波摩那型钩端螺旋体外膜蛋白LipL32基因片段的克隆表达

目的　构建L3 2_pGEX_5x_2重组质粒 ,诱导表达重组钩端螺旋体外膜脂蛋白LipL3 2。方法　PCR获取编码LipL3 2的基因片段 ,构建重组克隆载体和表达载体 ,转化受体菌 ,诱导表达重组LipL3 2蛋白。将重组LipL3 2蛋白和钩体抗血清进行Western_blot。结果　扩增出约 750bp的LipL3 2成熟蛋白基因 ,LipL3 2基因插入pGEX_5x_2表达载体 ,表达产物谷胱甘肽S_转移酶 (GST ,2 6× 10 3)与LipL3 2蛋白的融合蛋白的相对分子质量约为 53× 10 3 ,与预期大小一致。Western_blot显示重组LipL3 2蛋白能与钩体抗血清特异结合。结论　LipL3 2蛋白能在大肠埃希菌中表达 ,重组LipL3 2蛋白具有免疫反应性     

钩端螺旋体赖型017鞭毛钩相关蛋白K基因的克隆及序列分析

在以抑制消减杂交比较强毒株赖型钩端螺旋体017株和无毒株双曲钩体Patoc　I株　的基因组差异时,获得了一系列仅存在于强毒株而无毒株缺如的差异片段.选取差异片段AF325810设计特异性引物,以赖型钩端螺旋体017株基因组DNA为模板,进行巢式PCR扩增,PCR纯化产物T载体克隆,选取阳性克隆测序,进一步进行生物信息学分析,以获得强毒株赖型钩端螺旋体017株特有的毒力相关基因,DOT BLOT显示其在钩端螺旋体各株间有不同分布PCR扩增得到了产物为2kb大小的DNA片段,序列分析结果显示得到了问号钩端螺旋体赖型017株的鞭毛钩相关蛋白K基因的上游序列,为进一步探索钩端螺旋体的致病机制奠定了基础.     

钩端螺旋体LA_1100蛋白膜定位研究

目的 研究LA_1100蛋白在钩端螺旋体中的膜定位并分析其在中国流行血清群中的保守性.方法 利用生物信息学软件对LA_1100的二级及三级结构进行分析,以Triton X-114抽提分离钩体细胞的各个组分,Westernblot及FACS方法验证LA_1100在钩端螺旋体中的膜定位.Western Blot和PCR在蛋白水平及核酸水平检测了其在13个中国流行血清群代表株中的保守性.结果 LA_1100的二级结构显示具有α-螺旋及β-折叠结构,进一步分析表明,此蛋白具有跨膜区.LA_1100单体结构具有典型的TolC结构域,三级结构模拟显示三聚体可形成孔状结构.膜定位显示,该蛋白定位于外膜.该基因的保守性分析结果表明,在中国13个流行代表株中有12株均检出该基因或该蛋白的特征性条带.结论 LA_1100为具有TolC结构域可以形成孔状结构的钩端螺旋体外膜蛋白,在中国流行株钩端螺旋体中保守.由于TolC蛋白与病原菌分泌致病因子密切相关,推测此蛋白可能与钩体感染宿主时粘附及致病相关,进一步对此蛋白进行研究有利于揭示钩体的致病机制.     

致病钩体表层膜蛋白新基因（Lslp）的克隆表达及免疫原性研究

克隆表达钩端螺旋体表层膜蛋白新基因Lslp并分析表达产物的免疫原性。根据前期研究得到的致病钩体新基因Lslp(GenBankAF32 5 80 7)的序列设计引物 ,在 6株致病钩体中扩增Lslp基因并测序。以BamHⅠ酶切Lslp和pGEX 1 λT ,构建重组质粒并用酶切和PCR鉴定 ,进一步在大肠杆菌中诱导表达 ,并进行免疫印迹分析 ;纯化表达产物免疫家兔 ,ELISA检测血清抗体滴度。结果显示Lslp在 6株致病钩体中均能扩增出相应片段 ,且序列同源性达到99 6 % ;构建高效原核表达重组质粒pGST LslP ,经IPTG诱导在大肠杆菌中可表达出 6 6kDGST融合蛋白 ,并能与全钩抗血清发生免疫印迹反应 ;将上述融合蛋白免疫新西兰大白兔产生 1 :5 1 2 0高滴度的IgG抗体。研究结果提示致病钩体膜蛋白新基因Lslp可在大肠杆菌进行高效表达 ,表达产物能被全钩抗血清识别 ,为研究钩体的致病机制和筛选保护性抗原提供了基础     

七日热群钩端螺旋体的两个新血清型

本文报告七日热群钩端螺旋体的两个新血清型。A10株钩端螺旋体系I 962年自勐腊县钩端螺旋体病患者分离,命名为云南型钩端螺旋体(Leptospira interrogans serovar yunnan)H27株钩端螺旋体系1964年自河口县钩端螺旋体病患者分离,命名为河口型钩端螺旋体(Le-ptospira interrogans serovar hekou)。     

钩端螺旋体的几种检测方法

钩端螺旋体的几种检测方法万成松张文炳曹虹（第一军医大学微生物学教研室,广州５１０５１５）钩端螺旋体（简称钩体,Ｌｅｐｔｏｓｐｉｒａ）是一类细长、弯曲、两端呈钩状的螺旋体,钩体种类很多,分类学上归细菌范畴,可分致病性和非致病性两大类。钩体病是由致病性钩...     

重组钩端螺旋体外膜蛋白酶联免疫吸附(ELISA)检测方法的建立

目的建立以重组外膜蛋白为基础的钩端螺旋体抗体间接ELISA检测方法。方法以基因重组技术获取重组钩端螺旋体外膜蛋白LipL32,以该蛋白为抗原,特异的钩体抗血清进行ELISA方阵滴定、交叉性试验、阻断试验,并对北京地区的70份犬血清使用建立的ELISA方法以及德国Virion公司的全菌体钩端螺旋体ELISA试剂盒进行相互验证。结果方阵滴定试验确立以100ng/孔为抗原包被浓度,1∶160为血清稀释度。交叉性试验具有广泛性、阻断试验标明该方法特异性强、灵敏度高。两种方法数据经χ2检验,两者检出率之间差异不显著。结论重组LipL32蛋白具有结合活性。初步建立了以重组LipL32蛋白为抗原的钩端螺旋体抗体间接ELISA检测方法。     

七日热群钩端螺旋体的一个新血清型

A23株钩端螺旋体系1962年8月3日分离富云南省勐腊县钩端螺旋体病患者血液。经交叉凝集试验、交又凝集素吸收试验和园子血清凝集试验证明是七日热群保林卡那亚群钩端螺旋体的一个新血清型。建议命名为致病性钩端螺旋体曼I芏血清型(Leptospira interrogansserovar manzhucng)。此型感染在勐腊已发现6例。     

钩端螺旋体遗传物质和毒力因子的研究进展

钩端螺旋体可引起人、兽共患疾病--钩端螺旋体病,其基本结构由圆柱形菌体、鞭毛和外膜组成.经血清型分类法将该体分为24个血清群200多种血清型.该体由大、小两个染色体组成,基因组共约5000kb,推测含4 768个基因.结构基因编码的鞭毛蛋白、溶血素、脂蛋白、脂多糖等可作为毒力因子,在钩端螺旋体致病过程中起主要作用.     

钩端螺旋体的研究进展

广义上钩端螺旋体是指螺旋体目钩端螺旋体科钩端螺旋体属的微生物,随着研究的深入,现该属微生物被划分为钩端螺旋体属（Leptospira）和细丝体属（Leptonema）17个种。由于钩端螺旋体具有独特的形态结构、进化上特殊的地位和医学上的重要意义,一直是研究者和医务工作者关注的对象。钩端螺旋体可引起钩端螺旋体病,该病是一个潜在的、严重的世界性公共卫生问题。其典型症状是黄疸、肾衰竭、出血及心肌炎与心律不齐,     

Thermus thermophilus L11 methyltransferase, PrmA, is dispensable for growth and preferentially modifies free ribosomal protein L11 prior to ribosome assembly

The ribosomal protein L11 in bacteria is posttranslationally trimethylated at multiple amino acid positions by the L11 methyltransferase PrmA, the product of the prmA gene. The role of L11 methylation in ribosome function or assembly has yet to be determined, although the deletion of Escherichia coli prmA has no apparent phenotype. We have constructed a mutant of the extreme thermophile Thermus thermophilus in which the prmA gene has been disrupted with the htk gene encoding a heat-stable kanamycin adenyltransferase. This mutant shows no growth defects, indicating that T. thermophilus PrmA, like its E. coli homolog, is dispensable. Ribosomes prepared from this mutant contain unmethylated L11, as determined by matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF MS), and are effective substrates for in vitro methylation by cloned and purified T. thermophilus PrmA. MALDI-TOF MS also revealed that T. thermophilus L11 contains a total of 12 methyl groups, in contrast to the 9 methyl groups found in E. coli L11. Finally, we found that, as with the E. coli methyltransferase, the ribosomal protein L11 dissociated from ribosomes is a more efficient substrate for in vitro methylation by PrmA than intact 70S ribosomes, suggesting that methylation in vivo occurs on free L11 prior to its incorporation into ribosomes.     

Recognition of ribosomal protein L11 by the protein trimethyltransferase PrmA

Bacterial ribosomal protein L11 is post-translationally trimethylated at multiple residues by a single methyltransferase, PrmA. Here, we describe four structures of PrmA from the extreme thermophile Thermus thermophilus. Two apo-PrmA structures at 1.59 and 2.3 A resolution and a third with bound cofactor S-adenosyl-L-methionine at 1.75 A each exhibit distinct relative positions of the substrate recognition and catalytic domains, revealing how PrmA can position the L11 substrate for multiple, consecutive side-chain methylation reactions. The fourth structure, the PrmA-L11 enzyme-substrate complex at 2.4 A resolution, illustrates the highly specific interaction of the N-terminal domain with its substrate and places Lys39 in the PrmA active site. The presence of a unique flexible loop in the cofactor-binding site suggests how exchange of AdoMet with the reaction product S-adenosyl-L-homocysteine can occur without necessitating the dissociation of PrmA from L11. Finally, the mode of interaction of PrmA with L11 explains its observed preference for L11 as substrate before its assembly into the 50S ribosomal subunit.     

Sequence, structural, and evolutionary analysis of prokaryotic ribosomal protein L11 methyltransferases

The Escherichia coli PrmA enzyme catalyzes methylation of the large ribosomal subunit protein L11. Database homology searches, multiple sequence alignment, and structure prediction allowed to dissect the primary structure of PrmA into two domains and assign putative functional or structural roles to invariant or highly conserved residues. Evolutionary relationships within the PrmA family were also analyzed. The topology of the branching order agrees to a large extent with the consensus phylogeny of Eubacteria, with the exception of beta and epsilon subdivisions of Proteobacteria, which most probably had their original prmA genes replaced by copies acquired via the lateral gene transfer from gamma-Proteobacteria and some close relative of the ancestor of gramnegative bacteria, respectively.     

游仆虫重组核糖体蛋白L11与肽链释放因子的体外相互作用分析

核糖体蛋白L11(ribosome protein L11)是一种高度保守的蛋白质．为研究真核生物的核糖体蛋白L11的功能,从八肋游仆虫（Euplotes octocarinatus）大核基因组中克隆到核糖体蛋白L11基因,构建了重组表达质粒pGEX-6p1-L11,通过谷胱甘肽-Sepharose 4B亲和层析,纯化了重组融合蛋白GST-L11．Pull down 分析显示,八肋游仆虫的核糖体蛋白L11与第一类肽链释放因子eRF1a可以在体外相互作用．这一结果提示,与原核生物一样,低等真核生物的核糖体蛋白L11在肽链终止过程中可能起一定的作用．     

Multiple-site trimethylation of ribosomal protein L11 by the PrmA methyltransferase

Ribosomal protein L11 is a universally conserved component of the large subunit, and plays a significant role during initiation, elongation, and termination of protein synthesis. In Escherichia coli, the lysine methyltransferase PrmA trimethylates the N-terminal alpha-amino group and the epsilon-amino groups of Lys3 and Lys39. Here, we report four PrmA-L11 complex structures in different orientations with respect to the PrmA active site. Two structures capture the L11 N-terminal alpha-amino group in the active site in a trimethylated post-catalytic state and in a dimethylated state with bound S-adenosyl-L-homocysteine. Two other structures show L11 in a catalytic orientation to modify Lys39 and in a noncatalytic orientation. The comparison of complex structures in different orientations with a minimal substrate recognition complex shows that the binding mode remains conserved in all L11 orientations, and that substrate orientation is brought about by the unusual interdomain flexibility of PrmA.     

S-Adenosylmethionine decarboxylase from the archaeon Methanococcus jannaschii: identification of a novel family of pyruvoyl enzymes

Polyamines are present in high concentrations in archaea, yet little is known about their synthesis, except by extrapolation from bacterial and eucaryal systems. S-Adenosylmethionine (AdoMet) decarboxylase, a pyruvoyl group-containing enzyme that is required for spermidine biosynthesis, has been previously identified in eucarya and Escherichia coli. Despite spermidine concentrations in the Methanococcales that are several times higher than in E. coli, no AdoMet decarboxylase gene was recognized in the complete genome sequence of Methanococcus jannaschii. The gene encoding AdoMet decarboxylase in this archaeon is identified herein as a highly diverged homolog of the E. coli speD gene (less than 11% identity). The M. jannaschii enzyme has been expressed in E. coli and purified to homogeneity. Mass spectrometry showed that the enzyme is composed of two subunits of 61 and 63 residues that are derived from a common proenzyme; these proteins associate in an (alphabeta)(2) complex. The pyruvoyl-containing subunit is less than one-half the size of that in previously reported AdoMet decarboxylases, but the holoenzyme has enzymatic activity comparable to that of other AdoMet decarboxylases. The sequence of the M. jannaschii enzyme is a prototype of a class of AdoMet decarboxylases that includes homologs in other archaea and diverse bacteria. The broad phylogenetic distribution of this group suggests that the canonical SpeD-type decarboxylase was derived from an archaeal enzyme within the gamma proteobacterial lineage. Both SpeD-type and archaeal-type enzymes have diverged widely in sequence and size from analogous eucaryal enzymes.     

人胱硫醚β-合酶及其截短型片段的表达、纯化和活性测定

将人胱硫醚β-合酶(CBS)基因克隆至质粒pGEX-4T-1中,获得的重组质粒pGEX-4T-1-CBS转入大肠杆菌E.coli Rosetta (DE3)菌株,构建了高效表达CBS的重组菌E.coli Rosetta (pGEX4T-1-CBS)。重组菌在0.1mmol/L的IPTG于30℃诱导16h,可溶性CBS表达量达到28mg/L培养基。将重组菌破碎后上清液经GSTrap Fast Flow亲和层析一步纯化得到CBS融合蛋白,在凝血酶柱上切割缓冲液中加入3%甘油和0.1%CHAPS可以有效抑制酶切后CBS聚沉,酶活性回收率为54.8%,蛋白质产率为15.2mg/L培养基,纯度达到95%,单位酶活为143U/mg,终浓度为1mmol/L的S-腺苷甲硫氨酸(AdoMet)可使CBS单位酶活提高5.1倍,达到735U/mg。同时构建了表达CBS_1-413(删除了CBS羧基端调控域138个氨基酸残基)的重组菌E.coli Rosetta (pETDuet-1-CBS_1-413),经过一步HisTrap Fast Flow亲和层析,酶活性回收率为74.3%,蛋白质产率为12.8mg/L培养基,纯度达到95%,单位酶活为965U/mg; 还表达和纯化了胱硫醚β-裂解酶(CBL),并在此基础上建立了一种新的CBL偶联的CBS酶活性测定方法。     

Differential Effects of Replacing Escherichia coli Ribosomal Protein L27 with Its Homologue from Aquifex aeolicus

The rpmA gene, which encodes 50S ribosomal subunit protein L27, was cloned from the extreme thermophile Aquifex aeolicus, and the protein was overexpressed and purified. Comparison of the A. aeolicus protein with its homologue from Escherichia coli by circular dichroism analysis and proton nuclear magnetic resonance spectroscopy showed that it readily adopts some structure in solution that is very stable, whereas the E. coli protein is unstructured under the same conditions. A mutant of E. coli that lacks L27 was found earlier to be impaired in the assembly and function of the 50S subunit; both defects could be corrected by expression of E. coli L27 from an extrachromosomal copy of the rpmA gene. When A. aeolicus L27 was expressed in the same mutant, an increase in the growth rate occurred and the "foreign" L27 protein was incorporated into E. coli ribosomes. However, the presence of A. aeolicus L27 did not promote 50S subunit assembly. Thus, while the A. aeolicus protein can apparently replace its E. coli homologue functionally in completed ribosomes, it does not assist in the assembly of E. coli ribosomes that otherwise lack L27. Possible explanations for this paradoxical behavior are discussed.