SARS冠状病毒N蛋白基因的克隆、表达及活性测定

利用PCR基因扩增法,以SARS冠状病毒全基因质粒为模板,获得N蛋白相应抗原基因,构建了表达载体pBV220／SARS-N,并在E．coli中获得高效表达。用纯化后的N蛋白抗原包被测定板,通过间接ELISA法对阴阳性血清进行活性测定,结果表明,在46份阳性血中有41份被测出,检出率为89．13％。本研究克隆并表达了SARS冠状病毒N蛋白,为进一步研制SARS病人抗体检测试剂和SARS疫苗奠定了基础。     

重组SARS冠状病毒M蛋白的表达、纯化及鉴定

SARS冠状病毒是人的严重急性呼吸综合征的病原体。根据对其他种类冠状病毒的研究结果 ,膜蛋白 (M蛋白 )是病毒主要的结构蛋白 ,重组M蛋白可被用来作为抗原检测对应冠状病毒的感染和制备疫苗。SARS病毒M蛋白基因克隆到原核表达载体pMAL cRI中 ,利用N端和C端分别融合麦芽糖结合蛋白 (maltosebindingprotein和MxeGyrAinteinCBD的策略 ,在大肠杆菌中初步表达了重组M蛋白 ,并通过Western印迹和质谱对蛋白质进行了鉴定。重组蛋白质经亲和层析得到了部分纯化 ,纯化后的蛋白质将用于功能研究与诊断试剂盒的研制。     

以霍乱毒素B亚基为佐剂的SARS病毒核酸疫苗的构建

由于冠状病毒主要通过粘膜系统侵人细胞,因此有效的粘膜免疫效应对于SARS的免疫预防具有重要作用。通过将SARS冠状病毒免疫保护相关的核衣壳蛋白和辐条蛋白与霍乱毒素B亚基基因融合,并克隆至真核基因表达载体,所构建的DNA候选疫苗在细胞内可表达霍乱毒素B亚基与SARS抗原的融合蛋白,从而可用于评价是否可有效产生粘膜免疫。     

SARS冠状病毒S蛋白噬菌体抗原库的构建及筛选

本研究旨在构建SARS冠状病毒S蛋白特异性噬菌体抗原库,并用于鉴定抗S蛋白单克隆抗体的抗原表位。首先采用PCR技术扩增出SARS冠状病毒S蛋白的全基因,以DNaseI将其随机酶切成50～500bp不同大小的DNA片段。然后将DNA片段平末端化并连接到经过改造的噬菌体表达载体pComb3XSS,经电转化大肠杆菌XL1-Blue和辅助噬菌体感染获得S蛋白的特异性噬菌体抗原库。利用两个抗S蛋白单克隆中和抗体(S-M1和S-M2)对S蛋白抗原库进行富集和筛选。结果表明,我们成功构建库容量为5.7×106的S蛋白噬菌体抗原库。通过对S-M1和S-M2的有效富集和筛选,分别得到14个和15个阳性克隆,序列分析初步揭示了抗体的抗原表位。因此,S蛋白噬菌体抗原库的构建为鉴定S蛋白的抗原表位提供了重要的技术平台,对研发SARS疫苗和诊断试剂具有重要的科学意义和应用价值。     

利用昆虫杆状病毒表达SARS冠状病毒的刺突蛋白和膜蛋白

SARS冠状病毒是人的严重急性呼吸综合征的病原体。对其他种类冠状病毒的研究结果显示,刺突蛋白(S蛋白)和膜蛋白(M蛋白)是病毒主要的结构蛋白。重组M蛋白和S蛋白可被用来作为抗原检测冠状病毒的感染和制备疫苗。这两个蛋白质分别被克隆并重组到昆虫杆状病毒基因组中,利用重组杆状病毒感染昆虫细胞来表达重组M蛋白和S蛋白,并对M蛋白进行了细胞内定位,融合蛋白的绿色荧光暗示了该蛋白质定位在细胞膜上。     

SARS 冠状病毒 S 蛋白受体结合结构域的表达及其表位作图

严重急性呼吸综合征 (SARS) 是一种新出现的人类传染病,该病的病原是 SARS 冠状病毒 (SARS-CoV). S 蛋白是 SARS 冠状病毒的一种主要结构蛋白,它在病毒与宿主细胞受体结合以及诱导机体产生中和抗体中起重要作用 . 研究表明 S 蛋白与受体结合的核心区域为第 318 ~ 510 氨基酸残基的片段 . 首先克隆并用 pGEX-6p-1 载体融合表达了该受体结合结构域,并且通过蛋白质印迹分析表明,该受体结合结构域融合蛋白能被 SARS 康复患者血清和 S 蛋白特异的单克隆抗体所识别 . 为了对这一区域进行抗原表位作图,进一步设计了一套 23 个覆盖受体结合结构域的长 16 个氨基酸残基的部分重叠短肽,并进行了 GST 融合表达 . 用免疫动物血清和单克隆抗体 D3D1 对 23 个融合蛋白进行蛋白质印迹和 ELISA 免疫反应性分析,结果鉴定出两个抗原表位 SRBD3(F334PSVYAWERKKISNCV349) 和表位 D3D1 (K447LRPFERDI455). 其结果对进一步分析 S 蛋白结构与功能以及诊断试剂和基因工程疫苗的研究有一定意义 .     

重组痘病毒表达SARS冠状病毒纤突蛋白及其免疫原性分析

对牛痘病毒弱毒株表达的SARS冠状病毒纤突蛋白(Spike protein,S)的免疫原性进行分析与比较.以减毒痘病毒(WR株)为载体重组了SARS冠状病毒全长S基因(rWR-SARS-S).SDS-PAGE和Western blot试验表明,迁移率约为190kD的重组SARS S蛋白可在HeLa细胞中表达,而且可以被鸡抗SARS全病毒高免血清识别,具有特异免疫反应原性.进一步研究表明,rWR-SARS-S感染的细胞在IFA试验中可与鸡抗SARS的高免血清发生特异反应,具有良好的敏感性和特异性.以104PFU的rWR-SARS-S免疫BALB/c小鼠产生的抗体在间接ELISA试验中可以被S蛋白识别,产生特异抗原抗体反应.利用痘病毒表达的SARS冠状病毒S蛋白具有良好的抗原性和生物学活性,可替代SARS冠状病毒全病毒,为研究安全、敏感和特异的重组诊断抗原奠定了重要基础.     

SARS冠状病毒刺突蛋白在裂殖酵母中的表达

根据SARS冠状病毒S蛋白主要抗原表位的分析,将S蛋白基因扩增成大小为800 bp～1000 bp的5个片段,分别与裂殖酵母载体pNMT1连接,经电穿孔转化TCP1菌株,得到诱导表达5个片段的裂殖酵母菌株。对诱导表达产物进行SDSPAGE和Western blot分析表明,S基因5个片段在裂殖酵母中分别得到不同程度的表达,为进一步研究新一代SARS疫苗提供了材料。     

SARS冠状病毒PLpro蛋白酶的结构与功能

SARS冠状病毒基因组编码2种病毒蛋白酶,即木瓜样蛋白酶（PLpro）和3C样蛋白酶(3CLpro).其中,PLpro蛋白酶结构与功能研究是近年来冠状病毒分子生物学研究的热点之一. PLpro蛋白酶参与SARS冠状病毒1a(1ab)复制酶多聚蛋白N端部分的切割加工,是SARS冠状病毒复制酶复合体(RC)形成的重要调节蛋白分子;最新研究表明,SARS冠状病毒PLpro蛋白酶是一种病毒编码的去泛素化酶（DUB）,对细胞蛋白具有明显去泛素化作用;而且对泛素(Ub)和泛素样分子ISG15均具有活性. PLpro蛋白酶对宿主抗病毒天然免疫反应具有负调节作用,是SARS冠状病毒的一种重要干扰素拮抗分子.PLpro蛋白酶是一种多功能病毒蛋白酶.本文结合作者课题组研究工作,对SARS冠状病毒PLpro蛋白酶结构和功能研究最新进展进行综述.     

SARS冠状病毒NS融合蛋白的重组表达纯化与免疫学性质分析(英文)

刺突蛋白(S)和核心蛋白(N)是SARS冠状病毒的主要结构蛋白.在病毒细胞受体结合和病毒包装过程起重要作用.重组融合表达这2种蛋白具有较高的诊断学价值.对SARS病毒N蛋白和S蛋白氨基酸序列进行计算机分析,选择含有优势抗原表位的N蛋白1～227位氨基酸片段和S蛋白450～650位氨基酸片段,采用序列重叠延伸策略(sequenceoverlappingextension,SOE)构建编码N1227LinkerS450650新型融合蛋白的基因片段,导入原核表达载体,实现融合蛋白在大肠杆菌的高效表达.利用组氨酸标签亲和层析的方法纯化,获得高纯度的融合蛋白.对该融合蛋白的结构特征模拟分析的结果显示,其免疫化学性质均无显著改变.采用ELISA和Western印迹方法对其识别SARS冠状病毒特异性抗体的能力进行初步鉴定,显示该融合蛋白具有较好的抗原性和特异性,可有效特异性地检测恢复期SARS病人血清中抗SARS冠状病毒结构蛋白的抗体,可以作为SARS冠状病毒感染的辅助诊断手段.     

B-cell responses in patients who have recovered from severe acute respiratory syndrome target a dominant site in the S2 domain of the surface spike glycoprotein

Severe acute respiratory syndrome (SARS) is a recently emerged infectious disease caused by a novel strain of coronavirus. Examination of the immune responses of patients who have recovered from SARS should provide important information for design of a safe and effective vaccine. We determined the continuous viral epitopes targeted by antibodies in plasma samples from convalescent SARS patients through biopanning with a vast M13 phage display dodecapeptide library. These epitopes converged to very short peptide fragments, one on each of the structural proteins spike and nucleocapsid and the nonstructural proteins 3a, 9b, and nsp 3. Immunoassays found that most of the patients who had recovered from SARS developed complementary antibodies to the epitope-rich region on the spike S2 protein, indicating that this is an immunodominant site on the viral envelope comprising the spike, matrix, and small envelope glycoproteins. These S2-targeting antibodies were shown to effectively neutralize the coronavirus, indicating that they provided protective immunity to help the patients recover from the viral infection. These results suggest that the SARS coronavirus might have an antigenic profile distinct from those of other human or animal coronaviruses. Due to the tested safety and protective effects of the convalescent-phase serological antibodies, identification of their complementary antigens may enable the design of an epitope-based vaccine to prevent potential antibody-mediated immunopathology.     

An exposed domain in the severe acute respiratory syndrome coronavirus spike protein induces neutralizing antibodies

Exposed epitopes of the spike protein may be recognized by neutralizing antibodies against severe acute respiratory syndrome (SARS) coronavirus (CoV). A protein fragment (S-II) containing predicted epitopes of the spike protein was expressed in Escherichia coli. The properly refolded protein fragment specifically bound to the surface of Vero cells. Monoclonal antibodies raised against this fragment recognized the native spike protein of SARS CoV in both monomeric and trimeric forms. These monoclonal antibodies were capable of blocking S-II attachment to Vero cells and exhibited in vitro antiviral activity. These neutralizing antibodies mapped to epitopes in two peptides, each comprising 20 amino acids. Thus, this region of the spike protein might be a target for generation of therapeutic neutralizing antibodies against SARS CoV and for vaccine development to elicit protective humoral immunity.     

Mosaic evolution of the severe acute respiratory syndrome coronavirus

Severe acute respiratory syndrome (SARS) is a deadly form of pneumonia caused by a novel coronavirus, a viral family responsible for mild respiratory tract infections in a wide variety of animals including humans, pigs, cows, mice, cats, and birds. Analyses to date have been unable to identify the precise origin of the SARS coronavirus. We used Bayesian, neighbor-joining, and split decomposition phylogenetic techniques on the SARS virus replicase, surface spike, matrix, and nucleocapsid proteins to reveal the evolutionary origin of this recently emerging infectious agent. The analyses support a mammalian-like origin for the replicase protein, an avian-like origin for the matrix and nucleocapsid proteins, and a mammalian-avian mosaic origin for the host-determining spike protein. A bootscan recombination analysis of the spike gene revealed high nucleotide identity between the SARS virus and a feline infectious peritonitis virus throughout the gene, except for a 200- base-pair region of high identity to an avian sequence. These data support the phylogenetic analyses and suggest a possible past recombination event between mammalian-like and avian-like parent viruses. This event occurred near a region that has been implicated to be the human receptor binding site and may have been directly responsible for the switch of host of the SARS coronavirus from animals to humans.     

Assembly of human severe acute respiratory syndrome coronavirus-like particles

Viral particles of human severe acute respiratory syndrome coronavirus (SARS CoV) consist of three virion structural proteins, including spike protein, membrane protein, and envelope protein. In this report, virus-like particles were assembled in insect cells by the co-infection with recombinant baculoviruses, which separately express one of these three virion proteins. We found that the membrane and envelope proteins are sufficient for the efficient formation of virus-like particles and could be visualized by electron microscopy. Sucrose gradient purification followed by Western blot analysis and immunogold labeling showed that the spike protein could be incorporated into the virus like particle also. The construction of engineered virus-like particles bearing resemblance to the authentic one is an important step towards the development of an effective vaccine against infection of SARS CoV.     

Gold nanoparticle-adjuvanted S protein induces a strong antigen-specific IgG response against severe acute respiratory syndrome-related coronavirus infection,but fails to induce protective antibodies and limit eosinophilic infiltration in lungs

The spike (S) protein of coronavirus, which binds to cellular receptors and mediates membrane fusion for cell entry, is a candidate vaccine target for blocking coronavirus infection. However, some animal studies have suggested that inadequate immunization against severe acute respiratory syndrome coronavirus (SARS-CoV) induces a lung eosinophilic immunopathology upon infection. The present study evaluated two kinds of vaccine adjuvants for use with recombinant S protein: gold nanoparticles (AuNPs), which are expected to function as both an antigen carrier and an adjuvant in immunization; and Toll-like receptor (TLR) agonists, which have previously been shown to be an effective adjuvant in an ultraviolet-inactivated SARS-CoV vaccine. All the mice immunized with more than 0.5 µg S protein without adjuvant escaped from SARS after infection with mouse-adapted SARS-CoV; however, eosinophilic infiltrations were observed in the lungs of almost all the immunized mice. The AuNP-adjuvanted protein induced a strong IgG response but failed to improve vaccine efficacy or to reduce eosinophilic infiltration because of highly allergic inflammatory responses. Whereas similar virus titers were observed in the control animals and the animals immunized with S protein with or without AuNPs, Type 1 interferon and pro-inflammatory responses were moderate in the mice treated with S protein with and without AuNPs. On the other hand, the TLR agonist-adjuvanted vaccine induced highly protective antibodies without eosinophilic infiltrations, as well as Th1/17 cytokine responses. The findings of this study will support the development of vaccines against severe pneumonia-associated coronaviruses.     

Antigenicity and receptor-binding ability of recombinant SARS coronavirus spike protein

Severe acute respiratory syndrome (SARS) is an emerging infectious disease associated with a novel coronavirus and causing worldwide outbreaks. SARS coronavirus (SARS-CoV) is an enveloped RNA virus, which contains several structural proteins. Among these proteins, spike (S) protein is responsible for binding to specific cellular receptors and is a major antigenic determinant, which induces neutralizing antibody. In order to analyze the antigenicity and receptor-binding ability of SARS-CoV S protein, we expressed the S protein in Escherichia coli using a pET expression vector. After the isopropyl-beta-D-thiogalactoside induction, S protein was expressed in the soluble form and purified by nickel-affinity chromatography to homogeneity. The amount of S protein recovered was 0.2-0.3mg/100ml bacterial culture. The S protein was recognized by sera from SARS patients by ELISA and Western blot, which indicated that recombinant S protein retained its antigenicity. By biotinylated ELISA and Western blot using biotin-labeled S protein as the probe, we identified 130-kDa and 140-kDa proteins in Vero cells that might be the cellular receptors responsible for SARS-CoV infection. Taken together, these results suggested that recombinant S protein exhibited the antigenicity and receptor-binding ability, and it could be a good candidate for further developing SARS vaccine and anti-SARS therapy.     

Construction of a eukaryotic expression plasmid encoding partial S gene fragments of the SARS-CoV and its potential utility as a DNA vaccine

The spike (S) protein, a main surface antigen of the SARS coronavirus (SARS-CoV), is considered to be one of the most important protective antigen candidates for targets for vaccine design against the virus. In this study, a secreted recombinant expression plasmid, pVAX-S1, encoding the partial S protein with a signal peptide, was constructed and used to immunize BALB/c mice through electroporation. It was demonstrated that the eukaryotic expression vector pVAX-S1 was successfully constructed by restriction enzyme and sequence analysis. The expressed protein could be detected specifically by Western blot analysis. The serum IgG level of the vaccine group mice was significantly higher than that of the corresponding control group at day 14 after vaccination (P < 0.05). The vaccine group demonstrated significantly higher S1 protein lymphocyte proliferation index (LPI) than the control groups (P < 0.05). Furthermore, in the experimental group, a decrease in the ratio of CD4(+) to CD8(+) T-lymphocytes and an increase level of IFN-gamma in serum were observed. However, interleukin-4 (IL-4) was not detectable in two groups. These results strongly demonstrated that the pVAX-S1 plasmid could induce humoral and cellular immune responses in mice, and may be a potential candidate for a DNA vaccine against the SARS coronavirus.     

SARS亚基疫苗-突刺蛋白受体结合区RBD在烟草叶绿体中的高效表达

叶绿体表达系统为植物源重组药用蛋白和亚基疫苗的生产提供了一个有效的途径。为验证SARS亚基疫苗在叶绿体中表达的可行性,以及为植物源SARS亚基疫苗的生产提供一套高效、低成本的技术平台,本研究将人工优化合成的SARS-CoV突刺蛋白(S蛋白)受体结合区序列RBD与载体分子CTB融合基因导入烟草叶绿体基因组中。PCR和Southern杂交分析表明,外源融合基因已整合到烟草叶绿体基因组中,并获得同质化。Western杂交分析表明,重组融合蛋白CTB-RBD在叶绿体转基因烟草中获得表达,且主要以可溶性单体形式存在。ELISA分析表明,在不同生长阶段、不同生长部位和不同时间点烟草叶片中,重组融合蛋白CTB-RBD的表达水平呈现明显的变化。重组蛋白在成熟叶片中的表达水平最高可以达到10.2%TSP。本研究通过SARS亚基疫苗RBD在烟草叶绿体中的高效表达,有望为植物源SARS亚基疫苗的生产以及SARS血清抗体的检测提供一个有效的技术平台。     

Characterization of the 3a protein of SARS-associated coronavirus in infected vero E6 cells and SARS patients

Proteomics was used to identify a protein encoded by ORF 3a in a SARS-associated coronavirus (SARS-CoV). Immuno-blotting revealed that interchain disulfide bonds might be formed between this protein and the spike protein. ELISA indicated that sera from SARS patients have significant positive reactions with synthesized peptides derived from the 3a protein. These results are concordant with that of a spike protein-derived peptide. A tendency exists for co-mutation between the 3a protein and the spike protein of SARS-CoV isolates, suggesting that the function of the 3a protein correlates with the spike protein. Taken together, the 3a protein might be tightly correlated to the spike protein in the SARS-CoV functions. The 3a protein may serve as a new clinical marker or drug target for SARS treatment.