戊型肝炎病毒衣壳蛋白中和表位间的构象诱导

重组蛋白NE2包含了戊型肝炎病毒(HEV)衣壳蛋白(pORF2)的aa394～606片段.在NE2上已鉴定出了2个HEV中和表位,并获得了3个识别中和表位的单克隆抗体(MAb)8C11、13D8和8H3.这3个MAb间的交叉阻断ELISA实验发现,8C11和13D8可以彼此完全阻断,8H3对8C11和13D8均不能阻断,而8C11非但不能阻断8H3,反而显著增强了8H3与抗原的结合.用生物传感器进行的抗体与抗原结合的动力学分析也证实了这一现象.这些结果提示,在NE2上8H3表位区域受到抗原上某些结构的掩盖,而8C11与NE2的结合引起了抗原空间结构的改变,导致了掩盖8H3表位的结构的去除和8H3表位的充分暴露.免疫捕获RT-PCR发现,8C11同样可以显著增强8H3对天然HEV病毒的捕获能力,提示这种结合诱导的衣壳蛋白空间构象改变在天然HEV病毒颗粒上同样存在.     

昆虫质型多角体病毒的研究进展

质型多角体病毒(Cytoplasmic polyhedrosis virus,CPV)隶属呼肠孤病毒科Reoviridae质型多角体病毒属Cypovirus,通常基因组由10个节段双链RNA构成。RNA分子量为3～27u。根据病毒基因组dsRNA片段在聚丙烯酰胺或琼脂糖凝胶中电泳图谱的差异,目前CPV已被分为19个电泳型。不同于呼肠孤病毒科其它成员,CPV为单层衣壳,而不是常见的双层衣壳结构,衣壳蛋白主要由衣壳蛋白、大突起蛋白及塔式突起蛋白组成。大部分质型多角体病毒引起昆虫慢性疾病,造成寄主死亡或适应性降低。随着RNA病毒基因序列测定技术的成熟,质型多角体病毒的序列测定方面取得较大进展,目前GenBank核苷酸序列数据库中已经公布了家蚕Bombyx mori CPV电泳型1两个株系(H株和I株)、舞毒蛾Lymantria dispar CPV电泳型1、舞毒蛾CPV电泳型14及粉纹夜蛾Trichoplusia ni CPV电泳型全基因组序列,为该病毒的进化与起源的研究提供更多的遗传信息。本文从结构功能、侵染特点、基因组特点及应用前景等方面综述了昆虫质型多角体病毒的研究进展。     

装载戊型肝炎病毒核酸片段的重组MS2噬菌体衣壳的制备及其特性研究

为制备一种可以实际应用于戊型肝炎病毒(Hepatitis E virus,HEV)核酸检测的质控品,即装载戊型肝炎病毒核酸片段的重组MS2噬菌体衣壳(rHEPC)。根据装甲RNA技术原理,设计将MS2噬菌体基因组的5’端部分非编码区、成熟酶蛋白、衣壳蛋白以及部分复制酶起始位点等编码基因与HEV ORF2保守区部分基因序列串联并合成目标基因MS2-HEV。随后将MS2-HEV基因克隆、插入原核表达载体pET-28b中构建pET-28b-MS2/HEV重组质粒,转化大肠杆菌感受态细胞BL21(DE3),经过1mM/L IPTG诱导培养4h后,SDS-PAGE鉴定表达情况;将验证的表达菌体超声破碎、离心、取上清、去除核酸杂质后再经超滤离心纯化、浓缩,电镜分析回收浓缩的rHEPC形态;梯度稀释rHEPC进行稳定性鉴定包括DNase I、RNase A抗性以及保存期三方面的稳定性试验检测。SDS-PAGE分析结果表明重组MS2-HEV基因获得有效表达,重组rHEPC纯度高无杂带;RT-PCR鉴定结果表明设计的HEV保守基因序列成功地被包装到重组rHEPC中。进一步的病毒颗粒稳定性试验结果表明制备的rHEPC能够有效抵抗高浓度的DNase I和RNase A的降解作用,并且在-20℃条件下可以持续保存7个月而无明显降解。上述结果表明制备的rHEPC达到了作为RNA病毒核酸检测阳性质控品的基本要求。     

RNA噬菌体病毒样颗粒包装机制及其应用研究进展

RNA噬菌体是一类结构简单的较小病毒,病毒衣壳为T=3的20面体对称结构,由180拷贝的衣壳蛋白亚基组成,其基因组为正义单链RNA,约含有3500个核苷酸,具有mRNA的作用,编码4种蛋白:病毒衣壳蛋白,成熟酶蛋白,复制酶亚基和裂解蛋白.这些噬菌体最初从大肠埃希菌属中分离出,尽管后来在柄杆菌属和假单胞菌属中也被陆续发现,但迄今为止,对大肠埃希菌噬菌体的研究最为广泛和透彻,根据血清学和生化性质的不同,此类噬菌体可被分成4个类群.     

戊型肝炎病毒载体疫苗的研发

<正>戊型肝炎病毒是一种单链核糖核酸构成的无包膜病毒,通过粪口途径传播,会导致人类的急性肝炎。当前市面上无戊型肝炎疫苗(HEV)可用。HEV繁殖缺乏合适的细胞培养系统,HEV假衣壳(ORF2蛋白)既可以在大肠杆菌、也可以在昆虫细胞中产生,在猴子抗病毒和避免人感染HEV方面这种伪衣壳都是有效的。我们计划开发一种新的抗HEV感染的疫苗,其使用腺相关病毒(AAV)作为HEV衣     

HepG2细胞中与戊型肝炎病毒衣壳蛋白相互作用蛋白的初步研究

利用重组戊型肝炎病毒(HEV)衣壳蛋白片段p239(368~606 aa)形成的类病毒颗粒作为亲和层析诱饵蛋白,HepG2为细胞模型,筛选与p239类病毒颗粒特异性相互作用蛋白。经过二维电泳分离,MALDI-TOF-MS分析鉴定得到GRP78/Bip,HSP90,alpha-tubulin及P43四个与p239有相互作用的候选蛋白。GRP78/Bip为热休克蛋白家族成员,体外免疫共沉淀实验结果证实,其与p239有特异性的结合。此研究结果为深入研究HEV的感染过程如吸附、入胞,以及HEV的致病机理提供了有益线索。     

流感病毒A非结构蛋白功能的研究进展

流感病毒属正粘病毒科(Orthomyxoviridae),是一种带包膜并且分节段的单负链RNA病毒。根据病毒核衣壳蛋白(Nucleocapsid)和基质蛋白(Matrix,M)抗原性的差异,流感病毒可分为甲、乙、丙3个型。甲型流感病毒呈球形或丝状,其RNA基因组总长度在13.6kb左右,分为8个节段,共编码10个蛋白     

戊型肝炎病毒颗粒性蛋白疫苗H-2d限制性Th表位的筛选

戊型肝炎病毒衣壳蛋白重组抗原HEV 239能形成类病毒颗粒,具备演变成多价疫苗的载体的潜力,此文旨在筛选、鉴定其内包含的H-2d限制性Th表位。以50μg HEV 239蛋白与完全弗式佐剂混合后皮下免疫BALB/c鼠,以覆盖HEV 239蛋白全长的15氨基酸肽库体外刺激其脾细胞,用IFN--γELISPOT方法检测其细胞免疫应答,并通过磁珠剔除脾细胞中CD4 T细胞或CD8 T细胞以分析筛选得到的T细胞表位的特性。结果显示:HEV 239中包含优势的T细胞表位P34(HEV PORF2 AA533~AA547,HSKTF FVLPL RGKLS)及数个较弱的T细胞表位,P34对HEV 239免疫的BALB/c鼠脾细胞的刺激效果与HEV 239蛋白相当,剔除实验表明该表位为CD4 T细胞表位,即Th表位。     

急性呼吸道感染儿童中WU多瘤病毒基因组序列特征分析

为了解从北京地区急性呼吸道感染儿童中发现的WU多瘤病毒的基因组编码特征,并对其进行基因序列多样性分析,应用针对基因组5'端非编码区、衣壳蛋白VP1、VP2编码基因以及LTAg编码基因的引物对,从已确证为WU病毒阳性的来自北京地区急性呼吸道感染儿童的编号为BJF5276的临床标本中经聚合酶链反应扩增得到预期的基因片段,直接测序后将序列拼接得到全基因组序列,进而推导其基因组编码特征;随后从其它21例已确证为WU多瘤病毒阳性的急性呼吸道感染儿童标本中扩增得到衣壳蛋白VP2编码区基因,进行基因序列测定以及基因序列多样性分析。得到了WU病毒BJF5276全基因组序列。序列分析结果显示WU病毒BJF5276基因组序列全长为5229bp,共有5个主要的CDS(Coding domain sequences),分别编码衣壳蛋白VP2、VP3、VP1,并以其互补序列为模板,编码STAg和LTAg;所得到的22例VP2蛋白编码区基因序列同源性比较结果显示病毒VP2基因编码区序列与GenBank中已有的64个序列之间同源性很高;Mega4.0NJ进化树(Neighbor-joiningtree)分析显示这22个VP2基因序列分属于不同的基因进化簇,其中20个序列属于进化簇I中的Ia,另外2个序列属于进化簇III,其中的一个序列在IIIb基因进化簇中,另外一个序列独立成簇,不属于现有的IIIa或IIIb,暂时将其命名为IIIc。本研究结果提示北京地区的WU病毒具有多瘤病毒科的基因组编码特性;序列非常保守,有分属于不同基因进化簇的WU病毒在北京地区流行,与文献报道的以Ib流行为主所不同的是北京地区的WU病毒以Ia为主,且有新的基因进化簇出现。     

携带EGFP基因的戊型肝炎病毒重组质粒的构建及其感染性的验证

为了构建携带增强型绿色荧光蛋白(Enhanced green fluorescent protein,EGFP)基因的戊型肝炎病毒(Hepatitis E virus,HEV)重组质粒,转染人肺癌细胞A549细胞验证其感染性,PCR法分两段扩增HEV全基因组序列和EGFP基因序列,将EGFP报告基因插入到HEV ORF2基因下游,并克隆到体外转录表达载体pGEM-7Zf(+)上。然后利用脂质体转染法将重组质粒转入A549细胞,24h后在荧光显微镜下观察EGFP的表达;转染72h后,利用免疫荧光法检测HEV ORF2蛋白的表达。转染7d后将发生病变的A549细胞收集作为接种物,接种A549细胞验证携带EGFP的HEV-EGFP重组病毒的感染性。结果显示经酶切和测序鉴定携带EGFP的HEV重组表达质粒pGEM-HEV-EGFP构建成功;EGFP基因与HEV在A549细胞中可融合表达;携带EGFP的HEV重组表达质粒转染A549细胞7d后出现病变,并且连续传代3代仍具有感染性。本研究成功构建了携带EGFP的HEV全基因组重组质粒pGEM-HEV-EGFP,并成功感染A549细胞,为进一步研究HEV的复制机制及致病机理奠定基础。     

C-Terminal Amino Acids 471-507 of Avian Hepatitis E Virus Capsid Protein Are Crucial for Binding to Avian and Human Cells

The infection of chickens with avian Hepatitis E virus (avian HEV) can be asymptomatic or induces clinical signs characterized by increased mortality and decreased egg production in adult birds. Due to the lack of an efficient cell culture system for avian HEV, the interaction between virus and host cells is still barely understood. In this study, four truncated avian HEV capsid proteins (ORF2-1 – ORF2-4) with an identical 338aa deletion at the N-terminus and gradual deletions from 0, 42, 99 and 136aa at the C-terminus, respectively, were expressed and used to map the possible binding site within avian HEV capsid protein. Results from the binding assay showed that three truncated capsid proteins attached to avian LMH cells, but did not penetrate into cells. However, the shortest construct, ORF2-4, lost the capability of binding to cells suggesting that the presence of amino acids 471 to 507 of the capsid protein is crucial for the attachment. The construct ORF2-3 (aa339-507) was used to study the potential binding of avian HEV capsid protein to human and other avian species. It could be demonstrated that ORF2-3 was capable of binding to QT-35 cells from Japanese quail and human HepG2 cells but failed to bind to P815 cells. Additionally, chicken serum raised against ORF2-3 successfully blocked the binding to LMH cells. Treatment with heparin sodium salt or sodium chlorate significantly reduced binding of ORF2-3 to LMH cells. However, heparinase II treatment of LMH cells had no effect on binding of the ORF2-3 construct, suggesting a possible distinct attachment mechanism of avian as compared to human HEV. For the first time, interactions between avian HEV capsid protein and host cells were investigated demonstrating that aa471 to 507 of the capsid protein are needed to facilitate interaction with different kind of cells from different species.     

CD63在戊型肝炎病毒感染中的作用机制

本研究旨在寻找戊型肝炎病毒(hepatitis E virus,HEV)衣壳蛋白ORF2的相互作用蛋白,探讨其在HEV感染中的作用。采用酵母双杂交方法从人肝细胞文库中筛选与HEV ORF2相互作用的蛋白,结果显示CD63与HEV ORF2相互作用。Pull-down实验提示原核表达的ORF2与CD63结合较弱,而免疫共沉淀实验提示真核表达的ORF2能与CD63结合。流式细胞术检测结果显示,HEV易感细胞PLC/PRF/5细胞膜表面的CD63表达水平普遍低于HEV非易感细胞。过表达CD63抑制PLC/PRF/5细胞的HEV感染,而小干扰RNA(small interfering RNA,siRNA)干扰CD63表达则促进HEV感染。结果提示,CD63能与HEV ORF2相互作用,可能抑制HEV感染肝细胞。     

Dimerization of Hepatitis E Virus Capsid Protein E2s Domain Is Essential for Virus–Host Interaction

Hepatitis E virus (HEV), a non-enveloped, positive-stranded RNA virus, is transmitted in a faecal-oral manner, and causes acute liver diseases in humans. The HEV capsid is made up of capsomeres consisting of homodimers of a single structural capsid protein forming the virus shell. These dimers are believed to protrude from the viral surface and to interact with host cells to initiate infection. To date, no structural information is available for any of the HEV proteins. Here, we report for the first time the crystal structure of the HEV capsid protein domain E2s, a protruding domain, together with functional studies to illustrate that this domain forms a tight homodimer and that this dimerization is essential for HEV–host interactions. In addition, we also show that the neutralizing antibody recognition site of HEV is located on the E2s domain. Our study will aid in the development of vaccines and, subsequently, specific inhibitors for HEV.     

A Comprehensive Study of Neutralizing Antigenic Sites on the Hepatitis E Virus (HEV) Capsid by Constructing,Clustering, and Characterizing a Tool Box

The hepatitis E virus (HEV) ORF2 encodes a single structural capsid protein. The E2s domain (amino acids 459–606) of the capsid protein has been identified as the major immune target. All identified neutralizing epitopes are located on this domain; however, a comprehensive characterization of antigenic sites on the domain is lacking due to its high degree of conformation dependence. Here, we used the statistical software SPSS to analyze cELISA (competitive ELISA) data to classify monoclonal antibodies (mAbs), which recognized conformational epitopes on E2s domain. Using this novel analysis method, we identified various conformational mAbs that recognized the E2s domain. These mAbs were distributed into 6 independent groups, suggesting the presence of at least 6 epitopes. Twelve representative mAbs covering the six groups were selected as a tool box to further map functional antigenic sites on the E2s domain. By combining functional and location information of the 12 representative mAbs, this study provided a complete picture of potential neutralizing epitope regions and immune-dominant determinants on E2s domain. One epitope region is located on top of the E2s domain close to the monomer interface; the other is located on the monomer side of the E2s dimer around the groove zone. Besides, two non-neutralizing epitopes were also identified on E2s domain that did not stimulate neutralizing antibodies. Our results help further the understanding of protective mechanisms induced by the HEV vaccine. Furthermore, the tool box with 12 representative mAbs will be useful for studying the HEV infection process.     

戊型肝炎病毒细胞吸附模型的建立及病毒吸附区域初步研究

E.coli中表达的HEV衣壳蛋白片段P239(aa368~606)形成的类病毒颗粒与戊肝患者恢复期血清及中和单抗具有良好的反应性,较好地模拟了天然HEV病毒颗粒的表面空间结构。利用P239吸附HepG2细胞的模型来模拟HEV对宿主细胞的吸附,多株中和单抗对吸附的阻断验证了吸附的特异性。P239与多株传代细胞系的吸附结果则表明了这种特异性吸附的细胞选择性。对阻断P239吸附的线性单抗进行定位,初步确定了P239与细胞相互作用的区域:ORF2上的aa423~443很可能和病毒上的细胞膜受体结合部位非常靠近,或可能直接参与构成了病毒与细胞特异性识别的表位。此本研究为进一步研究HEV与宿主细胞的相互作用提供一定的线索。     

Mutational analysis of the hypervariable region of hepatitis e virus reveals its involvement in the efficiency of viral RNA replication

The RNA genome of the hepatitis E virus (HEV) contains a hypervariable region (HVR) in ORF1 that tolerates small deletions with respect to infectivity. To further investigate the role of the HVR in HEV replication, we constructed a panel of mutants with overlapping deletions in the N-terminal, central, and C-terminal regions of the HVR by using a genotype 1 human HEV luciferase replicon and analyzed the effects of deletions on viral RNA replication in Huh7 cells. We found that the replication levels of the HVR deletion mutants were markedly reduced in Huh7 cells, suggesting a role of the HVR in viral replication efficiency. To further verify the results, we constructed HVR deletion mutants by using a genetically divergent, nonmammalian avian HEV, and similar effects on viral replication efficiency were observed when the avian HEV mutants were tested in LMH cells. Furthermore, the impact of complete HVR deletion on virus infectivity was tested in chickens, using an avian HEV mutant with a complete HVR deletion. Although the deletion mutant was still replication competent in LMH cells, the complete HVR deletion resulted in a loss of avian HEV infectivity in chickens. Since the HVR exhibits extensive variations in sequence and length among different HEV genotypes, we further examined the interchangeability of HVRs and demonstrated that HVR sequences are functionally exchangeable between HEV genotypes with regard to viral replication and infectivity in vitro, although genotype-specific HVR differences in replication efficiency were observed. The results showed that although the HVR tolerates small deletions with regard to infectivity, it may interact with viral and host factors to modulate the efficiency of HEV replication.     

The carboxy-terminal two-thirds of the cowpea chlorotic mottle bromovirus capsid protein is incapable of virion formation yet supports systemic movement.

Previous investigations into recombination in cowpea chlorotic mottle bromovirus (CCMV) resulted in the recovery of an unusual recombinant virus, 3-57, which caused a symptomless infection of cowpeas but formed no detectable virions. Sequence analysis of cDNA clones derived from 3-57 determined that mutations near the 5' terminus of the capsid protein gene introduced an early translational termination codon. Further mutations introduced a new in-frame start codon that allowed translation of the 3' two-thirds of the capsid protein gene. Based on the mutations observed in 3-57, wild-type CCMV clones were modified to determine if the carboxyl two-thirds of the capsid protein functions independently of the complete protein in long-distance movement. Analysis of these mutants determined that while virion formation is not required for systemic infection, the carboxy-terminal two-thirds of the capsid protein is both required and sufficient for systemic movement of viral RNA. This indicates that the CCMV capsid protein is multifunctional, with a distinct long-distance movement function in addition to its role in virion formation.     

Identification of immunodominant and conformational epitopes in the capsid protein of hepatitis E virus by using monoclonal antibodies

Antibody to the capsid (PORF2) protein of hepatitis E virus (HEV) is sufficient to confer immunity, but knowledge of B-cell epitopes in the intact capsid is limited. A panel of murine monoclonal antibodies (MAbs) was generated following immunization with recombinant ORF2.1 protein, representing the C-terminal 267 amino acids (aa) of the 660-aa capsid protein. Two MAbs reacted exclusively with the conformational ORF2.1 epitope (F. Li, J. Torresi, S. A. Locarnini, H. Zhuang, W. Zhu, X. Guo, and D. A. Anderson, J. Med. Virol. 52:289-300, 1997), while the remaining five demonstrated reactivity with epitopes in the regions aa 394 to 414, 414 to 434, and 434 to 457. The antigenic structures of both the ORF2.1 protein expressed in Escherichia coli and the virus-like particles (VLPs) expressed using the baculovirus system were examined by competitive enzyme-linked immunosorbent assays (ELISAs) using five of these MAbs and HEV patient sera. Despite the wide separation of epitopes within the primary sequence, all the MAbs demonstrated some degree of cross-inhibition with each other in ORF2. 1 and/or VLP ELISAs, suggesting a complex antigenic structure. MAbs specific for the conformational ORF2.1 epitope and a linear epitope within aa 434 to 457 blocked convalescent patient antibody reactivity against VLPs by approximately 60 and 35%, respectively, while MAbs against epitopes within aa 394 to 414 and 414 to 434 were unable to block patient serum reactivity. These results suggest that sequences spanning aa 394 to 457 of the capsid protein participate in the formation of strongly immunodominant epitopes on the surface of HEV particles which may be important in immunity to HEV infection.