长年耕作对北方旱作麦田土壤细菌群落结构及理化性质的影响

为探究旱作麦田长期耕作对不同土层细菌群落结构的影响及其与土壤理化性质的关系,于2016~2021年在山西农业大学闻喜旱地小麦试验示范基地开展长期定位试验,研究夏闲期免耕（NT）、深松（ST）和深翻（DP）这3种耕作方式对不同土层土壤理化性质,细菌群落α、β多样性,细菌门和属优势物种及差异物种的影响,并采用PICRUSt2预测其代谢功能.结果表明,旱作麦田连续5a深松和深翻较免耕显著提高了20~40 cm土层土壤含水量,显著降低了0~20 cm土层土壤有机碳含量;深松较深翻显著提高了0~20 cm土层土壤含水量、土壤有机碳、可溶性有机碳和可溶性有机氮含量.深松和深翻较免耕可提高0~40 cm土层土壤细菌群落的α多样性,且深松高于深翻.深松和深翻较免耕显著提高了0~20 cm土层中酸杆菌门、硝化螺旋菌门和20~40 cm土层中酸杆菌门、绿弯菌门、芽单胞菌门、Rokubacteria门、GAL15门和硝化螺旋菌门的相对丰度;显著提高了0~20 cm土层硝化螺旋菌属和20~40 cm土层Rubrobacter属和链霉菌属的相对丰度.深松较深翻显著提高了0~40 cm土层酸杆菌门、芽单胞菌门的相对丰度.冗余分析表明,0~20 cm土层的土壤有机碳、可溶性有机碳和可溶性有机氮含量对放线菌门和牙殖球菌属产生正向效应,且深松下0~40 cm土层的土壤含水量对酸杆菌门、绿弯菌门和芽单胞菌门产生正向效应.PICRUSt2预测结果表明,深松和深翻较免耕显著提高了20~40 cm土层细菌群落的氨基酸代谢和辅酶维生素代谢的相对丰度,但降低了脂质代谢的相对丰度;深松较深翻显著提高了0~40 cm土层细菌群落的氨基酸代谢和0~20 cm土层其他氨基酸代谢的相对丰度.总之,旱地麦田夏闲期深松或深翻均可提高土壤含水量、土壤细菌群落的α多样性及细菌群落的代谢能力,深松还可提高酸杆菌门和芽单胞菌门的相对丰度,并提高细菌群落的氨基酸代谢能力,从而提高了土壤可溶性有机碳、氮含量.     

密云水库入库河流微生物群落演替对氮素形态转化的影响

密云水库是北京市重要的地表饮用水源地,但近年来,密云水库库区及入库河流中的总氮（TN）浓度呈现连年上升的趋势.以密云水库上游典型入库河流牤牛河为例,考察各形态氮素变化的空间分布规律,并从微生物群落组成和功能预测的视角,解析氮素形态的转化,以期为密云水库的氮污染治理提供科学依据.结果表明,密云水库上游除TN外,其余水质理化指标均满足我国地表水环境质量标准（GB 3838-2002）的Ⅱ类标准.入库河流TN浓度显著高于库区（P<0.05）,且以NO₃^--N为主,占比为77.7%~92.9%.半城子水库库区的C/N较高,有助于反硝化脱氮的发生,表现出一定自净能力.牤牛河水体和底质中微生物群落结构具有显著差异,呈现一定的空间分布特征,高NO₃^--N浓度是影响微生物群落结构演替的主要环境因子.牤牛河中存在大量硝化和反硝化功能微生物,反硝化菌相对丰度高于硝化菌,且均呈现出底质略高于水体的特点.牤牛河优势硝化菌和反硝化菌分别为Nitrosopumilus和Pseudomonas.PICRUSt2功能预测结果表明,牤牛河微生物氮代谢以NO₃^--N还原模块为主,且主要发生于水体中;硝化过程的功能基因在水体中的丰度最高,主要为narGH;而参与NO₃^--N还原反应的主要功能基因为底质中的异养反硝化菌（DNRA）所携带的nirBD,而反硝化模块的功能基因主要为nirK.     

汞矿区周边农田土壤微生物群落结构特征及其环境驱动因子

为探究汞矿区周边农田土壤微生物群落结构特征及其与环境驱动因子关系,以铜仁汞（Hg）矿区周边（碧江区坝黄镇、石阡县花桥镇、江口县凯德镇和碧江区川硐镇,分别用BJ、SQ、JK和TR表示）农田土壤为研究对象,分析了土壤理化性质、Hg污染状况、酶活性以及微生物群落结构特征.采用冗余分析（RDA）和相关性网络分析了土壤微生物群落结构与环境因子互作关系.结果表明,研究区土壤存在一定程度的Hg污染,其中,JK和TR属于轻度污染,SQ和BJ属于偏中度污染;TR存在中等潜在生态风险,BJ和JK存在强潜在生态风险,SQ存在很强潜在生态风险.研究区土壤的主要细菌优势菌群包括：变形菌门（Proteobacteria）、放线菌门（Actinobacteria）、酸杆菌门（Acidobacteria）和绿弯菌门（Chloroflexi）;主要真菌优势菌群包括：子囊菌门（Ascomycota）、担子菌门（Basidiomycota）和被孢霉门（Mortierellomycota）.RDA分析表明,pH、蔗糖酶（SC）和过氧化氢酶（CAT）活性是土壤细菌群落结构组成的主要环境因子,pH、碱解氮（AN）、速效钾（AK）、HCl-Hg、酸性磷酸酶（ACP）和脲酶（URE）活性是土壤真菌群落结构组成的主要环境因子.相关性网络分析表明,pH、AP、HCl-Hg、SC、ACP和CAT是影响土壤Proteobacteria、Acidobacteria、Actinobacteria、Chloroflexi、厚壁菌门（Firmicutes）、棒状杆菌门（Rokubacteria）和浮霉菌门（Planctomycetes）等细菌群落结构的主要环境因子;而AK、pH、TN、AP、AN、ACP、URE和SC活性是影响土壤Ascomycota、Basidiomycota、Mortierellomycota、球囊菌门（Glomeromycota）、壶菌门（Chytridiomycota）、红藻门（Rozellomycota）、梳霉门（Kickxellomycota）和Mucoromycota （毛霉门）等真菌群落结构的主要环境因子.     

投加颗粒活性炭和二氧化锰对剩余污泥厌氧消化的影响

厌氧系统添加碳和金属纳米材料是强化厌氧消化的有效策略.为考察投加GAC和MnO₂对剩余污泥厌氧消化过程的影响,设置了空白组（R0）、GAC组（R1）、MnO₂组（R2）以及GAC/MnO₂组（R3）4组间歇实验,研究GAC和MnO₂的投加对剩余污泥厌氧消化效率、微生物活性和微生物群落结构的影响.结果表明,反应器运行28 d后,与R0相比,R1和R3的产CH₄速率分别提高了68.18%和51.35%,R2的产CH₄量降低了21.25%.GAC和MnO₂的单独或者混合投加,对厌氧发酵过程均有促进作用.Mn²⁺与剩余污泥释放的磷酸盐生成磷酸盐沉淀对厌氧代谢通道的阻塞作用,造成R2产CH₄效率变低.GAC优良导电性、吸附能力和MnO₂/Mn²⁺的催化作用是R3产CH₄效率增强的主要原因.正常代谢条件下,投加GAC、MnO₂和GAC/MnO₂均可以提高污泥厌氧消化系统微生物活性.微生物群落分析表明,GAC和MnO₂促进了产甲烷菌Methanobacterium和Methanosaeta的富集,强化了发酵细菌和产甲烷菌的种间电子传递,促进了剩余污泥厌氧发酵过程和CH₄的产生.     

分层型水库水体好氧不产氧光合细菌时空演替特征

好氧不产氧光合细菌（aerobic anoxygenic photosynthesis bacteria,AAPB）以多样的群落结构及独特的代谢功能在水体物质循环中扮演着重要角色.基于实时荧光定量PCR及Illumina MiSeq高通量DNA测序技术研究金盆水库水体中AAPB丰度及群落结构时空演替特征,结合冗余分析揭示环境因子对其群落结构影响规律.结果表明,金盆水库水体AAPB丰度（以pufM基因计）变化范围为（6.70±0.43）×10³~（2.69±0.15）×10⁴ copies·mL^-1,最大值出现于10月,且随水深增加而减小.样本主要归为19个属（除未分类菌属外）,优势AAPB菌属包括慢生根瘤菌属（Bradyrhizobium sp.）和甲烷菌属（Methylobacterium sp.）,两者隶属α-变形菌（α-Proteobacteria）,其中慢生根瘤菌属（Bradyrhizobium sp.）占比于11月最高,高达60%以上（除10 m外）,此外也发现了以低比例存在的红长命菌属（Rubrivivax sp.）,隶属β-变形菌（β-Proteobacteria）.AAPB不同属间存在较强的互作关系,如红杆菌属（Rhodobacter sp.）与小红卵菌属（Rhodovulum sp.）呈正相关,噬氢菌属（Hydrogenophaga sp.）与慢生根瘤菌属（Bradyrhizobium sp.）呈负相关等.AAPB种群结构组成及分布差异显著,主要受T、TN、NO₃^--N和光照强度影响,且由环境因素综合调控.如10月水深0、5和15 m水体AAPB种群结构受水温（T）、总氮（TN）和总磷（TP）显著影响,12月水深5 m水体AAPB种群结构受光照强度、pH、溶解氧（DO）和叶绿素a（Chla）显著影响等.研究结果对解析分层型水库水体AAPB丰度和多样性的时空变化特征具有指导意义,并为探索AAPB种群结构的水环境驱动因素提供理论依据.     

杭州市产业结构与环境污染间的灰色关联度分析研究

文章运用灰色关联分析方法,分别以经济发展指标GDP和环境污染指标废气、废水和固废排放量为参考序列,以产业发展经济数据为比较序列,进行灰色关联度分析,结果发现,杭州现有产业结构初步适应了经济与环境相协调的发展理念,但是有些部门产业或行业仍对环境的污染产生着重要影响。     

Abundance and diversity of ammonia-oxidizing archaea in response to various habitats in Pearl River Delta of China, a subtropical maritime zone

Ammonia-oxidizing archaea (AOA) are widely considered key to ammonia oxidation in various environments. However, little work has been conducted to simultaneously investigate the abundance and diversity of AOA as well as correlations between archaeal amoA genotypes and environmental parameters of different ecosystems at one district. To understand the abundance, diversity, and distribution of AOA in Pearl River Delta of China in response to various habitats, the archaeal amoA genes in soil, marine, river, lake, hot spring and wastewater treatment plant (WWTP) samples were investigated using real-time fluorescent quantitative PCR and clone libraries. Our analyses indicated that the diversity of AOA in various habitats was different and could be clustered into five major clades, i.e., estuary sediment, marine water/sediment, soil, hot spring and Cluster 1. Phylogenetic analyses revealed that the structure of AOA communities in similar ecological habitats exhibited strong relation. The canonical correspondence method indicated that the AOA community structure was strongly correlated to temperature, pH, total organic carbon, total nitrogen and dissolved oxygen variables. Assessing AOA amoA gene copy numbers, ranging from 6.84×10⁶ to 9.45×10⁷ copies/g in dry soil/sediment, and 6.06×10⁶ to 2.41×10⁷ copies/L in water samples, were higher than ammonia-oxidizing bacteria (AOB) by 1-2 orders of magnitude. However, AOA amoA copy numbers were much lower than AOB in WWTP activated sludge samples. Overall, these studies suggested that AOA may be a major contributor to ammonia oxidation in natural habitats but play a minor role in highly aerated activated sludge. The result also showed the ratio of AOA to AOB amoA gene abundance was positively correlated with temperature and less correlated with other environmental parameters. New data from our study provide increasing evidence for the relative abundance and diversity of ammonia-oxidizing archaea in the global nitrogen cycle.     

Absolute dominance of hydrogenotrophic methanogens in full-scale anaerobic sewage sludge digesters

Anaerobic digestion （AD） is gaining increasing attention due to the ability to covert organic pollutants into energy-rich biogas and, accordingly, growing interest is paid to the microbial ecology of AD systems. Despite extensive efforts, AD microbial ecology is still limitedly understood, especially due to the lack of quantitative information on the structures and dynamics of AD microbial communities. Such knowledge gap is particularly pronounced in sewage sludge AD processes although treating sewage sludge is among the major practical applications of AD. Therefore, we examined the microbial communities in three full-scale sewage sludge digesters using qualitative and quantitative molecular techniques in combination： denaturing gradient gel electrophoresis （DGGE） and real-time polymerase chain reaction （PCR）. Eight out of eleven bacterial sequences retrieved from the DGGE analysis were not affiliated to any known species while all eleven archaeal sequences were assigned to known methanogen species. Quantitative real-time PCR analysis revealed that, based on the 16S rRNA gene abundance, the hydrogenotrophic order Methanomicrobiales is the most dominant methanogen group （〉 94% of the total methanogen population） in all digesters. This corresponds well to the prevailing occurrence of the DGGE bands related to Methanolinea and Methanospirillum, both belonging to the order Methanomicrobiales, in all sludge samples. It is therefore suggested that hydrogenotrophic methanogens, especially Methanomicrobiales strains, are likely the major players responsible for biogas production in the digesters studied. Our observation is contrary to the conventional understanding that aceticlastic methanogens generally dominate methanogen communities in stable AD environments, suggesting the need for further studies on the dominance relationship in various AD systems.     

腐蚀损伤对典型铝合金结构疲劳寿命的影响研究

目的研究严酷服役条件下飞机结构的寿命衰减问题。方法以飞机关键结构模拟件为研究对象,基于编制的某机场环境加速试验谱进行当量加速腐蚀试验,采用MTS810材料试验系统进行预腐蚀后的疲劳试验。结果通过对试验结果的分析,确定了关键结构疲劳寿命腐蚀影响系数与腐蚀损伤尺寸之间的对应关系。结论关键结构腐蚀损伤宽度与疲劳寿命腐蚀影响系数相关性最好。     

芦芽山华北落叶松林土壤剖面细菌群落分布格局

微生物群落是维持森林土壤生态系统结构和功能的关键组分.细菌群落在土壤剖面上的垂直分布对森林土壤碳库和土壤营养循环具有重要影响.利用Illumina MiSeq高通量测序技术,分析了芦芽山华北落叶松(Larix principis-rupprechtii)林腐殖质层及0～80 cm土层细菌群落特征,探究影响土壤剖面细菌群落结构的驱动机制.结果表明,细菌群落的α多样性随土壤深度的增加显著单调降低,群落结构在土壤剖面上有显著差异.放线菌门(Actinobacteria)、变形菌门(Proteobacteria)的相对丰度随着土壤深度增加而降低;酸杆菌门(Acidobacteria)和绿弯菌门(Chloroflexi)的相对丰度随土层深度的增加而增加.RDA分析结果表明,土壤NH⁺₄、 TC、 TS、 WCS、 pH、 NO^-₃和TP是决定土壤剖面细菌群落结构的重要因子,其中pH的影响最为显著.分子生态网络分析表明,凋落物层和亚表层土壤(10～20 cm)细菌群落的复杂性较高,深层(40～80 cm)土壤细...