炭疽芽孢杆菌保护性抗原在大肠杆菌中的表达及纯化

按照炭疽芽孢杆菌保护性抗原（PA）基因成熟肽编码序列设计引物,从炭疽杆菌pOX1质粒中扩增出PA基因片段,将该片段定向插入到原核表达载体pET-28a中,获得了pET-PA原核表达重组质粒,限制性酶切分析和DNA序列测定均证实该克隆插入片段为PA基因的成熟呔编码序列。将该重组质粒转化大肠杆菌BL21（DE3）,经IPTG诱导,重组蛋白在大肠杆菌表达系统中获得了高效表达;Western印迹分析表明表达产物具有良好的免疫学活性。     

炭疽菌保护性抗原受体结合区的表达及其多克隆抗体的制备

原核表达炭疽杆菌保护性抗原受体结合区并制备该蛋白的多克隆抗体.从炭疽芽胞杆菌A16R中经PCR扩增得到了炭疽菌保护性抗原(PA)受体结合区基因,即PA的第四结构域(PA-D4),将其克隆至含有6×His编码序列的原核表达载体pET-2b(+)中,将重组质粒转化大肠杆菌BL21(DE3),在IPTG诱导下进行蛋白表达;用HiTrapTM Chelating HP柱纯化重组蛋白,Western blot进一步鉴定;以纯化后的蛋白为抗原,免疫新西兰大耳白兔制备该蛋白的多克隆抗体;用ELISA和Western blot检测抗血清.结果表明,目的蛋白在大肠杆菌BL21(DE3)中获得了可溶性表达,纯化后纯度可达90%以上;制备了针对PA-D4融合蛋白的高效价抗血清,ELISA抗体滴度为1∶ 102 400;其抗体能特异性识别内源性的PA.PA-D4重组蛋白及其多克隆抗体的获得,为后续研究其功能和炭疽疫苗免疫保护机制奠定了基础.     

利用组氨酸合成酶基因作为同源双交换序列构建在乳酸乳球菌中表达炭疽杆菌保护性抗原的载体

目的:为了实现炭疽杆菌保护性抗原(PA)在乳酸乳球菌中的整合性表达,利用组氨酸合成酶基因(HISB)作为同源交换序列构建表达PA的载体。方法:采用PCR等方法将酸启动子P170、红霉素抗性基因、HISB及酶切位点克隆到pMD18-T载体上,命名为pHEC-P170-PA。结果:构建好的双交换载体经酶切电泳鉴定并测序,其序列中含有PA基因。结论:构建了炭疽杆菌保护性抗原基因同源双交换载体。     

炭疽毒素保护性抗原第四结构域在大肠杆菌中的可溶性表达

人工优化设计并合成炭疽毒素保护性抗原第四结构域基因,并与噬菌体gⅢ蛋白N端结构域基因融合,在大肠杆菌中可溶性表达融合蛋白。结果表明合成了炭疽毒素保护性抗原第四结构域基因,并在大肠杆菌中获得了高效可溶性融合表达,可溶性表达产物占细菌总蛋白量的36％左右;经亲和层析纯化获得了重组蛋白;Western印迹分析表明,表达产物能与His单抗（重组蛋白羧基端带有6xHis）发生特异性结合反应。以上结果表明获得了炭疽毒素保护性抗原第四结构域,为利用人抗体库进行筛选抗炭疽毒素的人源性中和抗体奠定了基础。     

炭疽杆菌的致病因子与炭疽的防治

炭疽为一种人、兽共患急性传染病,部分国家将炭疽杆菌作为生物威胁因子进行研究和生产。该菌毒性与质粒PXOl、PXO2有关,PXOl产物包括水肿因子、保护性抗原和致死因子。PXO2是另一编码致病因子,产物荚膜抑制细胞的吞噬,有助病菌繁殖、扩散和建立感染。抗生素与抗炭疽血清联合应用,突变保护性抗原、水肿因子、致死因子联合注射,Al(OH)3佐剂PA疫苗,减毒口服菌苗,PA基因重组活菌苗均可抵抗炭疽杆菌致死性攻击。     

炭疽芽胞杆菌A16R株FtsE蛋白的可溶性表达和纯化简

目的：构建炭疽芽胞杆菌FtsE蛋白的原核表达载体,实现其在原核表达系统中的可溶性表达,并纯化融合蛋白。方法：用PCR方法从炭疽芽胞杆菌A16R株扩增得到厅sE基因片段,酶切后连接到pET28a原核表达载体,构建重组表达质粒pET28a-ftsE,转化大肠杆菌BL21（DE3）菌株,筛选可溶性诱导表达与纯化融合蛋白的条件,以获得高纯度融合蛋白。结果：构建了FtsE蛋白的融合表达载体,并在大肠杆菌中获得高效表达;在20℃下,经0．1mmol/LIPTG诱导3h表达的产物主要是可溶性蛋白,经Ni-NTA亲和层析纯化获得了高纯度的FtsE融合蛋白,经Western印迹检测,目的蛋白表达正确。结论：实现了炭疽芽胞杆菌FtsE蛋白原核表达系统的可溶性表达并获得了高纯度融合蛋白,为后续研究奠定了基础。     

炭疽芽胞杆菌A16R株FtsE蛋白的可溶性表达和纯化

目的:构建炭疽芽胞杆菌FtsE蛋白的原核表达载体,实现其在原核表达系统中的可溶性表达,并纯化融合蛋白。方法:用PCR方法从炭疽芽胞杆菌A16R株扩增得到ftsE基因片段,酶切后连接到pET28a原核表达载体,构建重组表达质粒pET28a-ftsE,转化大肠杆菌BL21(DE3)菌株,筛选可溶性诱导表达与纯化融合蛋白的条件,以获得高纯度融合蛋白。结果:构建了FtsE蛋白的融合表达载体,并在大肠杆菌中获得高效表达;在20℃下,经0.1 mmol/L IPTG诱导3 h表达的产物主要是可溶性蛋白,经Ni-NTA亲和层析纯化获得了高纯度的FtsE融合蛋白,经Western印迹检测,目的蛋白表达正确。结论:实现了炭疽芽胞杆菌FtsE蛋白原核表达系统的可溶性表达并获得了高纯度融合蛋白,为后续研究奠定了基础。     

重组炭疽保护性抗原的表达、纯化与生物活性分析

构建分泌型表达质粒 ,在大肠杆菌中实现了重组炭疽保护性抗原 (rPA)的分泌型表达。重组蛋白位于细菌外周质 ,表达量约占菌体总蛋白的 10 %。以离子交换、疏水层析和凝胶过滤为基础 ,建立了rPA的纯化工艺 ,每升培养物可获得约 15mgrPA ,纯度可达 95 %以上。体外细胞毒性试验显示rPA具有较好的生物学活性。用rPA免疫家兔产生的抗血清在体外可抑制炭疽致死毒素的活性 ,表明rPA可诱导机体产生保护性免疫。以上结果为今后发展新一代炭疽疫苗打下基础     

炭疽芽孢杆菌EA1蛋白的融合表达和纯化

目的：原核表达重组炭疽芽孢杆菌EA1蛋白。方法：用PCR方法从炭疽芽孢杆菌A16R疫苗株染色体中扩增编码EA1蛋白的eag基因序列,经过纯化、酶切后克隆到含有GST标签的原核表达载体pGEX-6P-2中,构建重组载体pGEX-EA1;将空载体（作为对照）、重组载体转化大肠杆菌BL21（DE3）菌株获得表达工程菌株,对其表达和纯化条件进行优化;利用Western印迹检测融合蛋白的表达。结果：构建了EA1蛋白的融合表达载体,并在大肠杆菌中获得高效表达;经Glutathione Sepharose 4B纯化获得了EA1蛋白;Western印迹表明,此蛋白可与GST标签抗体反应。结论：在原核表达系统中表达并纯化得到EA1融合蛋白,为进一步对其进行功能研究奠定了基础。     

炭疽芽胞杆菌BslA(260－652)蛋白的表达纯化与黏附功能鉴定

【目的】克隆表达炭疽芽胞杆菌BlsA的功能区片段并对其生物学功能进行鉴定。【方法】以炭疽芽胞杆菌A16R基因组DNA为模板PCR扩增bslA(260-652)基因片段,克隆至pET-28a(+)载体。将成功构建的重组质粒转化入大肠杆菌Rosetta(DE3)中,诱导表达后收集菌体经超声破碎后,对可溶表达部分用镍柱进行亲和层析纯化。以纯化后的蛋白为抗原,免疫BALB/c小鼠制备该蛋白的多抗,用ELISA和Western blot检测抗血清;使用间接免疫荧光实验和细菌黏附实验研究目标蛋白及其抗体的生物学功能。【结果】BslA(260-652)获得了可溶性表达,纯化后纯度约为87.4%。以纯化蛋白为抗原,免疫BALB/c小鼠制备的抗血清ELISA效价可达1∶20000。将BslA(260-652)蛋白与Hela细胞共孵育后,能够直接和Hela的细胞膜结合。细菌黏附实验表明BslA(260-652)蛋白及其相应的多抗血清都能够显著地抑制炭疽芽胞杆菌A16R对Hela细胞的黏附。【结论】大肠杆菌表达得到的炭疽芽胞杆菌BslA(260-652)蛋白具有与天然蛋白相似的生物活性,为深入研究BslA蛋白在炭疽芽胞杆菌致病过程中的作用奠定实验基础。     

Constitutive expression of protective antigen gene of Bacillus anthracis in Escherichia coli

The fatal bacterial infection caused by inhalation of the Bacillus anthracis spores results from the synthesis of protein toxins-protective antigen (PA), lethal factor (LF), and edema factor (EF)--by the bacterium. PA is the target-cell binding protein and is common to the two effector molecules, LF and EF, which exert their toxic effects once they are translocated to the cytosol by PA. PA is the major component of vaccines against anthrax since it confers protective immunity. The large-scale production of recombinant protein-based anthrax vaccines requires overexpression of the PA protein. We have constitutively expressed the protective antigen protein in E. coli DH5alpha strain. We have found no increase in degradation of PA when the protein is constitutively expressed and no plasmid instability was observed inside the expressing cells. We have also scaled up the expression by bioprocess optimization using batch culture technique in a fermentor. The protein was purified using metal-chelate affinity chromatography. Approximately 125 mg of recombinant protective antigen (rPA) protein was obtained per liter of batch culture. It was found to be biologically and functionally fully active in comparison to PA protein from Bacillus anthracis. This is the first report of constitutive overexpression of protective antigen gene in E. coli.     

Construction and characterization of a protective antigen-deficient Bacillus anthracis strain

The pag gene coding for protective antigen (PA), one of the three toxin components of Bacillus anthracis, has been cloned into the mobilizable shuttle vector pAT187 and transferred by conjugation from Escherichia coli to B. anthracis. Using this strategy, an insertionally mutated pag gene constructed and characterized in E. coli, was introduced into B. anthracis Sterne strain. This transconjugant was used to select a recombinant clone (RP8) carrying the inactivated pag gene on the toxin-encoding plasmid, pXO1. Strain RP8 was deficient for PA while still producing the two other toxin components, i.e. lethal factor (LF) and edema factor (EF). In contrast to spores from the wild-type Sterne strain, spores prepared from RP8 were totally non-lethal in mice. These results clearly establish the central role played by PA in B. anthracis pathogenicity.     

Cloning of the protective antigen gene of Bacillus anthracis

The tripartite protein toxin of Bacillus anthracis consists of protective antigen (PA), edema factor (EF), and lethal factor (LF). As a first step in developing a more efficacious anthrax vaccine, recombinant plasmids containing the PA gene have been isolated. A library was constructed in the E. coli vector pBR322 from Bam HI-generated fragments of the anthrax plasmid, pBA1. Two clones producing PA were identified by screening lysates with ELISA (enzyme-linked immunosorbent assay). Western blots revealed a full-size PA protein in the recombinant E. coli, and a cell elongation assay demonstrated biological activity. Both positive clones had a 6 kb insert of DNA, which mapped in the Bam HI site of the vector. The two inserts are the same except that they lie in opposite orientations with respect to the vector. Thus PA is encoded by the plasmid pBA1.     

Production and characterization of neutralizing monoclonal antibodies that recognize an epitope in domain 2 of Bacillus anthracis protective antigen

Antibodies against the protective antigen (PA) of Bacillus anthracis play a key role in response to infection by this important pathogen. The aim of this study was to produce and characterize monoclonal antibodies (mAbs) specific for PA and to identify novel neutralizing epitopes. Three murine mAbs with high specificity and nanomolar affinity for B. anthracis recombinant protective antigen (rPA) were produced and characterized. Western immunoblot analysis, coupled with epitope mapping using overlapping synthetic peptides, revealed that these mAbs recognize a linear epitope within domain 2 of rPA. Neutralization assays demonstrate that these mAbs effectively neutralize lethal toxin in vitro.     

炭疽杆菌保护性抗原基因的克隆与序列测定

采用聚合酶链反应从炭疽芽孢杆菌减毒株ＹＢ１中扩增其保护性抗原（ＰＡ）的编码区基因,将其克隆至ｐＧＥＭ－Ｔ载体中,并分步测定其序列。序列测定表明,该基因长２２０５ｂｐ,编码７３５个氨基酸残基,与献报道的标准菌株Ｓｔｅｒｎｅ株的ＰＡ序列只有４个碱基的差异。     

Evaluation of Bacillus subtilis strain IS53 for the production of Bacillus anthracis protective antigen

An asporogenous strain of Bacillus subtilis , IS53, transformed with plasmid pPA102, produces the protective antigen (PA) component of the tripartite toxin of B. anthracis . Addition of yeast extract was required to support growth and PA production in all the media examined. Protective antigen expression was down-regulated during exponential growth and extracellular proteases caused marked degradation of the mature protein.     

Immunogenicity of the recombinant Bacillus strains with cloned gene of biosynthesis of protective antigen against Bacillus anthracis

Microbe Russian Anti-Plague Research Institute, Saratov A hybrid plasmid pUB110PA-1 demonstrating stable functioning in the cells of Bacillus strains and containing the gene of biosynthesis of Bacillus anthracis protective antigen was constructed. The recombinant strains surpassing the anthrax vaccinal cultures in the secreted synthesis of the protective antigen were obtained and their immunological efficacy was assessed. A single inoculation of Guinea pigs with the dose of 5 x 107 spores of the recombinant strains imparted efficient protection against B. anthracis challenge. Immune responses were characterized by high indices of immunity and titers of antibodies to the protective antigen. In contrast to the anthrax vaccinal preparations, the gene-engineering strains imposed no residual virulence for BALB/n mice and Guinea pigs.     

A Bacillus anthracis strain deleted for six proteases serves as an effective host for production of recombinant proteins

Bacillus anthracis produces a number of extracellular proteases that impact the integrity and yield of other proteins in the B. anthracis secretome. In this study we show that anthrolysin O (ALO) and the three anthrax toxin proteins, protective antigen (PA), lethal factor (LF), and edema factor (EF), produced from the B. anthracis Ames 35 strain (pXO1?, pXO2?), are completely degraded at the onset of stationary phase due to the action of proteases. An improved Cre-loxP gene knockout system was used to sequentially delete the genes encoding six proteases (InhA1, InhA2, camelysin, TasA, NprB, and MmpZ). The role of each protease in degradation of the B. anthracis toxin components and ALO was demonstrated. Levels of the anthrax toxin components and ALO in the supernatant of the sporulation defective, pXO1? A35HMS mutant strain deleted for the six proteases were significantly increased and remained stable over 24 h. A pXO1-free variant of this six-protease mutant strain, designated BH460, provides an improved host strain for the preparation of recombinant proteins. As an example, BH460 was used to produce recombinant EF, which previously has been difficult to obtain from B. anthracis. The EF protein produced from BH460 had the highest in vivo potency of any EF previously purified from B. anthracis or Escherichia coli hosts. BH460 is recommended as an effective host strain for recombinant protein production, typically yielding greater than 10mg pure protein per liter of culture.     

Expression and secretion of the protective antigen of Bacillus anthracis in Bacillus brevis

We used the Bacillus brevis-pNU212 system to develop a mass production system for the protective antigen (PA) of Bacillus anthracis. A moderately efficient expression-secretion system for PA was constructed by fusing the PA gene from B. anthracis with the B. brevis cell-wall protein signal-peptide encoding region of pNU212, and by introducing the recombinant plasmid, pNU212-mPA, into B. brevis 47-5Q. The clone producing PA secreted about 300 microg of recombinant PA (rPA) per ml of 5PY-erythromycin medium after 4 days incubation at 30 degrees C. The rPA was fractionated from the culture supernatant of B. brevis 47-5Q carrying pNU212-mPA using ammonium sulfate at 70% saturation followed by anion exchange chromatography on a Hitrap Q, a Hiload 16/60 Superdex 200 gel filtration column and a phenyl sepharose hydrophobic interaction column, yielding 70 mg rPA per liter of culture. The N-terminal sequence of the purified rPA was identical to that of native PA from B. anthracis. The purified rPA exhibited cytotoxicity towards J774A.1 cells when combined with lethal factor. The rPA formulated in either Rehydragel HPA or MPL-TDM-CWS adjuvant (Ribi-Trimix) elicited the expression of a large amount of anti-PA and neutralizing antibodies in guinea pigs and completely protected them against a 100 LD50 challenge with fully virulent B. anthracis spores.