乙型肝炎病毒核心抗原基因在大肠杆菌中的表达

乙肝病毒核心抗原(HBcAg)用于乙型肝炎的诊断是十分必需的,但从尸肝中提取可用于诊断的HBcAg十分困难。为了获得大量廉价的HBcAg用于临床诊断和流行病学检测,我们将HBcAg基因进行了重组,并在原核细胞中得到满意表达。 首先将带有完正ayw亚型乙型肝炎病毒DNA的pHBV-1质粒DNA(梁伟才惠赠,7.5kb)切下1504bp的BamHI片段,后者含有完整的HBcAg基因。将它插入pUR222的Bam     

重组人乙型肝炎病毒E抗原(HBeAg)的基因扩增与表达

本文从两例临床确诊为乙型肝炎患者的2mg肝穿刺标本中利用基因扩增方法,设计扩增出缺失羧基端34个氨基酸的乙型肝炎病毒C抗原(HBcAg)基因的0.45kb基因片段,将此片段克隆入表达载体,导入大肠杆菌中表达,结果获得每毫升培养液含有100万酶联反应单位的HBgAg,也存在1万酶联反应单位的HBcAg。SDS-聚丙烯酰胺凝胶电泳显示,其表达产物占菌体总蛋白的30～37％,分子量为155kD。HBeAg基因结构及表达形式有待进一步研究和探讨。     

通过乙型肝炎病毒核心基因5''''端的修饰使核心抗原在大肠杆菌中高效表达

为了使乙型肝炎病毒核心抗原(HBcAg)在大肠杆菌中获得高效表达,本文首次采用一种新方法对核心基因前区进行改造与修饰,即用限制性内切酶Taq I从核心基因内部5′端切开,去除核心基因起始信号ATG及ATG 5′端上游的全部前核心区(Precore),再化学合成一段既包含核心基因起始信号又具有多种功能的DNA片段。将两者拼接重组到表达载体pUC9上,转化受体菌,成功地获得高效表达HBcAg的菌株。用ELISA法检测,表达滴度为1:80000。表达产量占菌体总蛋白的16％。其菌体裂解液经免疫电镜观察,可见到成堆聚集的典型HBcAg颗粒。抗原单体分子量约为22000道尔顿,双体为44000。与目前国内外所普遍采用的方法比较,本文的方法有许多明显的优点,可用于其它基因改造。     

乙型肝炎病毒核心抗原及Flt3配体双表达核酸疫苗的小鼠免疫应答研究

目的 构建乙型肝炎病毒核心抗原(HBcAg)和Flt3配体(FL)胞外段双表达核酸疫苗,并观察其免疫原性。方法 分别将HBcAg、FL基因克隆入pJW4303载体,获得双表达核酸疫苗,体外转染293T细胞检测目的基因的表达。分组免疫BABL／c小鼠,酶联免疫吸附试验(ELISA)检测小鼠血清抗-HBc IgG效价,酶联免疫斑点试验(ELISPOT)检测HBcAg特异性Th1／Th2型细胞因子的分泌水平。结果 所构建疫苗在体外均能表达HBcAg和FL,当基因位于内部核糖体切入位点(IRES)元件上游时表达水平明显较优。pJW4303／C／FL免疫组产生的抗-HBc IgG效价和Th1／Th2型细胞因子的分泌水平均显著优于pJW4303／C和pJW4303／FL／C组。结论 成功构建双表达核酸疫苗,基因位于上游时表达水平高于下游。FL基因的引入明显增强了HBcAg核酸疫苗的免疫原性。     

乙型肝炎病毒核心抗原(HBcAg)高表达质粒的构建

我们利用了外切酶剪切,人工接头平端连接等DNA重组技术将HBcAg基因片段插入乳糖启动子下游的β-半乳糖苷酶结构基因中,获得了能高效表达HBcAg的重组质粒。ELISA方法检测表明,转化的大肠杆菌每毫升培养物含一万酶联免疫反应单位。     

大肠杆菌合成的乙型肝炎病毒核心抗原的研究Ⅱ．HBcAg的提纯

本文报道HBcAg基因工程菌MM206株的粗提物通过DEAE柱后,基因表达产物HBcAg与核酸及大部分细菌蛋白分开后,再经凝胶过滤和亲和层析作进一步提纯。经DEAE层析和亲和层析获得的纯制品聚丙烯酰胺凝胶电泳图谱显示一主带和两小带。从sepharose 4B柱和亲和层析柱洗出的HBcAg,ELIsA检测证明其比活性分别比粗制品高40倍和100倍,以纯制的HBcAg注射家兔,在6只接受免疫的动物中均产生有抗一HBc,能与从人肝提取的HBcAg产生特异的免疫反应,这表明大肠杆菌合成的HBcAg在动物体内具有生物学活性。     

重组痘苗病毒表达乙肝核心抗原基因的研究

pMM2066质粒EcoR I酶切回收ATG前只有12bp的乙肝核心抗原基因片段,将此基因片段插入痘苗转移载体pGJP-5的P7．5启动子后,组建成P5-C2066质粒,通过细胞内同源重组技术,于BudR存在条件下用人TK-143细胞筛选出三株能表达HBcAg的重组痘苗病毒株。感染细胞上清液1：64稀释时仍能用ELISA法测到HBcAg活性,同时也能测到滴度相近的HBeAg活性。免疫电镜可见平均为26．6nm的HBcAg颗粒。进行了不同量的重组痘苗病毒感染不同细胞,和不同培养温度对HBcAg表达影响的观察。     

外分泌型的乙型肝炎病毒核心抗原核酸疫苗的构建与体外表达

目的:构建含有组织型纤溶酶原激活剂(tPA)信号肽的乙型肝炎病毒核心抗原(HBcAg)核酸疫苗。方法将HBcAg基因用PCR方法扩增并分别引入相应的限制性内切酶酶切位点,然后克隆入pJW4303载体中获得相应的核酸疫苗,经筛选鉴定后,用上述核酸疫苗与野生型HBcAg核酸疫苗及空载体质粒pJW4303分别用脂质体瞬时转染293T细胞,应用蛋白印迹法检测核心抗原的表达。结果成功构建以pJW4303为载体的含tPA信号肽的HBcAg核酸疫苗,体外表达证实含tPA信号肽的HBcAg在293T细胞胞内和胞外均能表达,含tPA信号肽的HBcAg核酸疫苗的核心抗原表达水平较高。结论以pJW4303为载体的含tPA信号肽的HBcAg核酸疫苗能够将细胞内的HBcAg分泌到细胞外,为进一步研究其免疫原性打下了基础。     

核糖体结合位点序列对大肠杆菌中HBcAg重组质粒表达的影响

用Bal-31外切酶调整乙肝病毒核心抗原(HBcAg)基因非编码区长度并克隆到质粒pKK 223-3中,获得了不同水平地表达HBcAg的重组质粒pKL系统。该系统所表达的HBcAg蛋白分子量为21000D。DNA序列分析发现高、中、低表达水平的3个重组质粒的SD序列到HBcAg基因的ATG之间的距离分别为12bp、13bp和19bp,高、低表达质粒的mRNA核糖体结合位点序列的二级结构分析显示,二者的自由能相差约3倍,且低表达质粒的mRNA的SD序列中的3个碱基及AUG中的3个碱基都参与配对,而高表达质粒只有SD序列中的2个碱基参与配对,表明SD序列到ATG的距离及mRNA的二级结构均在HBcAg的表达调控中起重要作用。     

Adr亚型乙型肝炎病毒核心抗原基因的全顺序分析

采用定点克隆与随机克隆相结合的实验设计,用α~(35)S-dATP标记,以末端终止法测定了adr亚型乙型肝炎病毒DNA核心抗原基因的全顺序,包括终止密码子在内基因全长552核苷酸,编码由183氨基酸组成的多肽,计算分子量21000dlt。与日本及上海等实验室报道的adr亚型HBcAg基因比较,核苷酸点突变1.3—1.8％,由点突变导致的错义氨基酸突变有一处,占全部编码氨基酸的0.5％。与adw及ayw亚型比较,核苷酸点突变占全部核苷酸的9.8—10.9％,导致的错义突变占全部编码氨基酸的3.3—4.4％,并对eAg基因的定位进行了讨论。     

大肠杆菌合成的乙型肝炎病毒核心抗原(HBcAg)转化为e抗原(HBeAg)的探索

本文以带有HBcAg基因重组质粒的大肠杆菌转化株Ecoli MM206所合成的HBcAg进行HBcAg转化为HBeAg的探索研究。菌经超声破碎获得的菌裂解液对生理盐水透析两天后,酶联检测发现抗原性部分转化为HBeAg。将菌裂解液或HBcAg精制品用2-巯基乙醇处理,可使抗原性发生进一步转化。但是分子筛层析证明抗原蛋白分子大小没有明显变化。这种制品有可能作为诊断试剂用以检测抗-HBe,而且实验结果表明HBeAg是由HBeAg衍变来的。为要提高HBeAg的稳定性,以碘乙酰胺处理,使还原的抗原蛋白通过羧甲基化反应封闭游离的巯基。经上述处理的HBeAg通过分子筛层析可与大部分细菌杂蛋白分开,制品只有HBeAg活性而测不到HBeAg活性,因而提高了抗原蛋白的稳定性与纯度。     

乙肝病毒核心抗原基因在大肠杆菌中的表达

根据乙型肝炎病毒(HBV)DNA全基因组克隆pHBV-NC的酶切图谱,分别用限制性内切酶HincⅡ-AvaⅠ和BgLⅡ剪切pHBV—NC_1-DNA,获得了两种不同长度HBV核心抗原基因片段:HBcAgⅠ片段和HBcAgⅡ片段。用带有P_R启动子的质粒pCQV2和带有Lac启动子的质粒pUR222与HBcAgⅠ段和HBcAgⅡ片段连接,分别转化到大肠杆菌中,获得了三种不同的表达菌株,命名为pHBcAgⅠ、pHBcAgⅡ和pLcAgⅡ,并对其核心抗原的表达量做了比较。     

Priming Th1 immunity to viral core particles is facilitated by trace amounts of RNA bound to its arginine-rich domain

Particulate hepatitis B core Ag (C protein) (HBcAg) and soluble hepatitis B precore Ag (E protein) (HBeAg) of the hepatitis B virus share >70% of their amino acid sequence and most T and B cell-defined epitopes. When injected at low doses into mice, HBcAg particles prime Th1 immunity while HBeAg protein primes Th2 immunity. HBcAg contains 5-20 ng RNA/microg protein while nucleotide binding to HBeAg is not detectable. Deletion of the C-terminal arginine-rich domain of HBcAg generates HBcAg-144 or HBcAg-149 particles (in which >98% of RNA binding is lost) that prime Th2-biased immunity. HBcAg particles, but not truncated HBcAg-144 or -149 particles stimulate IL-12 p70 release by dendritic cells and IFN-gamma release by nonimmune spleen cells. The injection of HBeAg protein or HBcAg-149 particles into mice primes Th1 immunity only when high doses of RNA (i.e., 20-100 microg/mouse) are codelivered with the Ag. Particle-incorporated RNA has thus a 1000-fold higher potency as a Th1-inducing adjuvant than free RNA mixed to a protein Ag. Disrupting the particulate structure of HBcAg releases RNA and abolishes its Th1 immunity inducing potency. Using DNA vaccines delivered intradermally with the gene gun, inoculation of 1 microg HBcAg-encoding pCI/C plasmid DNA primes Th1 immunity while inoculation of 1 microg HBeAg-encoding pCI/E plasmid DNA or HBcAg-149-encoding pCI/C-149 plasmid DNA primes Th2 immunity. Expression data show eukaryotic RNA associated with HBcAg, but not HBeAg, expressed by the DNA vaccine. Hence, codelivery of an efficient, intrinsic adjuvant (i.e., nanogram amounts of prokaryotic or eukaryotic RNA bound to arginine-rich sequences) by HBcAg nucleocapsids facilitates priming of anti-viral Th1 immunity.     

HBcAg表达菌株的筛选、初步鉴定与DNA顺序分析

为提高HBcAg(乙型肝炎核心抗原)在大肠杆菌体内表达水平,将有HBcAg的基因片段用核酸外切酶从两端消化,插入载体质粒pUR222的EcoRI酶切位点,转化Ecoli BMH71—18,用菌落原位酶联免疫法由275个转化子筛选到7株阳性克隆,用ELISA比较了它们的表达水平,表达水平最高者为M2066菌株,P/N=2.0时菌体裂解液的稀泽度为1:33000’比表达最低者M2098高8,000倍,比第一代菌株M206高15,000倍,DNA顺序分析结果表明与mRNA起始密码上游的发卡结构去除有关。用SDS-PAGE和聚乙烯簿膜复印法检测菌体裂解液中HBcAg的分子量为21000,42000及63000,呈单体和聚合物形式存在,比由病人肝脏和血液中提取的HBcAg(19000)分子量大,为融合蛋白。经琼脂免疫双扩散与ELISA阻断试验未发现与β半乳糖苷酶有免疫学交叉反应。用ELIDA法,M2066-HBcAg与肝-HBcAg同时检测40份血清标本的抗-HBc,二者符合率95％。     

含不同长度前C序列的乙型肝炎病毒核心抗原基因在重组痘苗病毒中的表达

核酸序列分析表明,乙型肝炎(乙肝)病毒核心抗原基因(C基因)编码区内存在两个ATG。目前认为第二个ATG为乙肝病毒C抗原的起始密码子,两个ATG之间的序列称为前C序列,共87bp。Uy、Rutter、Roossinck及景新等的研究表明,含前C序列时,C基因在大肠杆菌中的表达是形成具有HBeAg活性的P25~e膜蛋白,在哺乳动物细胞中的表达则是形成分泌性的HBeAg;不含前C序列时,在大肠杆菌和哺乳动物细胞中均形成P21~e     

Construction of an expression plasmid vector for accomplishing in vivo delivery of recombinant biologically active proteins. 2. Synthesis of HBcAG in a vaccine strain of Salmonella choleraesuis

The capacity of a previously described plasmid vector pAZ to deliver bioactive proteins to targets in vivo has been studied. This vector molecule has a strong constitutive promoter, is extremely stable in cells of vaccinal S. choleraesuis strain, and encodes the synthesis of marker protein beta-galactosidase which helps monitor the vector's fate in the host. The gene encoding hepatitis B virus core antigen (HBcAg) has been inserted into pAZ under its constitutive promoter. The resultant recombinant plasmid p19-24 has been used to transform Enterobacteriaceae (E. coli and S. choleraesuis) cells. Transformed cells produce immunologically active HBcAg. p19-24 was stable in S. choleraesuis cells during their culturing and during this strain persistence in mice. Triple oral immunization of rabbits in a dose of 1 x 10(9) S. choleraesuis cells TC177 induced the production of virus-specific antibodies. Successful transformation of cells of another vaccinal strain S. abortus ovis by this plasmid extends the potentialities of the vector. The results demonstrate good prospects of using pAZ vector for the construction of live oral vaccines.     

Unusually high-level expression of a foreign gene (hepatitis B virus core antigen) in Saccharomyces cerevisiae

As a model system for the study of factors affecting gene expression, hepatitis B virus core antigen (HBcAg) has been expressed in the yeast Saccharomyces cerevisiae. The singularly high levels of expression achieved are approx. 40% of the soluble yeast protein. The HBcAg polypeptides are present as 28-nm particles which are morphologically indistinguishable from HBcAg particles in human plasma and are highly immunogenic in mice. The plasmid construction employed to achieve these very high levels of expression utilizes the constitutively active yeast promoter from the GAP491 gene which is fused in a way that all non-translated sequences flanking the HBcAg coding region are yeast-derived. Hybrid constructions containing 3'-nontranslated viral DNA (yeast 5') or 5'-nontranslated viral DNA (yeast 3') as well as a construction with both 5'- and 3'-nontranslated viral DNA also have been made. A comparison of these constructions for levels of HBcAg expression indicates that the strongest contributor to the high levels of protein is the presence of 5'-flanking sequences which are yeast-derived; secondarily, a significant improvement can be achieved if the 3'-flanking sequences also are yeast-derived. The high abundance of HBcAg in the highest producer is explicable in part on the basis of the very high stability in yeast cells of HBcAg polypeptides. Analysis of the HBcAg coding sequence reveals a very low index of codon bias for S. cerevisiae, largely discounting codon usage as a contributor to the high level of protein obtained.     

HBcAg基因在甲醇型酵母中的表达、产物纯化及其性质的初步研究

为研究乙肝核心抗原蛋白(HBcAg)在甲醇型酵母(PichiaPastoris)中的表达和性质,用PCR方法将HBcAg基因(L)克隆到P.Pastoris胞内表达载体pPIC3k中,并利用电击和同源重组法,将重组质粒pPIC3kL转化感受态的甲醇型GS115酵母菌株。经过筛选得到阳性P.Pastoris重组子。重组菌株经甲醇诱导培养,表达产物的Western印迹结果表明,HBcAg蛋白能在甲醇型酵母(PichiaPastoris)中诱导表达,产物为一215kDa的蛋白。经蔗糖密度梯度超离心和CsCl密度梯度超离心纯化后,ELISA和密度测定结果表明重组HBcAg蛋白主要分布在密度为12576gml和13013gml的2个峰值处。电镜观察表明,该重组HBcAg蛋白能自主装配成大小不同的2种颗粒(即核心颗粒),大颗粒直径约34nm左右,小颗粒直径约30nm左右。同时,我们还观察到,该核心蛋白颗粒在体外可发生集聚现象。