反转录病毒MSCV介导汉坦病毒核蛋白基因在NIH3T3细胞中整合和表达

汉坦病毒是引起肾综合征出血热(HFRS)和汉坦病毒型肺炎综合征(HPS)的主要病原体.由S基因编码的核蛋白(NP)主要与机体的细胞免疫有关,并调节病毒的复制及诱导细胞程序性死亡.构建了汉坦病毒Z10株核蛋白cDNA与含有pac基因的反转录病毒鼠干细胞病毒(MSCV)重组体MSCV-FlagNP,通过磷酸钙转录法导入产病毒的包装细胞系BOSC23中,产生完整的重组MSCV-FlagNP病毒.然后以重组病毒感染NIH 3T3细胞,利用Puromycin的选择特性(pac基因)对感染细胞进行连续压力筛选,获得了转核蛋白抗性细胞.利用Southern blot和PCR方法分别对核蛋白基因在抗性细胞染色体整合情况及其完整性进行了鉴定.并且用Western blot在抗性细胞中可检测到核蛋白的表达.进一步以Flag单克隆抗体介导的免疫荧光染色联合共聚焦激光扫描荧光显微镜,分析了内源性Flag融合核蛋白在抗性细胞内分布,发现核蛋白主要分布于胞浆及胞核周围区,并且部分核蛋白可聚集形成胞浆包涵体.转核蛋白基因细胞模型的建立,对进一步研究汉坦病毒核蛋白功能以及病毒复制机制有重要意义.     

抗汉坦病毒核蛋白单链抗体的构建与表达

汉坦病毒核蛋白在病毒各个基因组片段核糖核蛋白(RNP)复合物的形成,以及RNP复合物装配入病毒颗粒中发挥重要作用。体外研究表明,核蛋白与病毒RNA的特异性结合结构域位于第175—217个氨基酸残基,羧基端其它部分为非特异性结合结构域。为了在细胞内病毒复制的正常过程中研究核蛋白的功能,应用噬菌体表面呈现技术,分别从鼠杂交瘤细胞和人外周血淋巴细胞天然抗体库中,筛选出两株不同抗原结合位点的抗汉坦病毒核蛋白抗体L13 F3和H34Fab抗体,并在大肠杆菌中进行表达。L13 F3 Fab抗体的抗原结合位点位于核蛋白氨基端25—65个氨基酸之间,H34的抗原结合位点位于核蛋白的羧基端的一半。分别使重链可变区羧基端与轻链可变区氨基端通过9个氨基酸寡肽连接起来,构建成单链抗体,并在大肠杆菌内进行表达。通过酶联免疫吸附试验(EL-SIA)、间接免疫荧光试验(IFA)和Western blot检测,确定所构建单链抗体与母抗体的抗原结合特性无差别。单链抗体分子量小,易于操作并保留了全部的抗原结合活性,是在细胞内探索汉坦病毒核蛋白功能的良好工具。     

BSP基因RNA干扰对乳腺癌MDA-MB-231BO细胞生物学特性的影响

旨在研究RNA干扰(RNA interference,RNAi)抑制骨唾液酸蛋白(bone sialoprotein,BSP)基因表达后对人乳腺癌细胞MDA-MB-231BO生物学特性的影响。应用pSilencer5.1-U6Retro构建针对BSP基因的siRNA逆转录病毒重组表达质粒,将重组质粒转染293细胞制备病毒悬液感染MDA-MB-231BO细胞,利用嘌呤霉素筛选抑制BSP表达的乳腺癌细胞。Western blotting检测细胞内BSP蛋白表达,采用MTT法和集落形成试验检测细胞的增殖,流式细胞仪检测细胞周期变化。结果显示,成功构建BSP基因RNAi稳定转染的231BO-BSP27细胞。231BO-BSP27细胞内BSP蛋白表达抑制率为69.3%,与对照组细胞相比,231BO-BSP27细胞的生长速率和克隆形成率明显降低;S期细胞数量明显减少,G0/G1期细胞增多。由此证实,逆转录病毒介导的RNAi能实现BSP基因稳定沉默,从而抑制MDA-MB-231BO细胞的生长和增殖。     

汉坦病毒嵌合基因 G2S0.7在昆虫细胞中融合表达产物的免疫学研究

在前期工作基础上,对汉坦病毒糖蛋白(GP)和核蛋白(NP)的嵌合基因G2S0．7表达产物的免疫学特性进行进一步的研究。将汉坦病毒含有G2S0．7嵌合基因的重组杆状病毒在昆虫细胞中融合表达并免疫BALB／c小鼠,用ELISA、微量细胞培养中和实验及淋巴细胞增殖实验检测免疫应答效果,以研究嵌合基因的免疫效果。结果表明,用该融合蛋白免疫小鼠,可诱导产生抗汉坦病毒NP及GP特异性的抗体,抗体效价分别为1：3200及1：200;同时融合蛋白还可刺激机体产生低水平的中和抗体和明确的淋巴细胞增殖反应。说明汉坦病毒G2S0．7嵌合基因表达的融合蛋白既可刺激机体产生特异性的抗汉坦病毒体液免疫应答,也可刺激机体产生特异性的细胞免疫应答,为进一步进行汉坦病毒基因工程疫苗的研究奠定了实验基础。     

人突触相关蛋白抗原表位分析、抗体制备及表达研究

突触相关蛋白家族成员的功能与神经突触膜上的谷氨酸酯受体和钾离子通道的定位和功能有关,参与神经递质的释放、神经的生长、发育及修复.为分析一个新的人突触相关蛋白基因（FRG4）的抗原表位和该蛋白质在血管细胞的表达,从人胎肝文库PCR扩增获得FRG4基因全长cDNA序列.通过生物信息学分析,预测FRG4编码氨基酸序列的二级结构、抗原决定簇和功能结构域;选取抗原13肽PKLVKEEVFWRNY,采用固相多肽合成法合成了FRG4抗原多肽,免疫新西兰白兔获得兔抗人FRG4多抗;免疫组化检测该蛋白质在人血管细胞中的表达.高效液相色谱检测显示制备的兔抗人FRG4多克隆抗体纯度达82.79%,抗体滴度为1∶16 000,蛋白质印迹证实该抗体具有较好的反应性和特异性,免疫组化证实,其主要在平滑肌细胞和内皮细胞的胞浆中表达.结果表明,成功制备了兔抗人FRG4抗体,FRG4蛋白主要在细胞胞浆中表达,与生物信息学分析结果一致.     

胞内抗体技术及医学应用

胞内抗体技术是近年来随抗体工程技术发展起来的一项新型基因治疗方法．它将单链抗体表达于非淋巴细胞内,并使之定向分布于细胞核、细胞浆或内质网等部位,特异性阻断、干扰分布于该部位的大分子物质生物活性或加工分泌过程．实验证明该技术能抑制生长因子受体的表达,灭活原癌基因蛋白,抑制病毒复制．在生物科学及医学研究中具有很大应用潜力．     

逆转录病毒介导诱导型一氧化氮合酶基因转染抑制血管平滑肌细胞增殖的研究

目的：研究逆转录病毒介导诱导型一氧化氮合酶（iNOS）基因转染对体外培养的大鼠主动脉血管平滑肌细胞（VSMC）增殖的影响,探讨iNOS转基因治疗血管移植术后再狭窄的可行性。方法：将不同滴度的病毒上清转染体外培养的VSMC;采用RT-PCR、Western-blot检测VSMC内iNOSmRNA和iNOS蛋白的表达;用Griess法检测iNOS转基因细胞的培养液中一氧化氮（NO）的含量;用改良MTT、法检测iNOS转基因对VSMC增殖的抑制作用。结果：不同滴度的PLXSNiNOS转染体外培养的VSMC48h后,在VSMC内可检测到外源性iNOSmRNA和iNOS蛋白,表达水平随病毒滴度的增加而增强,呈现剂量依赖性;而用最高滴度的PIXSN转染体外培养的VSMC48h后,在VSMC内未能检测到外源性iNOSmRNA和iNOS蛋白表达;iNOS转基因细胞的培养液中NO含量显著增高,同时VSMC增殖受到明显抑制,均呈现剂量依赖性。结论：逆转录病毒介导iNOS基因可高效转染体外培养的VSMC,并在细胞内表达活性的iNOS蛋白,而且产生大量的NO,明显抑制VSMC增殖。为iNOS转基因治疗血管移植术后再狭窄的临床应用提供有力的实验依据。     

BrdU标记的人巨细胞病毒感染HEL细胞的方法学研究

目的 以标记在人巨细胞病毒(HCMV)DNA上的BrdU为示踪剂,研究病毒在受染HEL细胞中的移动过程;同时结合病毒蛋白pp65的表达探讨病毒复制、增殖的过程。方法 以BrdU标记的HCMV(MOI=4)感染HEL细胞,分别选取感染后2h、4h、6h、24h及48h 5个时间点的细胞,用抗BrdU单克隆抗体,研究病毒核酸的胞内定位;同时用抗HCMV蛋白pp65的单克隆抗体检测此蛋白的表达及分布。结果 免疫细胞荧光染色结果提示:在感染5个时间点,病毒DNA依次位于胞质、胞核及同时位于胞核和胞质;蛋白pp65的表达及分布规律为:胞内无表达、胞核分布、胞核与胞质同时分布及巨细胞和融合细胞内分布。结论 以BrdU为标记物标记双链DNA病毒核酸不仅为研究HCMV．的胞内移动提供了良好的模型,同时也为其他病毒的研究提供了良好的工具;本实验结合HCMV蛋白pp65的表达和分布直观地反应了HCMV感染HEL细胞并在其中复制、增殖的过程。     

大鼠高血压相关基因表达蛋白抑制血管平滑肌细胞增殖

大鼠高血压相关基因 ( r HRG- 1 )编码一新细胞内信号传递蛋白 .体外转染 r HRG- 1表达蛋白发现 r HRG- 1表达蛋白能抑制自发性高血压大鼠血管平滑肌细胞内 Raf蛋白 ( Raf- 1 )和丝裂素活化蛋白激酶 ( MAPK)活性 ,抑制抗细胞凋亡基因 ( bcl- 2 )和增殖细胞核抗原 ( PCNA)基因 m RNA表达 ,同时还抑制该细胞 DNA的合成 .r HRG- 1是一正常血压大鼠血管平滑肌细胞内高度表达的基因 ,由此推测在自发性高血压大鼠血管平滑肌细胞内转染 r HRG- 1表达蛋白抑制其细胞 DNA合成的作用可能是抑制细胞内 Raf- 1活性与 MAPK活性及抑制 PCNA和 bcl- 2基因表达的结果     

Viperin抑制黄病毒属感染作用机制研究进展

Viperin是近年来发现的具有重要免疫活性的宿主蛋白之一,其在细胞内的表达在病毒感染或干扰素诱导后明显上升,显示出广泛的抗病毒活性。已证实它可以影响许多囊膜病毒在宿主细胞中的组装和释放,但在不同的病毒中所表现的具体抗病毒活性不同。黄病毒属病毒为单股正链具囊膜的RNA病毒,该种属病毒具有相似的结构特征。Viperin蛋白可以抑制多数黄病毒在细胞中的复制。就Viperin抗几种黄病毒属病毒作用机制进行综述,为相关研究提供参考。     

Intracellular neutralization of influenza virus by immunoglobulin A anti-hemagglutinin monoclonal antibodies.

Traditionally, immunoglobulin A (IgA) was thought to neutralize virus by forming complexes with viral attachment proteins, blocking attachment of virions to host epithelial cells. Recently we have proposed an intracellular action for dimeric IgA, which is actively transported through epithelial cells by the polymeric immunoglobulin receptor (pIgR), in that it may be able to bind to newly synthesized viral proteins within the cell, preventing viral assembly. To this effect, we have previously demonstrated that IgA monoclonal antibodies against Sendai virus, a parainfluenza virus, colocalize with the viral hemagglutinin-neuraminidase protein within infected epithelial cells and reduce intracellular viral titers. Here we determine whether IgA can interact with influenza virus hemagglutinin (HA) protein within epithelial cells. Polarized monolayers of Madin-Darby canine kidney epithelial cells expressing the pIgR were infected on their apical surfaces with influenza virus A/Puerto Rico/8-Mount Sinai. Polymeric IgA anti-HA, but not IgG anti-HA, delivered to the basolateral surface colocalized with HA protein within the cell by immunofluorescence. Compared with those of controls, viral titers were reduced in the supernatants and cell lysates from monolayers treated with anti-HA IgA but not with anti-HA IgG. Furthermore, the addition of anti-IgA antibodies to supernatants did not interfere with the neutralizing activity of IgA placed in the basal chamber, indicating that IgA was acting within the cell and not in the extracellular medium to interrupt viral replication. Thus, these studies provide additional support for the concept that IgA can inhibit replication of microbial pathogens intracellularly.     

Multiple functions of immunoglobulin A in mucosal defense against viruses: an in vitro measles virus model

Three defense functions of immunoglobulin A (IgA), immune exclusion, intracellular neutralization, and virus excretion, were assessed in a measles virus model using polarized epithelial cells expressing the polymeric immunoglobulin receptor and monoclonal antibodies against the viral H and F envelope proteins and the internal N protein. Anti-H IgA was the most effective antibody at preventing infection via the apical surface, i.e., immune exclusion. This IgA was also the most effective at intraepithelial cell neutralization after infection at the apical surface and endocytosis of IgA at the basolateral surface, although an antibody against the internal N protein was also effective. In the intracellular neutralization experiments, confocal immunofluorescence microscopy showed prominent colocalization of anti-H IgA and H protein inside virus-infected cells, whereas colocalization of anti-F and F protein and of anti-N and N protein was much less, in agreement with the neutralization results. Combinations of IgA anti-H, anti-F, and anti-N showed no synergistic effects in intracellular neutralization. In the immune excretion experiments, virus immune complexes with either anti-H or anti-F IgA placed beneath polarized epithelial cells could be transported to the apical supernatant. Anti-F IgA, which was relatively poor at immune exclusion and intracellular neutralization, was the most robust at virus excretion. Thus, the studies collectively demonstrated three different antiviral functions of IgA in relation to epithelium and also suggested that the particular viral component with which a given IgA antibody reacts is an important determinant of the magnitude of the antiviral effect.     

Interaction of the coronavirus nucleoprotein with nucleolar antigens and the host cell

Coronavirus nucleoproteins (N proteins) localize to the cytoplasm and the nucleolus, a subnuclear structure, in both virus-infected primary cells and in cells transfected with plasmids that express N protein. The nucleolus is the site of ribosome biogenesis and sequesters cell cycle regulatory complexes. Two of the major components of the nucleolus are fibrillarin and nucleolin. These proteins are involved in nucleolar assembly and ribosome biogenesis and act as chaperones for the import of proteins into the nucleolus. We have found that fibrillarin is reorganized in primary cells infected with the avian coronavirus infectious bronchitis virus (IBV) and in continuous cell lines that express either IBV or mouse hepatitis virus N protein. Both N protein and a fibrillarin-green fluorescent protein fusion protein colocalized to the perinuclear region and the nucleolus. Pull-down assays demonstrated that IBV N protein interacted with nucleolin and therefore provided a possible explanation as to how coronavirus N proteins localize to the nucleolus. Nucleoli, and proteins that localize to the nucleolus, have been implicated in cell growth-cell cycle regulation. Comparison of cells expressing IBV N protein with controls indicated that cells expressing N protein had delayed cellular growth. This result could not to be attributed to apoptosis. Morphological analysis of these cells indicated that cytokinesis was disrupted, an observation subsequently found in primary cells infected with IBV. Coronaviruses might therefore delay the cell cycle in interphase, where maximum translation of viral mRNAs can occur.     

Phosphorylation of tegument protein pp28 contributes to trafficking to the assembly compartment in human cytomegalovirus infection

Human cytomegalovirus (HCMV) UL99 encodes a late tegument protein pp28 that is essential for envelopment and production of infectious virus. This protein is localized to the endoplasmic reticulum-Golgi intermediate compartment (ERGIC) in transfected cells but it localizes to the cytoplasmic assembly compartment (AC) in HCMV-infected cells. Trafficking of pp28 to the AC is required for the assembly of infectious virus. The N-terminal domain (aa 1–61) of pp28 is sufficient for trafficking and function of the wild type protein during viral infection. However, residues required for authentic pp28 trafficking with the exception of the acidic cluster in the N-terminal domain of pp28 remain undefined. Monitoring protein migration on SDS-PAGE, we found that pp28 is phosphorylated in the virus-infected cells and dephosphorylated in the viral particles. By generating substitution mutants of pp28, we showed that three serine residues (aa 41–43) and a tyrosine residue (aa 34) account for its phosphorylation. The mutant forms of pp28 were localized to the plasma membrane as well as the ERGIC in transfected cells. Likewise, these mutant proteins were localized to the plasma membrane as well as the AC in virus-infected cells. These results suggested that phosphorylation of pp28 contributes to its intracellular trafficking and efficient viral assembly and incorporation.     

Target Cells of Cytotoxic T Lymphocytes Directed to the Individual Structural Proteins of Rabies Virus

Target cells of cytotoxic T lymphocytes (CTL) directed to the individual structural proteins (except for the large polymerase (L) protein) of rabies virus were established by expressing only the respective protein in murine neuroblastoma (NA) and murine macrophage (J774-1) cell lines. Mice infected with the ERA strain of rabies virus developed CTL responses to all of these rabies virus proteins. The cytotoxic activity was abrogated by pretreatment of the effector cells with anti-CD8 monoclonal antibody (MAb) and complement but not with anti-CD4 MAb. Cell lysis by CTL was blocked in the presence of anti-major histocompatibility complex (MHC) class 1 antibodies in J774-1 cell lines. Rabies virus-infected cells express these proteins at the surface, which can be recognized and lysed by the respective CTL. Mice immunized with β-propiolactone-inactivated virus induced a CTL response against glycoprotein but not against internal viral components. This assay system might be useful for further analysis of the possible contribution of these proteins in the cell-mediated immune protection against rabies.     

A concerted action of hepatitis C virus p7 and nonstructural protein 2 regulates core localization at the endoplasmic reticulum and virus assembly

Hepatitis C virus (HCV) assembly remains a poorly understood process. Lipid droplets (LDs) are thought to act as platforms for the assembly of viral components. The JFH1 HCV strain replicates and assembles in association with LD-associated membranes, around which viral core protein is predominantly detected. In contrast, despite its intrinsic capacity to localize to LDs when expressed individually, we found that the core protein of the high-titer Jc1 recombinant virus was hardly detected on LDs of cell culture-grown HCV (HCVcc)-infected cells, but was mainly localized at endoplasmic reticulum (ER) membranes where it colocalized with the HCV envelope glycoproteins. Furthermore, high-titer cell culture-adapted JFH1 virus, obtained after long-term culture in Huh7.5 cells, exhibited an ER-localized core in contrast to non-adapted JFH1 virus, strengthening the hypothesis that ER localization of core is required for efficient HCV assembly. Our results further indicate that p7 and NS2 are HCV strain-specific factors that govern the recruitment of core protein from LDs to ER assembly sites. Indeed, using expression constructs and HCVcc recombinant genomes, we found that p7 is sufficient to induce core localization at the ER, independently of its ion-channel activity. Importantly, the combined expression of JFH1 or Jc1 p7 and NS2 induced the same differential core subcellular localization detected in JFH1- vs. Jc1-infected cells. Finally, results obtained by expressing p7-NS2 chimeras between either virus type indicated that compatibilities between the p7 and the first NS2 trans-membrane domains is required to induce core-ER localization and assembly of extra- and intra-cellular infectious viral particles. In conclusion, we identified p7 and NS2 as key determinants governing the subcellular localization of HCV core to LDs vs. ER and required for initiation of the early steps of virus assembly.     

Human cytomegalovirus pp28 (UL99) localizes to a cytoplasmic compartment which overlaps the endoplasmic reticulum-golgi-intermediate compartment

Although the assembly of herpesviruses has remained an active area of investigation, considerable controversy continues to surround the cellular location of tegument and envelope acquisition. This controversy is particularly evident when the proposed pathways for alpha- and beta-herpesvirus assembly are compared. We have approached this aspect of human cytomegalovirus (HCMV) assembly, specifically, envelopment, by investigating the intracellular trafficking of viral tegument proteins which localize in the cytoplasms of infected cells. In this study we have demonstrated that the virion tegument protein pp28 (UL99), a true late protein, was membrane associated as a result of myristoylation. A mutation in this protein which prevented incorporation of [(3)H]myristic acid also altered the detergent solubility and intracellular distribution of the protein when it was expressed in transfected cells. Using a panel of markers for intracellular compartments, we could localize the expression of wild-type pp28 to an intracellular compartment which colocalized with the endoplasmic reticulum-Golgi-intermediate compartment (ERGIC), a dynamic compartment of the secretory pathway which interfaces with both the ER and Golgi apparatus. The localization of this viral tegument protein within an early secretory compartment of the cell provided further evidence that the assembly of the HCMV tegument likely includes a cytoplasmic phase. Because pp28 has been shown to be localized to a cytoplasmic assembly compartment in HCMV-infected cells, our findings also suggested that viral tegument protein interactions within the secretory pathway may have an important role in the assembly of the virion.     

N protein is the predominant antigen recognized by vesicular stomatitis virus-specific cytotoxic T cells.

The specificity of anti-vesicular stomatitis virus (VSV)-specific cytotoxic T cells was explored with cell lines expressing VSV genes introduced by electroporation. Low levels of nucleocapsid (N) protein were detected on the surface of VSV-infected cells, but N protein could not be detected on the plasma membrane of transfected EL4 cells. Intracellular N protein was detectable by enzyme-linked immunosorbent assay or immunoprecipitation in some of the transfected cell lines but not in others, unless the transfected genes were induced by sodium butyrate. However, all of the stably transfected EL4 cell lines expressing the VSV-Indiana N protein were efficiently lysed by serotype-specific and cross-reactive anti-VSV cytotoxic T cells (CTLs). Primary cross-reactive anti-VSV CTLs appeared to be specific solely for N protein, based on cold-target competition assays using infected and transfected target cells. Cell lines expressing 100- to 1,000-fold less N protein than did VSV-infected cells were efficiently lysed by both primary and secondary anti-VSV CTLs. Cell lines expressing 100-fold less G protein than did VSV-infected cells were not lysed by either population of effectors. Significantly, cold-target competition studies with secondary CTLs demonstrated that N protein-expressing cell lines were more efficient competitors than were VSV-infected cells even though the latter expressed 100- to 1,000-fold more N protein. This was not an artifact of viral infection since infection of the transfected cell lines did not affect their ability to compete. The possibility that cell lines constitutively expressing internal virus proteins present antigen more effectively than infected cells do is discussed.