冲绳海槽热液区可培养硫氧化细菌多样性及其硫氧化特性

冲绳海槽热液区独特的地质环境孕育了特殊的生物群落,硫氧化细菌作为生物地球化学循环的重要参与者在热液生态系统中发挥着至关重要的作用。【目的】通过硫氧化菌株的分离培养揭示冲绳海槽热液区可培养硫氧化细菌的多样性和硫氧化活性。【方法】采用多种培养基对冲绳海槽热液区不同沉积物样品中的硫氧化细菌进行富集培养和分离纯化;利用16S rRNA基因序列确定硫氧化细菌的分类地位并进行系统发育分析;采用碘量法对典型硫氧化菌株硫氧化活性进行检测。【结果】本研究从冲绳海槽热液区样品中共分离鉴定85株硫氧化细菌,分属于α-变形菌纲、γ-变形菌纲、放线菌门和厚壁菌门,优势属为氢弧菌属(Hydrogenovibrio)、拉布伦氏菌属(Labrenzia)、深海海旋菌属(Thalassospira)和海杆状菌属(Marinobacter)。硫氧化活性检测结果表明,7株典型硫氧化菌株对硫代硫酸钠的降解活性介于31%–100%之间,其中泰坦尼克号盐单胞菌SOB56 (Halomonas titanicae SOB56)、南极海杆状菌SOB93(Marinobacter antarcticus SOB93)、印度硫氧化粗杆菌SOB107 (Thioclava indica SOB107)和嗜温氢弧菌CJG136 (Hydrogenovibrio thermophiles CJG136)可以完全降解硫代硫酸钠。【结论】冲绳海槽热液区可培养硫氧化细菌的多样性丰富,为研究该热液区的硫循环过程提供了实验材料和理论基础,多种硫氧化活性菌株的获得极大地丰富了菌种资源,为探究深海热液区硫循环的能量代谢途径和分子机制奠定基础。     

化能自养硫氧化细菌Halothiobacillus sp.LS2介导的以乙炔为电子受体的硫氧化反应

【目的】探究化能自养硫氧化细菌Halothiobacillus sp. LS2介导的以乙炔为电子受体的厌氧硫氧化反应。【方法】稀释涂布法测定细胞生长情况,离子色谱仪测试硫氧化动力学中SO_4~(2–)和S_2O_3~(2–)以及基于相对荧光定量法的基因表达分析。【结果】尽管菌株LS2在以氧气为电子受体时的最大反应速率V_(max)更高,但在厌氧条件下且以乙炔为电子受体时,菌株LS2的生长量是氧气为电子受体时的2倍,且硫氧化酶基因soxB的表达量显著高于氧气作为电子受体时。【结论】菌株LS2不仅可以以乙炔为电子受体完成厌氧硫氧化反应,且这一代谢过程的产能效率较有氧硫氧化过程更高。本研究首次发现了微生物介导的以乙炔为电子受体的厌氧硫氧化反应,对丰富硫的生物地球化学循环理论有积极意义。     

深海热液生物共附生可培养硫氧化细菌的多样性及硫氧化特性

[背景]深海热液环境中存在大量H2S及含硫化合物,许多微生物与大型生物形成了紧密的共生体系,例如硫氧化细菌,它们利用其独特的代谢体系协助宿主更好地适应极端环境,但目前尚未对热液底栖生物共附生的硫氧化细菌进行培养鉴定和功能分析.[目的]了解深海热液生物共附生硫氧化细菌的种群特征和功能特征,筛选出深海热液生物共附生微生物中...     

一株嗜盐嗜碱硫氧化菌的筛选、鉴定及硫氧化特性

【背景】沼气和天然气等清洁能源中往往会含有一定量的硫化氢,硫化氢的存在不仅污染环境,而且对人类危害很大。【目的】以硫代硫酸钠为唯一硫源从巴丹吉林沙漠盐碱湖岸边沉积物中分离筛选得到一株硫氧化菌BDL05,并研究其硫氧化特性。【方法】通过形态观察、生理生化特征及16S rRNA基因序列分析对硫氧化菌BDL05进行鉴定。【结果】菌株BDL05为革兰氏阴性菌,弧状,其16S rRNA基因序列与Thiomicrospira microaerophila ASL 8-2的相似性达99.8%,将其命名为Thiomicrospira microaerophila BDL05。该菌氧化硫代硫酸盐的最适pH为9.3,最适总钠盐浓度为0.8mol/L,在以硫化钠为硫源的气升式反应器中单质硫的生成率为94.7%,生成速率为3.0 mmol/(L·h)。【结论】菌株Thiomicrospira microaerophila BDL05为嗜盐嗜碱硫氧化菌,其耐盐耐碱性较强,比生长速率快,硫化钠氧化能力较强,是一株在气体生物脱硫方面具有应用价值的菌株。     

西藏热泉沉积物的硫氧化细菌多样性及其影响因素

【目的】探究西藏热泉沉积物中硫氧化细菌群落多样性及其环境影响因素。【方法】选取西藏5个地热区的25个热泉样点,现场测量各采样点的水体理化参数,并采集热泉水和沉积物样品。通过功能基因(硫代硫酸盐水解酶编码基因:soxB)克隆文库分析方法,研究沉积物样品中硫氧化细菌群落的组成和多样性,并统计分析其与环境参数之间的相关性。【结果】克隆文库分析结果显示,西藏热泉沉积物样品中的硫氧化细菌主要分属于α-Proteobacteria、β-Proteobacteria和γ-Proteobacteria纲。研究样品中的硫氧化菌群落香农指数与溶解有机碳的浓度(R=0.489,P0.05)呈显著正相关。另外,统计发现西藏各热泉之间的硫氧化菌群落组成差异较大,其优势硫氧化细菌种群差异明显,大多数样点的优势硫氧化细菌种群为β-Proteobacteria,少量样点以α-Proteobacteria和γ-Proteobacteria为主。Mantel检验结果显示,西藏热泉样品中的硫氧化细菌群落组成与温度、硫化物、电导率、海拔、总溶解固体和pH显著(P0.05)相关。【结论】西藏热泉沉积物中的硫氧化细菌群落广泛分布,且主要以变形菌门为主。地理隔离和理化差异导致了热泉沉积物样品间的硫氧化菌群落组成差异。     

一株分离自网箱养殖区沉积物的硫氧化菌B1-1的鉴定及其硫氧化特性

【背景】海水网箱养殖是一种高密度、高投饵的人工养殖方式,其产生的硫化物污染严重影响了海水养殖业的经济效益及可持续发展。【目的】鉴定从网箱养殖区沉积物中分离得到的硫氧化菌B1-1并研究其硫氧化特性,为利用生物技术修复网箱养殖环境提供理论依据。【方法】通过形态观察、生理生化特征及16S rRNA基因序列分析对硫氧化菌B1-1进行鉴定;通过摇床培养对该菌株氧化硫代硫酸盐的最适培养条件(pH、温度、底物浓度、外加碳源、外加氮源、金属离子)进行研究。【结果】该菌株被鉴定为HalothiobacillushydrothermalisB1-1。菌株B1-1生物氧化硫代硫酸盐的最适pH为8.0,最适生长温度为30°C,最适底物浓度为5.0g/L;外加碳源对该菌株氧化能力无显著影响,外加铵盐(硫酸铵或草酸铵)可以将延滞期缩短至12 h,添加Mg~(2+)可以显著提高菌株的氧化能力,氧化率达100%。【结论】Halothiobacillus hydrothermalisB1-1耐盐性较强,对硫代硫酸盐氧化率高,可作为修复受硫化物污染网箱养殖环境的潜在菌株资源。     

硫氧化菌种脱除硫化物生成单质硫限制性因素优化

【目的】针对硫氧化菌种较为特殊的生化特性,优选其氧化硫化物生成单质硫过程的相关限制性因素,以提高该类菌种生成单质硫效率。【方法】采用一株典型脱硫菌Thermithiobacillus tepidarius JNU-2(T.tepidarius JNU-2)氧化硫化物生成单质硫。研究该菌株在以Na2S2O3为能源底物时的培养特性和脱硫性能,并结合单因素实验对菌株氧化硫化物生成单质硫的限制性因素进行优选。【结果】T.tepidarius JNU-2在以Na2S2O3为唯一能源底物培养时的μmax为0.207 h-1,最终生物量为4.0×106 cells/m L。98%的Na2S2O3在24 h时被消耗殆尽,此时单质硫产量达到最大值为0.8 g/L。随后单质硫逐渐被氧化利用,最终稳定在0.2 g/L。经过对该过程主要限制性因素进行单因素实验优化,确定最佳碳氮源、Mg SO4、Fe SO4和能源底物条件分别为:CO2、NH4Cl0.5 g/L、Mg SO4 0.5 g/L、Fe SO4 0.1 g/L和Na2S2O3 15.0 g/L。优化后的氧化Na2S2O3生成单质硫过程的最大生物量可达4.8×106 cells/m L,单质硫产量提升至1.14 g/L。相较于未优化之前,单质硫的产量提高了42.5%。【结论】优化该过程主要限制性因素可有效提高化能自养型T.tepidarius JNU-2氧化硫化物生成单质硫效率。     

三峡库区水体中硫氧化菌的群落多样性

【目的】探究三峡库区干流和支流水体硫氧化菌群落组成和多样性及其与水体理化性质的相关性。【方法】于2017年3月在三峡库区支流和干流共选取9个采样点,测量各采样点水体理化参数,针对水体样品的sox B基因进行系统发育分析、聚类分析和多样性分析,并分析水体理化性质与硫氧化菌群落组成和多样性的相关性。【结果】克隆文库分析显示,本研究的三峡库区水体样品中硫氧化菌分属于α-Proteobacteria和β-Proteobacteria纲,其中β-Proteobacteria的硫氧化菌是群落构成主体,在干流和支流的采样点中相对丰度均高于95.6%。聚类分析和主坐标分析(PCo A)显示,各支流采样点之间以及支流样点和其对应干流样点之间的硫氧化菌群落构成差异较大,而干流采样点间硫氧化菌群落构成差异较小。Mantel检验结果显示,硫氧化菌群落组成与水体的温度、盐度、溶氧量、藻含量和p H等理化参数呈显著(P0.05)相关。Pearson相关性分析显示硫氧化菌的群落多样性与藻含量和DIC呈现显著负相关。【结论】三峡库区支流和干流水体中硫氧化菌主要由β-Proteobacteria纲构成,库区干流水体中硫氧化菌群落构成较为相似,而不同支流水体中的硫氧化菌群落构成差异较明显,并且支流和对应干流交汇处的水体中硫氧化菌群落组成差异明显,水体理化性质是导致这一差异的重要原因之一。     

一株嗜酸硫杆菌M4-422-6的分离及其全基因组测序和比较基因组学分析

【目的】开展具有硫氧化能力的嗜酸硫杆菌属(Acidithiobacillus)的分离及其比较基因组学分析,不仅可以丰富硫氧化细菌菌种资源,而且有助于加深理解嗜酸硫杆菌的分子进化与生态适应机制。【方法】利用以硫代硫酸钠为唯一能源的培养基分离具有硫氧化能力的细菌;利用Illumina HiSeq X和Oxford Nanopore测序平台对一株嗜酸硫杆菌M4-422-6进行全基因组测序;利用相关生物信息学分析软件对原始数据进行组装和基因组注释,并与一株亲缘关系最近的菌株Igneacidithiobacillus copahuensis VAN18-1进行比较基因组学分析。【结果】分离获得一株具有硫氧化能力的嗜酸硫杆菌M4-422-6。基因组注释结果显示,菌株M4-422-6基因组由1个染色体和2个质粒组成,基因组大小为2 917 823 bp,G+C含量为58.54%,共编码2 925个蛋白。16S rRNA基因和基因组系统发育树显示,菌株M4-422-6代表嗜酸硫杆菌属的一个潜在新种。功能基因注释结果显示,菌株Acidithiobacillus sp. M4-422-6拥有与菌株特性相关的众多基因,包括硫氧化相关基因、CO₂固定相关基因和耐酸相关基因。比较基因组学分析发现,虽然菌株M4-422-6与VAN18-1的亲缘关系最近,但两者仍拥有众多的差异基因,主要包括噬菌体抗性相关基因和移动元件编码基因。【结论】菌株M4-422-6代表嗜酸硫杆菌属的一个潜在新种,该菌株具有同种内菌株所不具有的特有基因,并据此推测嗜酸硫杆菌种内分化可归因于对特定生态位的适应。     

罗氏沼虾(Macrobrachium rosenbergii)养殖池塘沉积物中细菌、硫酸盐还原菌和硫氧化菌的垂直分布特征

沉积物中微生物介导的硫循环在有机物分解和养分循环中发挥重要作用,但目前我们对水产养殖生态系统中的参与硫酸盐还原和硫氧化过程的微生物多样性及其调控机制仍知之甚少。【目的】探究硫酸盐还原菌(sulfate-reducing bacteria,SRB)和硫氧化菌(sulfur-oxidizing bacteria,SOB)的垂直分布特征及其主要的环境驱动因素。【方法】本研究利用高通量测序和荧光定量PCR (qPCR)分析了罗氏沼虾(Macrobrachium rosenbergii)养殖池塘沉积物表层(0–1 cm)、中层(10–11 cm)和底层(20–21 cm)中的细菌、SRB和SOB的丰度、多样性和群落组成。【结果】细菌(16S rRNA)、硫酸盐还原菌(dsrB)和硫氧化菌(soxB)的基因拷贝数呈现着从表层到中层急剧骤降的趋势(ANOVA,P<0.05),但中层和底层样品之间的差异却并不显著(P>0.05),以及α多样性分析显示3个群体的物种丰富度和均匀度都随深度而逐步降低,这都说明硫循环过程主要发生于沉积物的表层。γ-、δ-和β-变形菌分别是细菌、SRB和SOB的优势类群;其中SRB以Desulfobacca属和脱硫八叠球菌属(Desulfosarcina)为主,前者在表层有着最低的比重,而后者却与之相反;硫杆菌(Thiobacillus)作为细菌和SOB的优势属,更广泛地分布于中层沉积物中。RDA分析和Mantel检验揭示了影响细菌群落的主要环境因子是NO₃^–、SO₄^2–、TOC和TON,而SRB的群落变异主要是由As、TON、NO₃^–和Pb所驱动,以及SOB的群落变化则主要响应了TC、NO₂^–、NH₄⁺和TON浓度。【结论】养殖池塘底栖的细菌、SRB和SOB的丰度、多样性和群落结构的垂直分布特征可能受到多种环境因素共同的影响。     

Bacteria dominate the ammonia-oxidizing community in a hydrothermal vent site at the Mid-Atlantic Ridge of the South Atlantic Ocean

Ammonia oxidation is the first and rate-limiting step of nitrification, which is carried out by two groups of microorganisms: ammonia-oxidizing bacteria (AOB) and the recently discovered ammonia-oxidizing archaea (AOA). In this study, diversity and abundance of AOB and AOA were investigated in five rock samples from a deep-sea hydrothermal vent site at the Mid-Atlantic Ridge (MAR) of the South Atlantic Ocean. Both bacterial and archaeal ammonia monooxygenase subunit A (amoA) gene sequences obtained in this study were closely related to the sequences retrieved from deep-sea environments, indicating that AOB and AOA in this hydrothermal vent site showed typical deep ocean features. AOA were more diverse but less abundant than AOB. The ratios of AOA/AOB amoA gene abundance ranged from 1/3893 to 1/242 in all investigate samples, indicating that bacteria may be the major members responding to the aerobic ammonia oxidation in this hydrothermal vent site. Furthermore, diversity and abundance of AOA and AOB were significantly correlated with the contents of total nitrogen and total sulfur in investigated samples, suggesting that these two environmental factors exert strong influences on distribution of ammonia oxidizers in deep-sea hydrothermal vent environment.     

中国南海部分深海沉积物真菌多样性及其抗菌活性

【目的】从南海4个站位的深海沉积物中分离真菌,揭示其多样性并测定抗菌活性。【方法】使用4种培养方法和8种培养基,从12个深海沉积物样本中分离培养真菌,通过菌落形态观察和ITS序列系统发育分析进行鉴定。采用滤纸片扩散法和生长速率法分别测试真菌小量发酵液粗浸膏的抗细菌和抗真菌活性。【结果】共分离到125株纯培养真菌,基于形态和ITS序列分析,排重后得到18个种类型,这些真菌可以划分到12个属,大多数属于子囊菌门(Ascomycota),只有2株属于担子菌门(Basidiomycota)。4个站位可培养真菌多样性具有差异性。抑菌活性筛选显示,大多数真菌具有较好的抑菌活性;链格孢属(Alternaria)、青霉属(Penicillium)、匐柄霉属(Stemphylium)这几个属的真菌表现出对多种指示细菌有抑制作用,尤其是Alternaria tenuissima DN09、Alternaria alternata DN14和Penicillium chrysogenum DN16对G~+和G~–细菌均表现出抑制作用。【结论】本研究揭示了南海深海沉积物可培养真菌多样性和抑菌活性,为进一步利用深海沉积物来源真菌奠定了基础。     

Growth and Phylogenetic Properties of Novel Bacteria Belonging to the Epsilon Subdivision of the Proteobacteria Enriched from Alvinella pompejana and Deep-Sea Hydrothermal Vents

Recent molecular characterizations of microbial communities from deep-sea hydrothermal sites indicate the predominance of bacteria belonging to the epsilon subdivision of Proteobacteria (epsilon Proteobacteria). Here, we report the first enrichments and characterizations of four epsilon Proteobacteria that are directly associated with Alvinella pompejana, a deep sea hydrothermal vent polychete, or with hydrothermal vent chimney samples. These novel bacteria were moderately thermophilic sulfur-reducing heterotrophs growing on formate as the energy and carbon source. In addition, two of them (Am-H and Ex-18.2) could grow on sulfur lithoautrotrophically using hydrogen as the electron donor. Optimal growth temperatures of the bacteria ranged from 41 to 45°C. Phylogenetic analysis of the small-subunit ribosomal gene of the two heterotrophic bacteria demonstrated 95% similarity to Sulfurospirillum arcachonense, an epsilon Proteobacteria isolated from an oxidized marine surface sediment. The autotrophic bacteria grouped within a deeply branching clade of the epsilon Proteobacteria, to date composed only of uncultured bacteria detected in a sample from a hydrothermal vent along the mid-Atlantic ridge. A molecular survey of various hydrothermal vent environments demonstrated the presence of two of these bacteria (Am-N and Am-H) in more than one geographic location and habitat. These results suggest that certain epsilon Proteobacteria likely fill important niches in the environmental habitats of deep-sea hydrothermal vents, where they contribute to overall carbon and sulfur cycling at moderate thermophilic temperatures.     

Evaluating the Potential of Halothiobacillus Bacteria for Sulfur Oxidation and Biomass Production under Saline Soil

Abstract

Salinity negatively affects growth of sulfur-oxidizing bacteria (SOB) and their sulfate production ability, meanwhile decreases the available sulfate for plants in soil. The aim of this study was to isolate and characterize the bacteria of genus Halothiobacillus, as a salt-tolerant SOB, from saline and sulfidic habitats of Iran for the first time and evaluating the effect of salinity on their biomass and sulfate production during the oxidation of different sulfur sources. Isolation process and surveying the morphological, biochemical and 16S rRNA gene analysis resulted into identification of three species (eight strains) of Halothiobacillus genus including H. neapolitanus, H. hydrothermalis and H. halophilus. Salinity (0, 0.5, 1, 2 and 4?M NaCl) had a significant impact (p?≤?0.01) on bacterial biomass and sulfate production during the oxidation of thiosulfate and elemental sulfur. Biomass and sulfate production by strains was accompanied by a decrease in residual content of thiosulfate (RCT) in medium. The amount of produced biomass and sulfate in medium supplemented by thiosulfate was much higher than elemental sulfur. The highest amount of biomass and sulfate was produced by H. neapolitanus strain I19 at 0.5 and 1?M NaCl concentration. The results of this study could be the first step to focus on the application of these bacteria to increase sulfate storage of saline soils and crop production.     

Microbial diversity of a sulfide black smoker in main endeavour hydrothermal vent field,Juan de Fuca Ridge

Submarine hydrothermal vents are among the least-understood habitats on Earth but have been the intense focus of research in the past 30 years. An active hydrothermal sulfide chimney collected from the Dudley site in the Main Endeavour vent Field (MEF) of Juan de Fuca Ridge was investigated using mineralogical and molecular approaches. Mineral analysis indicated that the chimney was composed mainly of Fe-, Zn-and Cu-rich sulfides. According to phylogenetic analysis, within the Crenarchaeota, clones of the order Desulfurococcales predominated, comprising nearly 50% of archaeal clones. Euryarchaeota were composed mainly of clones belonging to Thermococcales and deep-sea hydrothermal vent Euryarchaeota (DHVE), each of which accounted for about 20% of all clones. Thermophilic or hyperthermophilic physiologies were common to the predominant archaeal groups. More than half of bacterial clones belonged to ɛ-Proteobacteria, which confirmed their prevalence in hydrothermal vent environments. Clones of Proteobacteria (γ-, δ-, β-), Cytophaga-Flavobacterium-Bacteroides (CFB) and Deinococcus-Thermus occurred as well. It was remarkable that methanogens and methanotrophs were not detected in our 16S rRNA gene library. Our results indicated that sulfur-related metabolism, which included sulfur-reducing activity carried out by thermophilic archaea and sulfur-oxidizing by mesophilic bacteria, was common and crucial to the vent ecosystem in Dudley hydrothermal site.     

Culturability and Secondary Metabolite Diversity of Extreme Microbes: Expanding Contribution of Deep Sea and Deep-Sea Vent Microbes to Natural Product Discovery

Microbes from extreme environments do not necessarily require extreme culture conditions. Perhaps the most extreme environments known, deep-sea hydrothermal vent sites, support an incredible array of archaea, bacteria, and fungi, many of which have now been cultured. Microbes cultured from extreme environments have not disappointed in the natural products arena; diverse bioactive secondary metabolites have been isolated from cultured extreme-tolerant microbes, extremophiles, and deep-sea microbes. The contribution of vent microbes to our arsenal of natural products will likely grow, given the culturability of vent microbes; their metabolic, physiologic, and phylogenetic diversity; numerous reports of bioactive natural products from microbes inhabiting high acid, high temperature, or high pressure environments; and the recent isolation of new chroman derivatives and siderophores from deep-sea hydrothermal vent bacteria.