耐热嗜盐菌的分离及16S rRNA基因序列分析

从位于西藏自治区澜沧江边一个47℃的盐井中分离筛选到一株耐热嗜盐菌菌株YJ0238, 对其进行了生理生化特性研究, 采用PCR方法扩增其16S rRNA基因序列, 并进行了测定。基于生理生化特性和16S rRNA基因序列的同源性比较, 以及系统发育分析, 发现菌株YJ0238是Idiomarina属中成员zobellii的一个亚种, 其16S rRNA基因序列已被GenBank数据库收录, 序列号为EF693953。迄今为止, 国内极少有关高温、高盐环境中微生物研究的报道, 本研究可为今后研究同类极端环境中新的物种资源以及微生物多样性提供素材和参考。     

耐热嗜盐菌的分离及16S rRNA基因序列分析

从位于西藏自治区澜沧江边一个47℃的盐井中分离筛选到一株耐热嗜盐菌菌株 YJ0238.对其进行了生理生化特性研究,采用PCR方法扩增其16S rRNA基因序列,并进行了测定.基于生理生化特性和16S rRNA基因序列的同源性比较,以及系统发育分析,发现菌株YJ0238是Idiomarina属中成员zobellii的一个亚种,其16S rRNA基因序列已被GenBank数据库收录,序列号为EF693953.迄今为止,国内极少有关高温、高盐环境中微生物研究的报道,本研究可为今后研究同类极端环境中新的物种资源以及微生物多样性提供素材和参考.     

一株嗜盐细菌的16SrRNA基因序列分析

目的:从舟山深海海泥中获得了底泥样品,并从中提取到了一株嗜盐细菌.方法:通过用不同盐浓度的培养基培养,挑取单菌落,反复划线纯化,得到了嗜盐菌的单菌落,通过菌株基因组DNA的提取、菌株的抗性实验、质粒的提取、16SrRNA的PCR扩增及克隆、16SrRNA的全序列分析等手段.结果:得到该菌株的16SrRNA的基因序列.结论:该株嗜盐菌是一株新色盐杆菌.     

一株解磷中度嗜盐菌的分离鉴定及解磷特性分析

从四川自贡某盐井壁植物根系土壤中分离得到1株中度嗜盐解磷菌QW1011。该菌细胞呈线状, 大小为0.8 μm×30 μm~100 μm, 革兰氏染色为阳性、最适NaCl生长浓度为10%, NaCl最高耐受浓度15%。好氧生长, 酪素水解、硝酸还原和接触酶阴性。菌株的16S rRNA基因序列(接受号：EF647207)与Bacillus megatherium ATCC 14581的16S rRNA相似性为100%, 其16S-23S rRNA间区(ISR)的PCR扩增片的PAGE指纹图谱与参考菌株Baci     

嗜盐菌HBCC-2的16S rRNA基因测序分析及其培养特性

从连云港台南盐场海盐生产区中分离纯化到一株嗜盐古菌HBCC-2,该菌株经PCR扩增后,测定其16S rRNA基因序列,采用BLAST软件对基因库中基因序列进行同源性比较,选取其相似性序列,采用Clustalx1.8和MEGA3.1软件对其16S rDNA序列进行了系统发育分析研究,结果表明HBCC-2菌株与菌株Halorubrum sp.GSL5.48的相似性达99%,结合其形态观察及生理生化反应特性,初步确定该菌株属于嗜盐红菌属(Halorubrum),菌株HBCC-2的16S rDNA序列已登陆到GenBank,其序列号为EF687739.通过比较不同NaCl浓度、pH和培养温度对该菌株生长的影响情况,研究了该菌株的生长特性,结果表明NaCl浓度为4mol/L、温度为35℃和pH为7.0的培养条件下其生长最佳.     

一株高产酯酶中度嗜盐菌的分离、鉴定及酯酶部分酶学性质的研究

利用平板筛选法从盐场卤水池中筛选到一株高效降解Tween 20的中度嗜盐菌DF-B6菌株。通过形态学、生理生化及16S rDNA序列分析确定该菌株为Idiomarina属的成员。底物特异性实验确定DF-B6菌株分泌的脂裂解酶为酯酶, 而非脂肪酶。在含8% NaCl的0.05 mol/L Tris-HCl (pH 8.0)缓冲液中, 50°C条件下作用, 酶活性最高。当反应液中金属离子浓度为10 mmol/L时, Mg2+、Ca2+和Mn2+对酶活有激活作用, 而Zn2+、Fe3+和Cu2+则对酶反应有抑制作用。     

新疆尉犁县黑湖嗜盐嗜碱菌的分离及系统发育学分析

【目的】从新疆尉犁县黑湖中筛选分离获得嗜盐嗜碱微生物,并对筛选获得的微生物进行种属鉴定。【方法】采用传统分离鉴定技术,进行形态和生理生化特性研究和基于16S r RNA基因的序列分析。【结果】从样品中分离获得可培养嗜盐嗜碱菌25株,对其进行鉴定。根据生理生化特征、16S r RNA基因序列测定和系统发育分析表明,25株菌分布在古菌Halorubrum、Haloarcula、Natrialba、Halohasta和Halopiger等5个属。其中优势菌群为Halorubrum,次优势菌群为Natrialba。其中DH-66(KU663028)属于Halopiger属,16S r RNA基因序列同源性与该属的模式菌株Halopiger aswanensis 56T同源性最高,为95.75%,预示为潜在的新种(新种鉴定将另行报道)。25株嗜盐嗜碱菌生长条件实验表明,这些菌适应Na Cl的浓度范围为15%-30%、最适浓度为20%-25%,生长的p H范围为7.0-13.0、最适p H为9.0-10.0。各种水解酶类的分析表明,在分离的25株菌中产淀粉酶的菌有5株占20%、产蛋白酶的菌有4株占16%、产酯酶可水解吐温20的菌有15株占60%、可水解吐温40的有7株占28%、可水解吐温80的有4株占16%、产过氧化氢酶的菌有14株占56%。9株菌同时能产4种酶,2株菌同时能产3种酶。表明了嗜盐嗜碱菌产酶的多样性。19株菌硝酸盐还原为阳性。【结论】揭示了新疆尉犁县黑湖嗜盐嗜碱菌生理生化特性的多样性和系统发育多样性,而且蕴藏着较丰富的新的微生物类群,亟待系统研究和进一步开发利用。     

松嫩平原盐碱地中耐(嗜)盐菌的生物多样性

【目的】分离纯化松嫩平原盐碱地中可培养的耐盐菌和嗜盐菌,并分析其生物多样性。【方法】采用纯培养法和定向富集法从该地区盐碱土样中分离耐盐菌和嗜盐菌,然后通过16S rRNA基因同源性比对鉴定所分离细菌的系统发育学地位,从而获取松嫩平原盐碱地中耐盐菌和嗜盐菌的多样性信息。【结果】共分离到细菌40株,分属于细菌域中3个门(Actinobacteria,Firmicutes,γ-Proteobacteria)、8个科、16个属、34个种。其中多数菌株属于厚壁菌门(Firmicutes),最优势属为葡球菌属(Staphylococcus)(8株,占总菌株的20%),其次依次为盐单胞菌属(Halomonas)(5株,12.5%)、芽胞杆菌属(Bacillus)(4株,10%)、大洋芽胞杆菌属(Oceanbacillus)(4株,10%)、库克菌属(Kocuria)(4株,10%)和假单胞菌属(Pseudomonas)(3株,7.5%)等。其中9株细菌的16S rRNA基因序列与最近缘种的同源性在97.2%-99.0%之间,可能为新种。菌株耐盐能力主要在5%-10%之间,其中62.5%的菌株为耐盐菌,其余则为中度嗜盐菌。所有菌株的耐碱能力在pH 9-12之间,其中60%的菌株耐碱能力则高达pH 12,除两株为嗜碱菌,其余均为耐碱菌。【结论】研究结果表明,松嫩平原盐碱地中耐盐菌与嗜盐菌种群丰富,主要以葡萄球菌和盐单胞菌为主,菌株不仅耐盐能力高而且耐碱能力也高,并且该地区可能含有丰富的耐盐菌和嗜盐菌的新物种。     

极端嗜盐菌16SrDNA的PCR扩增

四株嗜盐菌Haloarcula vallismortis(EM201)、Haloferax denitrificans(EM303)、A_5和B_2已通过一对特定引物用PCR技术从总DNA中扩增出各自的16SrDNA片段,分子大小在1.47kd左右.DNA杂交也表明这些PCR产物具有嗜盐菌的同源性.     

嗜盐古细菌的系统发育分析

用“Clustalw”和“PHYLIP”程序包分析嗜盐古细菌16S rRNA序列,建立了嗜盐古细菌的系统发育树。比较分析的结果进一步支持了以前的结论,即嗜盐古细菌在自然系统分类上应被分成嗜盐菌科的6个属。此系统发育分析方法不仅体现了在嗜盐古细菌属一级分类上的优势,而且还可能被用作一种相应于以《伯杰氏细菌系统分类手册》(第三卷)为基础的嗜盐古细菌种一级分类上的代换方法。实际上,这种系统发育分析方法比其他建立在表型特性基础上的分类系统更真实地反映了嗜盐古细菌内的亲缘关系。该方法的其他运算细节在本文中也进行了讨论。     

Evaluation of different partial 16S rRNA gene sequence regions for phylogenetic analysis of microbiomes

Operational taxonomic units (OTUs) are conventionally defined at a phylogenetic distance (0.03—species, 0.05—genus, 0.10—family) based on full-length 16S rRNA gene sequences. However, partial sequences (700 bp or shorter) have been used in most studies. This discord may affect analysis of diversity and species richness because sequence divergence is not distributed evenly along the 16S rRNA gene. In this study, we compared a set each of bacterial and archaeal 16S rRNA gene sequences of nearly full length with multiple sets of different partial 16S rRNA gene sequences derived therefrom (approximately 440-700 bp), at conventional and alternative distance levels. Our objective was to identify partial sequence region(s) and distance level(s) that allow more accurate phylogenetic analysis of partial 16S rRNA genes. Our results showed that no partial sequence region could estimate OTU richness or define OTUs as reliably as nearly full-length genes. However, the V1-V4 regions can provide more accurate estimates than others. For analysis of archaea, we recommend the V1-V3 and the V4-V7 regions and clustering of species-level OTUs at 0.03 and 0.02 distances, respectively. For analysis of bacteria, the V1-V3 and the V1-V4 regions should be targeted, with species-level OTUs being clustered at 0.04 distance in both cases.     

大黄鱼16SrRNA和18SrRNA基因的测定与序列分析

利用多对引物,扩增并测定出大黄鱼16SrRNA基因和18SrRNA基因的部分序列,其长度分别为1202bp和1275bp,16SrRNA基因序列的GC含量为46．12％,18SrRNA基因的Gc含量为53．oo％。将大黄鱼16SrRNA基因序列与GenBank中15种硬骨鱼类的同源序列结合,同时将其18SrRNA基因序列与GenBank中9种脊索动物的同源序列相结合,运用软件获得各自序列间差异百分比,转换和颠换数值等信息。基于这两种基因序列,利用NJ法和BI法,分别构建16种硬骨鱼类和10种脊索动物的分子系统树。18SrRNA构建的系统树包括三大支,一支为哺乳类、鸟类和爬行类共6个物种,一支为两栖类的1个物种,另一支为2种硬骨鱼类。16SrRNA构建的系统树显示大黄鱼所在的石首鱼科与鲈科和盖刺鱼科亲缘关系较近。此外还讨论了这两个基因的序列特征。     

Bacterial phylogeny based on 16S and 23S rRNA sequence analysis

Abstract: Molecular phylogeny increasingly supports the understanding of organismal relationships and provides the basis for the classification of microorganisms according to their natural affiliations. Comparative sequence analysis of ribosomal RNAs or the corresponding genes currently is the most widely used approach for the reconstruction of microbial phylogeny. The highly and less conserved primary and higher order structure elements of rRNAs document the history of microbial evolution and are informative for definite phylogenetic levels. An optimal alignment of the primary structures and a careful data selection are prerequisites for reliable phylogenetic conclusions. rRNA based phylogenetic trees can be reconstructed and the significance of their topologies evaluated by applying distance, maximum parsimony and maximum likelihood methods of phylogeny inference in comparison, and by fortuitous or directed resampling of the data set. Phylogenetic trees based on almost equivalent data sets of bacterial 23S and 16S rRNAs are in good agreement and their overall topologies are supported by alternative phylogenetic markers such as elongation factors and ATPase subunits. Besides their phylogenetic information content, the differently conserved primary structure regions of rRNAs provide target sites for specific hybridization probes which have been proven to be powerful tools for the identification of microbes on the basis of their phylogenetic relationships.     

Bacterial,archaeal and eukaryotic diversity in Arctic sediment as revealed by 16S rRNA and 18S rRNA gene clone libraries analysis

We studied the microbial diversity in the sediment from the Kongsfjorden, Svalbard, Arctic, in the summer of 2005 based on the analysis of 16S rRNA and 18S rRNA gene clone libraries. The sequences of the cloned 16S rRNA and 18S rRNA gene inserts were used to determine the species identity or closest relatives by comparison with sequences of known species. Compared to the other samples acquired in Arctic and Antarctic, which are different from that of ours, the microbial diversity in our sediment is much higher. The bacterial sequences were grouped into 11 major lineages of the domain Bacteria: Proteobacteria (include α-, β-, γ-, δ-, and ε-Proteobacteria); Bacteroidetes; Fusobacteria; Firmicutes; Chloroflexi; Chlamydiae; Acidobacteria; Actinobacteria; Planctomycetes; Verrucomicrobiae and Lentisphaerae. Crenarchaeota were dominant in the archaeal clones containing inserts. In addition, six groups from eukaryotes including Cercozoa, Fungi, Telonema, Stramenopiles, Alveolata, and Metazoa were identified. Remarkably, the novel group Lentisphaerae was reported in Arctic sediment at the first time. Our study suggested that Arctic sediment as a unique habitat may contain substantial microbial diversity and novel species will be discovered.     

Isolation of halophilic and halotolerant bacteria from a Japanese salt field and comparison of the partial 16S rRNA gene sequence of an extremely halophilic isolate with those of other extreme halophiles

Halophilic and halotolerant bacteria were isolated from soil samples of a Japanese salt field, an environment where salt concentrations vary annually. From 1 g of each of the five samples collected, over 1×10³ bacterial colonies (colony forming units (cfu)g^-1) grew on agar medium containing 2M Na⁺. In contrast, 0–4 bacterial colonies (cfu g^-1) were observed on agar medium containing 4M Na⁺. Two of the five samples contained numerous bacteria (10²–10³ cfu g^-1) capable of growth on a 2M Na⁺ alkaline (pH=9.5) medium, while few bacterial colonies were observed from the other three samples. Only one of the five samples was shown to contain bacteria capable of growth on a 4M Na⁺ alkaline medium. Most of the bacteria isolated on 4M Na⁺ agar were eubacteria, but one extreme halophile (TR-1, already described as Haloarcula japonica JCM7785) was also isolated. The 16S rRNA sequence of TR-1 was determined and shows high homology (94.4–98.5%) to Ha. marismortui and Ha. sinaiiensis. These results suggested that: 1) environments with seasonally varying salinity can harbour halotolerants as well as halophiles and, 2) closely related halophiles can be isolated from geographically distant habitats.     

利用16S rRNA基因同源性分析鉴定两株明串珠菌

从酸马奶中分离出2株明串珠菌KLDS 5.0301和KLDS 5.0302,对2株菌的16S rRNA基因经PCR扩增测序,将测序结果同该属内菌株的16S rRNA序列作多序列比较,并建立明串珠菌属的系统发育树.结果表明,KLDS 5.0301的16S rRNA序列同L. garlicum的同源性百分比为100%.KLDS 5.0302的16S rRNA序列同L.mesenteroides LM2菌株的16S rRNA序列的同源性百分比为99.9%.根据系统发育树的结果,将KLDS5.0301鉴定为L.garlicum,KLDS 5.0302鉴定为L.mesenteroides.菌株KLDS 5.0301和KLDS 5.0302的16SrRNA序列已经在GeneBank申请国际序列注册号,分别为DQ239691和DQ297412.