianjin Port has a extremely high salinity.The bacteria which live in such habitats have evolved distinct physiological,metabolic,and morphological characteristics to survive.The objective of this study is to identify all the specific salt-tolerant characteristics and the genetic evolution of the bacteria in the sediment.[Methods] In this study,the total DNA of sediment from Tianjin Port was extracted,and 16S rDNA was used to conduct an analysis of the fauna of sediment bacteria. We also isolated sediment bacteria using beef extract-peptone media with seven different NaCl concentrations (0,0.5%,2%,5%,10%,15%,and 20%),aiming to analyze the dominant species of halophilous bacteria under different salinities.[Results] 1) With each stepwise increase of salinity from 0.5% to 20%,the total number of isolated bacterial colonies decreased.14 strains of bacteria were identified and classified by the16S rDNA sequencing analysis.Of these,four could tolerate 0~2% salinity,four could tolerate 0~5% salinity,one could tolerate 0~15% salinity,and one tolerated within the full 0~20% salinity range.Further four strains were only able to tolerate within a few narrow salinity ranges.such as 5%~10%,10%~15%,10%~20% and 15%~20%;2) The quantity of bacteria strains that can be isolated from the marine sediment decreased with the increase of salinity. Also, the Shannon wiener index and species richness index of marine sediment bacteria decreased significantly from 5% salinity.However,there were no significant differences in the species evenness index;3) When the salinity was 0~10%,the dominant species was Bacillus.When the salinity was 15%, Halomonas was the dominant species.When the salinity was 20%,there were no significant differences in the proportions of these species.[Conclusion] Our results showed that some bacteria could tolerate living conditions with high salinity,and we even found a species which can tolerate a wide range of salinities (0~20%).In further study,it would be valuable to analyze these bacteria's unique physiological and biochemical functions that allow them to adapt to environments with high salinity.It can provide theories to promote the development of microbial population resources in marine sediment and the reclaimation of salinized soil by salt tolerant microorganisms.