南海南部陆坡表层沉积物细菌和古菌多样性

从南海南部陆坡表层沉积物中扩增了细菌和古菌16S rDNA序列,并对克隆子文库进行系统发育分析.细菌序列以变形杆菌(Proteobacteria)居多,其次是浮霉菌(Planctomycete)、酸杆菌(Acidobacteria)和candidate division OP10,另外还有少量铁还原杆菌(Deferrobacteres)、candidate division OP3、OP11、OP8、TM6、疣微菌(Verrucomicrobia)和螺旋体(Spirochaetes).古菌序列分别来自泉古生菌(Crenarchaeota)和广古生菌(Euryarchaeota),以Marine Benthic Group B(MBGB)、MarineCrenarchaeotic Group Ⅰ(MGⅠ)、Marine Benthic Group D(MBGD)和South African Gold Mine Euryarchaeotic Group(SAGMEG)为主.少量序列为C3、甲烷杆菌(Methanobacteriales)和Novel Euryarchaeotic Group(NEG).结果表明海底表层沉积物中有丰富多样的微生物群落.     

洋山深水港海域表层海水中古菌多样性特点

利用DGGE、定量PCR以及16S rRNA基因克隆文库技术对洋山深水港海域表层海水中的古菌多样性组成进行了调查和分析。通过Quantity One软件分析不同样品的DGGE图谱,发现洋山深水港3个不同海域(小洋山港口区、大洋山港口区、中间航道)的古菌群落多样性组成不存在明显的区别;利用定量PCR的方法对3个不同样品中的古菌16S rRNA基因拷贝进行计数,发现3个不同海域的古菌16S rRNA基因拷贝数的数量关系为:大洋山海域((1.69±0.19)×10~6copies/mL)中间航道((2.17±0.20)×10~6copies/mL)小洋山港口区((2.42±0.22)×10~6copies/mL),这说明洋山深水港3个不同海域的古菌群落组成是一致的,只是在数量上略有差异,为对该海域古菌的更深入调查研究提供了便利和数据基础。洋山深水港海域表层海水的古菌16S rRNA基因文库分析表明,古菌由三大门类组成:广古菌门(Euryarchaeota)、泉古菌门(Crenarchaeota)和奇古菌门(Thaumarchaeota)。广古菌门所占比例约为26.8%,泉古菌门约为33.0%,奇古菌门约为40.2%。广古菌门含有2个类群,分别是Mathanobacteriales(10.3%)和Marine GroupⅡ(16.5%);泉古菌门含有1个类群,为Unidentified Crenarchaeotic Group(33.0%);奇古菌门含有1个类群,为Marine GroupⅠ(40.2%)。结果显示,Mathanobacteriales类群和Marine GroupⅡ类群的比例失调,这可能预示着洋山深水港海域存在油污污染及外来微生物物种入侵的风险。     

莫克兰冷泉区沉积物原核微生物群落组成及其环境响应

【目的】冷泉系统广泛存在于大陆边缘地区,其典型特征是在海底渗漏出大量富含以甲烷为主的碳氢化合物和硫化氢等成分的低温流体。冷泉也因其独特的地球化学条件孕育着独特的原核微生物群落结构,然而,原核微生物组成与冷泉环境之间的响应关系却并不清楚。【方法】本文以莫克兰大陆边缘活跃冷泉区沉积物柱状样为研究对象,沿深度剖面分析了沉积物中的CH4以及孔隙水SO42–、H2S浓度等关键地球化学参数,并基于16S rRNA基因高通量测序对冷泉沉积物原核微生物的群落结构及其空间变化进行了系统分析。【结果】根据其硫酸盐-甲烷浓度剖面特征,从上向下,将沉积物垂向剖面划分为硫酸盐还原区(SZ)、硫酸盐-甲烷转换区(SMTZ)和产甲烷区(MZ)。通过原核微生物α多样性与基因定量研究发现,随着深度增加微生物多样性与丰度呈逐渐降低的趋势。16SrRNA基因高通量测序结果表明,SZ中以硫氧化细菌γ-变形菌纲、α-变形菌纲和埃普西隆杆菌门为主,且以硫酸盐为电子受体的与有机质降解相关的原核微生物JS1、绿弯菌门、洛基古菌纲、深古菌纲及底栖古菌纲的相对含量也较高;SMTZ存在较高含量的ANME-1a、ANME-1b与SEEP-S...     

南海Formosa冷泉区沉积物微生物多样性与分布规律研究

【目的】当前对全球冷泉生态系统微生物生态学研究显示，冷泉生态系统中主要微生物类群为参与甲烷代谢的微生物，它们的分布差异与所处冷泉区生物地球化学环境密切相关。但在冷泉区内也存在环境因子截然不同的生境，尚缺乏比较冷泉区内小尺度生境间微生物多样性和分布规律的研究。本研究旨在分析南海Formosa冷泉区内不同生境间微生物多样性差异，完善和理解不同环境因子对冷泉内微生物群落结构的影响。【方法】对采集自南海Formosa冷泉区不同生境(黑色菌席区、白色菌席区和碳酸盐岩区)沉积物样本中古菌和细菌16S rRNA基因进行测序，结合环境因子，比较微生物多样性差异，分析环境因子对微生物分布的影响。【结果】发现在Formosa冷泉内的不同生境中，甲烷厌氧氧化古菌(anaerobic methanotrophic archaea,ANME)是主要古菌类群，占古菌总体相对丰度超过70%；在菌席区ANME-1b和ANME-2a/b是主要ANME亚群，碳酸盐岩区则是ANME-1b。硫酸盐还原菌(sulfate-reducing bacteria,SRB)和硫氧化菌(sulfur-oxidizing bacteria...     

引物应用策略：基于2对古菌16S rRNA基因通用引物对环境样品古菌多样性分析

【目的】找到适宜的16S rRNA基因通用引物应用策略,应对复杂环境微生物多样性调查,尤其目前高速发展的高通量测序技术带来的巨大挑战。【方法】用Oligocheck软件分别将两对应试的古菌16S rRNA基因通用引物与RDP(Ribosomal database project)数据库中古菌16S rRNA基因序列进行匹配比对。用两对应试引物分别构建海洋沉积物样品的古菌16S rRNA基因文库。【结果】软件匹配结果显示引物f109/r958与目的基因的匹配程度高于引物f21/r958。该结果与古菌16S rRNA基因文库RFLP分析、古菌多样性指数分析结果相吻合。数据还表明,2对引物的综合文库能更好满足该沉积物样品的古菌多样性分析。【结论】选用与数据库中目的基因匹配性高的通用引物和多个引物的联合使用,可以有效提高环境样品微生物多样性调查的分辨率。     

基于amoA基因扩增子高通量测序的氨氧化古菌多样性分析方法

【背景】对于环境样品中氨氧化古菌(Ammonia-oxidizing archaea,AOA)多样性的研究,利用amoA功能基因作为分子标记会比16SrRNA基因有更强的特异性和更高的分辨率,能更准确地反映环境样品中氨氧化古菌的种群结构和分布特征。然而,目前对amoA基因扩增子高通量测序的分析存在两大限制因素:一是缺乏相应的amoA基因参考数据库;二是AOA amoA基因在种水平上的相似性阈值未知,分析过程中没有明确的划分种水平操作分类单元(Operational taxonomic unit,OTU)的阈值。【目的】构建基于amoA功能基因序列分析氨氧化古菌多样性的方法,为基于高通量测序的功能微生物多样性分析提供参考。【方法】基于目前已通过分离纯化或富集培养获得的34株氨氧化古菌及功能基因数据库中收录的环境样品amoA基因序列,构建氨氧化古菌amoA基因参考数据库。通过菌株间两两比对获得的amoA基因相似度与16SrRNA基因相似度的相关性分析,确定amoA基因在种水平上的相似性阈值。基于MOTHUR软件平台,利用建立的参考数据库和确定的阈值对南海一个垂直水体剖面样品的amoA基因序列进行多样性分析。【结果】构建了含有26 091条序列信息的古菌amoA基因参考数据库,确定了89%作为分析过程中古菌amoA基因划分种水平OTU的阈值,对南海水体样品氨氧化古菌的多样性分析结果很好地显示了南海不同深度水层水体中氨氧化古菌的种群结构和系统发育关系,有效揭示了南海氨氧化古菌的垂直分布差异。【结论】建立了基于amoA基因高通量测序的氨氧化古菌多样性分析方法,此方法可以有效分析环境样品中氨氧化古菌的多样性。     

海南东寨港红树林不同植被土壤微生物群落结构比较

【目的】比较不同植被下红树林土壤细菌和古菌的多样性及群落结构,认识红树林土壤微生物资源多样性。【方法】直接提取红树林土壤总DNA,采用细菌通用引物27F/1492R和古菌通用引物Arch21F/Arch958R进行PCR扩增,构建细菌和古菌16S rRNA基因文库,对海南东寨港自然保护区秋茄林、无瓣海桑林和无红树林裸滩土壤的细菌和古菌多样性和群落结构进行分析和比较。【结果】3种土壤样品的细菌类群包括变形细菌门(Proteobacteria)等16个类群,其中变形细菌门(Proteobacteria)与绿屈挠菌门(Chloroflexi)是优势类群;古菌包括6个嗜泉古菌界(Crenarchaeota)类群和7个广域古菌界(Euryarchaeota)类群,分别以Marine Benthic Group C、Marine Benthic Group D为优势类群。多样性指数(H’)和物种丰富度指数(Schao1)表明,本地种秋茄林下土壤细菌和古菌的多样性指数最高,外来种无瓣海桑显著低于秋茄林,甚至明显低于相邻无红树林裸滩沉积物;不同植被下土壤细菌和古菌群落结构存在显著差异,秋茄林土壤微生物群落结构和无红树林裸滩沉积物更相似。【结论】红树林土壤微生物类群丰富,不同植被下土壤细菌和古菌多样性和群落结构存在显著差异。     

从宏基因组推测扎龙湿地未培养甲烷古菌Rice Cluster II的代谢途径与可能的盐碱适应性

【背景】湿地是重要的甲烷排放源,因为其中栖息着各种产甲烷古菌。已知未培养甲烷古菌Rice Cluster Ⅱ (RCⅡ)类群广泛分布于低温酸性和北方泥炭藓湿地、淡水湿地及草本沼泽等环境,但它们在低温盐碱湿地中的分布及代谢途径尚未知。【目的】分析扎龙盐碱湿地未培养甲烷古菌RCⅡ类群的多样性、推测产甲烷代谢途径及其潜在的盐碱适应机制。【方法】16S rRNA基因扩增子测序分析扎龙湿地土壤中甲烷古菌群组成;构建16S rRNA基因克隆文库分析扎龙湿地土壤RCⅡ的多样性;宏基因组分析推测RCⅡ古菌编码的产甲烷途径及与耐盐碱相关物质的合成基因。【结果】16SrRNA基因高通量测序发现未培养甲烷古菌的RCⅡ类群占扎龙盐碱湿地总甲烷古菌的13.280%±0.019%;系统发育学分析表明该湿地的RCⅡ由3个分支组成;宏基因组分析组装了2个优势的未培养RCⅡ的基因组,均含完整的氢还原二氧化碳产甲烷途径的基因,并编码海藻糖的转运与合成基因。【结论】扎龙盐碱湿地土壤富含未培养RCⅡ甲烷古菌,推测它们通过氢还原二氧化碳产甲烷,利用细胞内高的海藻糖适应盐碱环境。     

大叶藻(Zostera marina)海草床沉积物细菌和古菌丰度及组成的垂直剖面特征

【背景】海草床是重要的"蓝碳"生态系统,对全球碳汇有重要贡献。海草床沉积物剖面的垂直梯度特征显著,表层呈现氧化态,富含活性有机质,而深层呈还原态,以惰性有机质为主。【目的】探究这种垂直特征如何影响微生物的丰度和群落分布。【方法】利用荧光定量PCR和16SrRNA基因高通量测序等手段,测定了山东荣成天鹅湖大叶藻海草床不同深度(5、10、15、20、25和30 cm)沉积物中细菌和古菌丰度、多样性和群落结构的变化。【结果】细菌和古菌16S rRNA基因拷贝数随深度的增加而降低,在沉积物5cm深处,细菌的16SrRNA基因拷贝数显著高于20cm和30cm层(ANOVA,P0.05)。深度对细菌和古菌α多样性指数没有显著影响(P0.05)。细菌中相对丰度最高的是变形菌门,其次是绿弯菌门,拟杆菌门,浮霉菌门等,其中δ-变形菌和浮霉菌的相对丰度随深度显著增加(P0.05)。古菌群落中深古菌门比例最高,在25cm深处达到70%以上;其次是乌斯菌门、洛基古菌门、广古菌门和奇古菌门等。奇古菌门比例随深度增加而显著降低(P0.05),其他古菌类群在不同深度间差异不显著(P0.05)。【结论】海草床沉积物细菌和古菌的丰度、多样性和群落分布具有明显的垂直特征,这种特征可能受沉积物有机质组成和氧化还原状况影响。     

人肠道梭菌和甲烷马赛球菌协同代谢甜菜碱和胆碱产甲烷研究

【目的】根据人肠道富含胆碱和甜菜碱,同时肠道微生物组中具有裂解胆碱和还原甜菜碱产三甲胺的细菌,以及利用三甲胺产甲烷的古菌,本研究探讨肠道细菌与古菌协同代谢甜菜碱和胆碱产甲烷的可能性。【方法】调查不同年龄段人群粪便中的16S rRNA基因多样性,分析肠道中古菌的菌群组成;利用定量PCR(quantitativePCR,qPCR)定量甲烷马赛球菌(Methanomassiliicoccus)特异的甲醇甲基转移酶基因mtaB和甲烷八叠球菌(Methanosarcina)及细菌的16SrRNA基因拷贝数,分析肠道中甲基营养型产甲烷古菌及总细菌的含量;宏基因组组装基因组(metagenome-assembled genomes, MAGs)分析携带甜菜碱还原酶基因grdH和胆碱裂解酶基因cutC的细菌组成。从粪便中分离代谢甜菜碱及胆碱产生三甲胺的细菌,并与分离自人肠道的甲烷马赛球菌构建共培养物,测定其协同转化甜菜碱和胆碱产甲烷的能力。【结果】年轻人粪便中含有甲烷杆菌科(Methanobacteriaceae,82.16%)的甲烷短杆菌属(Methanobrevibacter,49.18%)和甲烷...     

A distinct freshwater-adapted subgroup of ANME-1 dominates active archaeal communities in terrestrial subsurfaces in Japan

Anaerobic methane-oxidizing archaea (ANME) are known to play an important role in methane flux, especially in marine sediments. The 16S rRNA genes of ANME have been detected in terrestrial freshwater subsurfaces. However, it is unclear whether ANME are actively involved in methane oxidation in these environments. To address this issue, Holocene sediments in the subsurface of the Kanto Plain in Japan were collected for biogeochemical and molecular analysis. The potential activity of the anaerobic oxidation of methane (AOM) (0.38-3.54 nmol cm?3 day?1) was detected in sediment slurry incubation experiments with a (13) CH(4) tracer. Higher AOM activity was observed in low-salinity treatment compared with high-salinity condition (20‰), which supports the adaptation of ANME in freshwater habitats. The 16S rRNA sequence analysis clearly revealed the presence of a distinct subgroup of ANME-1, designated ANME-1a-FW. Phylogenetic analysis of the mcrA genes also implied the presence of the distinct subgroup in ANME-1. ANME-1a-FW was found to be the most dominant active group in the archaeal communities on the basis of 16S rRNA analysis (75.0-93.8% of total archaeal 16S rRNA clones). Sulfate-reducing bacteria previously known as the syntrophic bacterial partners of ANME-1 was not detected. Our results showed that ANME-1a-FW is adapted to freshwater habitats and is responsible for AOM in terrestrial freshwater subsurface environments.     

Characterization of C1-metabolizing prokaryotic communities in methane seep habitats at the Kuroshima Knoll, southern Ryukyu Arc, by analyzing pmoA, mmoX, mxaF, mcrA, and 16S rRNA genes

Samples from three submerged sites (MC, a core obtained in the methane seep area; MR, a reference core obtained at a distance from the methane seep; and HC, a gas-bubbling carbonate sample) at the Kuroshima Knoll in the southern Ryuku arc were analyzed to gain insight into the organisms present and the processes involved in this oxic-anoxic methane seep environment. 16S rRNA gene analyses by quantitative real-time PCR and clone library sequencing revealed that the MC core sediments contained abundant archaea (approximately 34% of the total prokaryotes), including both mesophilic methanogens related to the genus Methanolobus and ANME-2 members of the Methanosarcinales, as well as members of the delta-Proteobacteria, suggesting that both anaerobic methane oxidation and methanogenesis occurred at this site. In addition, several functional genes connected with methane metabolism were analyzed by quantitative competitive-PCR, including the genes encoding particulate methane monooxygenase (pmoA), soluble methane monooxygenase (mmoX), methanol dehydrogenese (mxaF), and methyl coenzyme M reductase (mcrA). In the MC core sediments, the most abundant gene was mcrA (2.5 x 10(6) copies/g [wet weight]), while the pmoA gene of the type I methanotrophs (5.9 x 10(6) copies/g [wet weight]) was most abundant at the surface of the MC core. These results indicate that there is a very complex environment in which methane production, anaerobic methane oxidation, and aerobic methane oxidation all occur in close proximity. The HC carbonate site was rich in gamma-Proteobacteria and had a high copy number of mxaF (7.1 x 10(6) copies/g [wet weight]) and a much lower copy number of the pmoA gene (3.2 x 10(2) copies/g [wet weight]). The mmoX gene was never detected. In contrast, the reference core contained familiar sequences of marine sedimentary archaeal and bacterial groups but not groups specific to C1 metabolism. Geochemical characterization of the amounts and isotopic composition of pore water methane and sulfate strongly supported the notion that in this zone both aerobic methane oxidation and anaerobic methane oxidation, as well as methanogenesis, occur.     

Stratification of Archaeal communities in shallow sediments of the Pearl River Estuary,Southern China

Microorganisms are known to play fundamental roles in the biogeochemical cycling of carbon in the coastal environments. To get to know the composition and ecological roles of the archaeal communities within the sediments of the Pearl River Estuary, Southern China, the diversity and vertical distribution of archaea in a sediment core was reported based on the 16S rRNA and mcrA genes for the first time. Quantitative PCR analysis revealed that archaea were present at 10⁶–10⁷ 16S rRNA gene copies/g (wet weight) in the sediment core, and the proportion of mcrA versus 16S rRNA gene copies varied from 11 to 45%. 16S rRNA gene libraries were constructed and analyzed for the top layer (0–6 cm), middle layer (18–24 cm), sulfate-methane transition zone (SMTZ, 32–42 cm), and bottom layer (44–50 cm) sediments. The results indicated that Miscellaneous Crenarchaeotal Group (MCG) was the main component in the sediments. The MCG archaea could be further divided into six subgroups: MCG-A, B, C, D, E, and F. On the other hand, mcrA sequences from methanogens related to the order Methanomicrobiales and ANME-2 methanotrophs were detected in all sediment layers. Taken together, our data revealed a largely unknown archaeal community in which MCG dominated within the Pearl River estuarine sediments, while methanogens and methane-oxidizing archaea putatively involving in methane metabolism, were also found in the community. This is the first important step towards elucidating the biogeochemical roles of these archaea in the Pearl River Estuary.     

Anaerobic oxidation of methane at different temperature regimes in Guaymas Basin hydrothermal sediments

Anaerobic oxidation of methane (AOM) was investigated in hydrothermal sediments of Guaymas Basin based on δ¹³C signatures of CH₄, dissolved inorganic carbon and porewater concentration profiles of CH₄ and sulfate. Cool, warm and hot in-situ temperature regimes (15–20 °C, 30–35 °C and 70–95 °C) were selected from hydrothermal locations in Guaymas Basin to compare AOM geochemistry and 16S ribosomal RNA (rRNA), mcrA and dsrAB genes of the microbial communities. 16S rRNA gene clone libraries from the cool and hot AOM cores yielded similar archaeal types such as Miscellaneous Crenarchaeotal Group, Thermoproteales and anaerobic methane-oxidizing archaea (ANME)-1; some of the ANME-1 archaea formed a separate 16S rRNA lineage that at present seems to be limited to Guaymas Basin. Congruent results were obtained by mcrA gene analysis. The warm AOM core, chemically distinct by lower porewater sulfide concentrations, hosted a different archaeal community dominated by the two deep subsurface archaeal lineages Marine Benthic Group D and Marine Benthic Group B, and by members of the Methanosarcinales including ANME-2 archaea. This distinct composition of the methane-cycling archaeal community in the warm AOM core was confirmed by mcrA gene analysis. Functional genes of sulfate-reducing bacteria and archaea, dsrAB, showed more overlap between all cores, regardless of the core temperature. 16S rRNA gene clone libraries with Euryarchaeota-specific primers detected members of the Archaeoglobus clade in the cool and hot cores. A V6-tag high-throughput sequencing survey generally supported the clone library results while providing high-resolution detail on archaeal and bacterial community structure. These results indicate that AOM and the responsible archaeal communities persist over a wide temperature range.     

Identification of methyl coenzyme M reductase A (mcrA) genes associated with methane-oxidizing archaea

Phylogenetic and stable-isotope analyses implicated two methanogen-like archaeal groups, ANME-1 and ANME-2, as key participants in the process of anaerobic methane oxidation. Although nothing is known about anaerobic methane oxidation at the molecular level, the evolutionary relationship between methane-oxidizing archaea (MOA) and methanogenic archaea raises the possibility that MOA have co-opted key elements of the methanogenic pathway, reversing many of its steps to oxidize methane anaerobically. In order to explore this hypothesis, the existence and genomic conservation of methyl coenzyme M reductase (MCR), the enzyme catalyzing the terminal step in methanogenesis, was studied in ANME-1 and ANME-2 archaea isolated from various marine environments. Clone libraries targeting a conserved region of the alpha subunit of MCR (mcrA) were generated and compared from environmental samples, laboratory-incubated microcosms, and fosmid libraries. Four out of five novel mcrA types identified from these sources were associated with ANME-1 or ANME-2 group members. Assignment of mcrA types to specific phylogenetic groups was based on environmental clone recoveries, selective enrichment of specific MOA and mcrA types in a microcosm, phylogenetic congruence between mcrA and small-subunit rRNA tree topologies, and genomic context derived from fosmid sequences. Analysis of the ANME-1 and ANME-2 mcrA sequences suggested the potential for catalytic activity based on conservation of active-site amino acids. These results provide a basis for identifying methanotrophic archaea with mcrA sequences and define a functional genomic link between methanogenic and methanotrophic archaea.     

An anaerobic methane-oxidizing community of ANME-1b archaea in hypersaline Gulf of Mexico sediments

Sediments overlying a brine pool methane seep in the Gulf of Mexico (Green Canyon 205) were analyzed using molecular and geochemical approaches to identify geochemical controls on microbial community composition and stratification. 16S rRNA gene and rRNA clone libraries, as well as mcrA gene clone libraries, showed that the archaeal community consists predominantly of ANME-1b methane oxidizers; no archaea of other ANME subgroups were found with general and group-specific PCR primers. The ANME-1b community was found in the sulfate-methane interface, where undersaturated methane concentrations of ca. 100 to 250 microM coexist with sulfate concentrations around 10 mM. Clone libraries of dsrAB genes and bacterial 16S rRNA genes show diversified sulfate-reducing communities within and above the sulfate-methane interface. Their phylogenetic profiles and occurrence patterns are not linked to ANME-1b populations, indicating that electron donors other than methane, perhaps petroleum-derived hydrocarbons, drive sulfate reduction. The archaeal component of anaerobic oxidation of methane is comprised of an active population of mainly ANME-1b in this hypersaline sediment.     

Microbial diversity of hydrothermal sediments in the Guaymas Basin: evidence for anaerobic methanotrophic communities

Microbial communities in hydrothermally active sediments of the Guaymas Basin (Gulf of California, Mexico) were studied by using 16S rRNA sequencing and carbon isotopic analysis of archaeal and bacterial lipids. The Guaymas sediments harbored uncultured euryarchaeota of two distinct phylogenetic lineages within the anaerobic methane oxidation 1 (ANME-1) group, ANME-1a and ANME-1b, and of the ANME-2c lineage within the Methanosarcinales, both previously assigned to the methanotrophic archaea. The archaeal lipids in the Guaymas Basin sediments included archaeol, diagnostic for nonthermophilic euryarchaeota, and sn-2-hydroxyarchaeol, with the latter compound being particularly abundant in cultured members of the Methanosarcinales. The concentrations of these compounds were among the highest observed so far in studies of methane seep environments. The delta-(13)C values of these lipids (delta-(13)C = -89 to -58 per thousand) indicate an origin from anaerobic methanotrophic archaea. This molecular-isotopic signature was found not only in samples that yielded predominantly ANME-2 clones but also in samples that yielded exclusively ANME-1 clones. ANME-1 archaea therefore remain strong candidates for mediation of the anaerobic oxidation of methane. Based on 16S rRNA data, the Guaymas sediments harbor phylogenetically diverse bacterial populations, which show considerable overlap with bacterial populations of geothermal habitats and natural or anthropogenic hydrocarbon-rich sites. Consistent with earlier observations, our combined evidence from bacterial phylogeny and molecular-isotopic data indicates an important role of some novel deeply branching bacteria in anaerobic methanotrophy. Anaerobic methane oxidation likely represents a significant and widely occurring process in the trophic ecology of methane-rich hydrothermal vents. This study stresses a high diversity among communities capable of anaerobic oxidation of methane.     

Comparative analysis of methane-oxidizing archaea and sulfate-reducing bacteria in anoxic marine sediments

The oxidation of methane in anoxic marine sediments is thought to be mediated by a consortium of methane-consuming archaea and sulfate-reducing bacteria. In this study, we compared results of rRNA gene (rDNA) surveys and lipid analyses of archaea and bacteria associated with methane seep sediments from several different sites on the Californian continental margin. Two distinct archaeal lineages (ANME-1 and ANME-2), peripherally related to the order Methanosarcinales, were consistently associated with methane seep marine sediments. The same sediments contained abundant (13)C-depleted archaeal lipids, indicating that one or both of these archaeal groups are members of anaerobic methane-oxidizing consortia. (13)C-depleted lipids and the signature 16S rDNAs for these archaeal groups were absent in nearby control sediments. Concurrent surveys of bacterial rDNAs revealed a predominance of delta-proteobacteria, in particular, close relatives of Desulfosarcina variabilis. Biomarker analyses of the same sediments showed bacterial fatty acids with strong (13)C depletion that are likely products of these sulfate-reducing bacteria. Consistent with these observations, whole-cell fluorescent in situ hybridization revealed aggregations of ANME-2 archaea and sulfate-reducing Desulfosarcina and Desulfococcus species. Additionally, the presence of abundant (13)C-depleted ether lipids, presumed to be of bacterial origin but unrelated to ether lipids of members of the order Desulfosarcinales, suggests the participation of additional bacterial groups in the methane-oxidizing process. Although the Desulfosarcinales and ANME-2 consortia appear to participate in the anaerobic oxidation of methane in marine sediments, our data suggest that other bacteria and archaea are also involved in methane oxidation in these environments.     

Microbial Diversity of Hydrothermal Sediments in the Guaymas Basin: Evidence for Anaerobic Methanotrophic Communities

Microbial communities in hydrothermally active sediments of the Guaymas Basin (Gulf of California, Mexico) were studied by using 16S rRNA sequencing and carbon isotopic analysis of archaeal and bacterial lipids. The Guaymas sediments harbored uncultured euryarchaeota of two distinct phylogenetic lineages within the anaerobic methane oxidation 1 (ANME-1) group, ANME-1a and ANME-1b, and of the ANME-2c lineage within the Methanosarcinales, both previously assigned to the methanotrophic archaea. The archaeal lipids in the Guaymas Basin sediments included archaeol, diagnostic for nonthermophilic euryarchaeota, and sn-2-hydroxyarchaeol, with the latter compound being particularly abundant in cultured members of the Methanosarcinales. The concentrations of these compounds were among the highest observed so far in studies of methane seep environments. The δ-¹³C values of these lipids (δ-¹³C = −89 to −58‰) indicate an origin from anaerobic methanotrophic archaea. This molecular-isotopic signature was found not only in samples that yielded predominantly ANME-2 clones but also in samples that yielded exclusively ANME-1 clones. ANME-1 archaea therefore remain strong candidates for mediation of the anaerobic oxidation of methane. Based on 16S rRNA data, the Guaymas sediments harbor phylogenetically diverse bacterial populations, which show considerable overlap with bacterial populations of geothermal habitats and natural or anthropogenic hydrocarbon-rich sites. Consistent with earlier observations, our combined evidence from bacterial phylogeny and molecular-isotopic data indicates an important role of some novel deeply branching bacteria in anaerobic methanotrophy. Anaerobic methane oxidation likely represents a significant and widely occurring process in the trophic ecology of methane-rich hydrothermal vents. This study stresses a high diversity among communities capable of anaerobic oxidation of methane.