HCV 1a/1b型嵌合体能在HepG2细胞内复制与表达

采用HCV 1a/1b嵌合体cDNA构建表达质粒转染HepG2细胞,以免疫组化和Western blotting检测HCV蛋白表达,RT-PCR检测HCV正、负链RNA,研究丙型肝炎病毒(HCV)1a和1b型嵌合体全长cDNA在HepG2细胞中的复制和表达.结果证明,转染细胞中检测到分子量约70 kDa的HCV NS3蛋白, 转染细胞连续传20代, 仍能检测到HCV正、负链RNA.表明该HCV嵌合体可以在细胞中复制和表达,HCV 1b型的RNA依赖的RNA聚合酶(RdRp)可以起始含1a型非编码区的病毒复制. HCV 5′端非翻译区第11、12、13、34和35位核苷酸改变可不影响其与核糖体结合.3′非翻译区9400,9403和9407位核苷酸改变,9435位缺失"A",9409,9410位及9495,9496,9497位分别插入"TT"和"AAT"可不影响RdRp的生物活性.本研究对阐明HCV复制和翻译机制有重要意义.     

嵌合型HCV全长cDNA的构建及体外转录制备感染性RNA的研究

构建HCV la/1b嵌合型全长cDNA克隆,进行体外转录,脂质体法转染HepG2细胞,以RT-PCR法检测HCV正、负链RNA,Western印迹检测HCV蛋白表达.结果表明,细胞在转染后8代(约35d)内,能间断检测到HCV正、负链RNA以及相对分子质量约70000的HCV NS3蛋白,证明该HCV嵌合体可以在细胞中复制和表达.本研究表明含有该嵌合型全长cDNA的质粒可以为后续HCV的研究提供大量可重复的性质均一的病毒模板,有助于深入了解HCV的复制机制.     

HCV特异性反义RNA表达载体的构建及活性评价

反义RNA是反义技术的一个重要领域,为探索丙型肝炎病毒治疗新途径及验证转基因细胞模型HepG2.9706的有效性,设计了一条互补于HCV 5′NCR及翻译起始区(39713核苷酸)的反义RNA序列,将其插入pGL3载体SV40启动子下游,构建了HCV特异性的反义RNA真核表达载体(pHCV-asR)。通过PCR扩增、酶切反应及序列分析进行了初步鉴定,并将其转染HepG2细胞,通过RTPCR方法检测其在细胞中的表达并将pHCV-asR转染转基因细胞模型HepG2.9706,评价其对HCV 5′NCR的抑制活性。结果表明,构建的反义RNA表达载体插入序列正确,并能在HepG2细胞中表达;pHCV-asR在HepG2.9706中对HCV 5′NCR调控荧光素酶基因表达具有特异性的剂量依赖性抑制活性,最高抑制率可达57%。     

HGV RNA基因组感染HepG2细胞的研究*

为了观察HGV　RNA基因组在HepG2细胞中的复制和表达并建立HGV感染的细胞模型,体外转录制备HGV RNA基因组,Lipofectamin介导转染HepG2细胞。取HGV RNA阳性培养上清液传代感染HepG2细胞,采用RT-PCR、免疫组化和Western blot等技术检测HGV在HepG2细胞中的复制和表达。HepG2细胞在转染后24h便可在培养上清液中检测到HGV负链RNA,传代感染的细胞及培养上清液中可检测到HGV正、负链RNA。在90d内传代20余次,均能检测到HGV的复制。免疫组化和W     

HGV RNA基因组感染HepG2细胞的研究

为了观察HGV RNA基因组在HepG2细胞中的复制和表达并建立HGV感染的细胞模型,体外转录制备HGV RNA基因组,Lipfectamin介导转染HepG2细胞。取HGV RNA阳性培养上清液传代感染HepG2细胞,采用RT-PCR、免疫组化和Western blot等技术检测HGV在HepG2细胞中的复制和表达。HepG2细胞地转染后24h便可在培养上清液中检测到HGV负链RNA,传代感染的细胞及培养上清液中可检测到HGV正、负链RNA。在90d内传代20余次,均能检测到HGV的复制。免疫组化和Western blot可检测到 HGV E2蛋白在感染细胞中的表达。HGV感染细胞经冻存后复苏,仍能检测到HGV RNA。故HGV RNA基因组能够在HepG2细胞中复制和表达,此细胞模型有可能用于HGV的复制与感染防治的研究。     

丙型肝炎病毒依赖于RNA的RNA聚合酶(RdRp)研究进展

由于缺乏合适的HCV感染细胞模型,严重制约了HCV复制,特别是HCV复制的关键因子依赖于RNA的RNA聚合酶(RdRp)的研究.对HCV序列比较分析并通过异源表达证明NS5B是HCV复制的RdRp.NS5B C端疏水性氨基酸区域以及NS5B与细胞膜形成复合体等影响NS5B溶解性.在合适的反应条件下NS5B可以多种RNA分子为模板催化RNA复制,特别是能有效复制HCV全长(+)RNA.高浓度GTP激活HCV RdRp活性.NS5B N/C端缺失突变和保守性A、B、C区中的点突变影响RdRp活性,但D区345位精氨酸突变为赖氨酸时RdRp活性明显升高.HCV RdRp的发现及其功能研究为HCV药物研究提供了新型靶标.     

NS5B与HCV负链RNA 3′末端特异性结合的分析

NS5B是RNA依赖性RNA聚合酶，在病毒RNA合成过程中起到中心催化酶的作用，在肠杆菌中表达和提纯了GST－NS5B融合蛋白，应用紫外交联试验（UV cross-linking）检测NS5B与丙型肝炎病毒（HCV）负链RNA3′末端的结合，确定NS5B是否参与HCV负链与HCN负链RNA3′末端复制体的形成。NS5B可与HCV负链RNA3′末端发生结合，这种结合存在量效关系， 比与正链RNA3′UTR X区的结合强约10倍，超大量的非同源性RNA和蛋白质不能竞争抑制S5B与负链RNA3′末端的结合，证明这种结合存在特异性。结果提示NS5B是HCV负链RNA3′末端复制体的成分之一。     

肝癌细胞系（HepG2）感染HCV RNA的研究

为建立丙型肝炎病毒（HCV）体外感染和细胞培养系统,用定量的HCV RNA阳性血清感染人肝癌细胞系（HepG2细胞系）,应用地高辛标记HCV RNA探针原位杂交技术和RT－PCR方法对感染后的细胞和上清液听 HCV RNA进行了检测。在感染后的第一代至第七代的细胞中出现特异性杂交阳性信号,第一代、第二代和第六代检测出HCV RNA正链,并在感染后第一、二代检测出HCV RNA负链。显示HCV不仅能在体外感染HepG2细胞系,而且在基因的复制,证明HepG2细胞能作为HCV的体外细胞培育系。     

HCV 5′NCR转基因细胞HepG2.9706的特性分析

丙型肝炎是由丙型肝炎病毒(hepatitis C virus,HCV)引起的威胁人类健康的重要传染病,迄今尚无有效的疫苗及特异性抗病毒治疗药物.抗HCV药物的研究和开发面临的关键问题是缺乏合适的HCV感染细胞及动物评价模型.转基因细胞模型是研究人类疾病常用的有效手段,因此,在HCV分子生物学进展的基础上,我们以对HCV翻译与复制有明显调控功能的HCV 5′NCR及部分翻译起始区序列为靶标,构建了HCV 5′NCR及部分多聚蛋白起始区序列与荧光素酶基因的融合基因,插入真核表达载体,转染HepG2细胞,获得了HCV 5′NCR转基因细胞HepG2.9706细胞株[1].本文对该细胞的某些特性进行了分析,以便更好地利用该细胞模型进行药物评价.     

互补引物/模板评价毕加酵母表达的丙型肝炎病毒RNA依赖的RNA聚合酶

构建含有感染性克隆HCV非结构基因5b区序列的酵母表达质粒,转化毕加酵母,获得持续、可溶性HCV RNA依赖的RNA聚合酶(RdRp)的表达,纯化蛋白在SDS-PAGE及Western blot中显示出特异性的64.2kD HCV RdRp蛋白带,同聚引物/模板测定显示RdRp的活性极低,延长反应时间,RNA聚合活性仅轻度升高.采用合成的杂聚互补引物/模板,未发现核苷酸在毕加酵母表达的RdRp作用下掺入模板,随时间延长,杂聚互补引物/模板降解.     

Effects of mutations of the initiation nucleotides on hepatitis C virus RNA replication in the cell

Replication of nearly all RNA viruses depends on a virus-encoded RNA-dependent RNA polymerase (RdRp). Our earlier work found that purified recombinant hepatitis C virus (HCV) RdRp (NS5B) was able to initiate RNA synthesis de novo by using purine (A and G) but not pyrimidine (C and U) nucleotides (G. Luo et al., J. Virol. 74:851-863, 2000). For most human RNA viruses, the initiation nucleotides of both positive- and negative-strand RNAs were found to be either an adenylate (A) or guanylate (G). To determine the nucleotide used for initiation and control of HCV RNA replication, a genetic mutagenesis analysis of the nucleotides at the very 5' and 3' ends of HCV RNAs was performed by using a cell-based HCV replicon replication system. Either a G or an A at the 5' end of HCV genomic RNA was able to efficiently induce cell colony formation, whereas a nucleotide C at the 5' end dramatically reduced the efficiency of cell colony formation. Likewise, the 3'-end nucleotide U-to-C mutation did not significantly affect the efficiency of cell colony formation. In contrast, a U-to-G mutation at the 3' end caused a remarkable decrease in cell colony formation, and a U-to-A mutation resulted in a complete abolition of cell colony formation. Sequence analysis of the HCV replicon RNAs recovered from G418-resistant Huh7 cells revealed several interesting findings. First, the 5'-end nucleotide G of the replicon RNA was changed to an A upon multiple rounds of replication. Second, the nucleotide A at the 5' end was stably maintained among all replicon RNAs isolated from Huh7 cells transfected with an RNA with a 5'-end A. Third, initiation of HCV RNA replication with a CTP resulted in a >10-fold reduction in the levels of HCV RNAs, suggesting that initiation of RNA replication with CTP was very inefficient. Fourth, the 3'-end nucleotide U-to-C and -G mutations were all reverted back to a wild-type nucleotide U. In addition, extra U and UU residues were identified at the 3' ends of revertants recovered from Huh7 cells transfected with an RNA with a nucleotide G at the 3' end. We also determined the 5'-end nucleotide of positive-strand RNA of some clinical HCV isolates. Either G or A was identified at the 5' end of HCV RNA genome depending on the specific HCV isolate. Collectively, these findings demonstrate that replication of positive-strand HCV RNA was preferentially initiated with purine nucleotides (ATP and GTP), whereas the negative-strand HCV RNA replication is invariably initiated with an ATP.     

Production of infectious chimeric hepatitis C virus genotype 2b harboring minimal regions of JFH-1

To establish a cell culture system for chimeric hepatitis C virus (HCV) genotype 2b, we prepared a chimeric construct harboring the 5' untranslated region (UTR) to the E2 region of the MA strain (genotype 2b) and the region of p7 to the 3' UTR of the JFH-1 strain (genotype 2a). This chimeric RNA (MA/JFH-1.1) replicated and produced infectious virus in Huh7.5.1 cells. Replacement of the 5' UTR of this chimera with that from JFH-1 (MA/JFH-1.2) enhanced virus production, but infectivity remained low. In a long-term follow-up study, we identified a cell culture-adaptive mutation in the core region (R167G) and found that it enhanced virus assembly. We previously reported that the NS3 helicase (N3H) and the region of NS5B to 3' X (N5BX) of JFH-1 enabled replication of the J6CF strain (genotype 2a), which could not replicate in cells. To reduce JFH-1 content in MA/JFH-1.2, we produced a chimeric viral genome for MA harboring the N3H and N5BX regions of JFH-1, combined with a JFH-1 5' UTR replacement and the R167G mutation (MA/N3H+N5BX-JFH1/R167G). This chimeric RNA replicated efficiently, but virus production was low. After the introduction of four additional cell culture-adaptive mutations, MA/N3H+N5BX-JFH1/5am produced infectious virus efficiently. Using this chimeric virus harboring minimal regions of JFH-1, we analyzed interferon sensitivity and found that this chimeric virus was more sensitive to interferon than JFH-1 and another chimeric virus containing more regions from JFH-1 (MA/JFH-1.2/R167G). In conclusion, we established an HCV genotype 2b cell culture system using a chimeric genome harboring minimal regions of JFH-1. This cell culture system may be useful for characterizing genotype 2b viruses and developing antiviral strategies.     

Role of the 5' TAR stem--loop and the U5-AUG duplex in dimerization of HIV-1 genomic RNA

The HIV-1 genome consists of two identical RNAs that are linked together through noncovalent interactions involving nucleotides from the 5' untranslated region (5' UTR) of each RNA strand. The 5' UTR is the most conserved part of the HIV-1 RNA genome, and its 335 nucleotide residues form regulatory motifs that mediate multiple essential steps in the viral replication cycle. Here, studying the effect of selected mutations both singly and together with mutations disabling SL1 (SL1 is a 5' UTR stem-loop containing a palindrome called the dimerization initiation site), we have done a rather systematic survey of the 5' UTR requirements for full genomic RNA dimerization in grown-up (i.e., predominantly >/=10 h old) HIV-1 viruses produced by transfected human and simian cells. We have identified a role for the 5' transactivation response element (5' TAR) and a contribution of a long-distance base pairing between a sequence located at the beginning of the U5 region and nucleotides surrounding the AUG Gag initiation codon. The resulting intra- or intermolecular duplex is called the U5-AUG duplex. The other regions of the 5' UTR have been shown to play no systematic role in genomic RNA dimerization, except for a sequence located around the 3' end of a large stem-loop enclosing the primer binding site, and the well-documented SL1. Our data are consistent with a direct role for the 5' TAR in genomic RNA dimerization (possibly via a palindrome encompassing the apical loop of the 5' TAR).     

Viral RNA mutations are region specific and increased by ribavirin in a full-length hepatitis C virus replication system

High rates of genetic variation ensure the survival of RNA viruses. Although this variation is thought to result from error-prone replication, RNA viruses must also maintain highly conserved genomic segments. A balance between conserved and variable viral elements is especially important in order for viruses to avoid "error catastrophe." Ribavirin has been shown to induce error catastrophe in other RNA viruses. We therefore used a novel hepatitis C virus (HCV) replication system to determine relative mutation frequencies in variable and conserved regions of the HCV genome, and we further evaluated these frequencies in response to ribavirin. We sequenced the 5' untranslated region (5' UTR) and the core, E2 HVR-1, NS5A, and NS5B regions of replicating HCV RNA isolated from cells transfected with a T7 polymerase-driven full-length HCV cDNA plasmid containing a cis-acting hepatitis delta virus ribozyme to control 3' cleavage. We found quasispecies in the E2 HVR-1 and NS5B regions of untreated replicating viral RNAs but not in conserved 5' UTR, core, or NS5A regions, demonstrating that important cis elements regulate mutation rates within specific viral segments. Neither T7-driven replication nor sequencing artifacts produced these nucleotide substitutions in control experiments. Ribavirin broadly increased error generation, especially in otherwise invariant regions, indicating that it acts as an HCV RNA mutagen in vivo. Similar results were obtained in hepatocyte-derived cell lines. These results demonstrate the potential utility of our system for the study of intrinsic factors regulating genetic variation in HCV. Our results further suggest that ribavirin acts clinically by promoting nonviable HCV RNA mutation rates. Finally, the latter result suggests that our replication model may be useful for identifying agents capable of driving replicating virus into error catastrophe.     

Expression of human immunodeficiency virus type 1 (HIV-1) gag, pol, and env proteins from chimeric HIV-1-poliovirus minireplicons.

Recent studies have demonstrated that genomes of poliovirus with deletions in the P1 (capsid) region contain the necessary viral information for RNA replication. To test the effects of the substitution of foreign genes on RNA replication and protein expression, chimeric human immunodeficiency virus type 1 (HIV-1)-poliovirus genomes were constructed in which regions of the gag, pol, or env gene of HIV-1 were substituted for regions of the P1 gene in the infectious cDNA clone of type 1 Mahoney poliovirus. The HIV-1 genes were inserted between nucleotides 1174 and 2956 of the poliovirus cDNA so that the translational reading frame was maintained between the HIV-1 genes and the remaining poliovirus genes. The chimeric genomes were positioned downstream from a T7 RNA polymerase promoter and transcribed in vitro by using T7 RNA polymerase, and the RNA was transfected into HeLa cells. A Northern (RNA blot) analysis of the RNA from transfected cells demonstrated the appropriate-size RNA, corresponding to the full-length chimeric genomes, which increased over time. Immunoprecipitation with antibodies specific for poliovirus RNA polymerase or sera from AIDS patients demonstrated the expression of the poliovirus RNA polymerase and HIV-1 proteins as fusions with the poliovirus P1 protein. The expression of the HIV-1-poliovirus P1 fusion protein was dependent upon an intact RNA polymerase gene, indicating that RNA replication was required for efficient expression. A pulse-chase analysis of the protein expression from the chimeric genomes demonstrated the initial rapid proteolytic processing of the polyprotein from the chimeric genomes to give HIV-1-poliovirus P1 fusion protein in transfected cells; the HIV-1 gag-P1 and HIV-1 pol-P1 fusion proteins exhibited a greater intracellular stability than the HIV-1 env-P1 fusion protein. Finally, superinfection with wild-type poliovirus of HeLa cells which had been transfected with the chimeric genomes did not significantly affect the expression of chimeric fusion protein. The results are discussed in the context of poliovirus RNA replication and demonstrate the feasibility of using poliovirus genomes (minireplicons) as novel vectors for expression of foreign proteins.     

Insulin inhibition of apolipoprotein B mRNA translation is mediated via the PI-3 kinase/mTOR signaling cascade but does not involve internal ribosomal entry site (IRES) initiation

Although insulin normally activates global mRNA translation, it has a specific inhibitory effect on translation of apolipoprotein B (apoB) mRNA. This suggests that insulin induces a unique signaling cascade that leads to specific inhibition of apoB mRNA translation despite global translational stimulation. Recent studies have revealed that insulin functions to regulate apoB mRNA translation through a mechanism involving the apoB mRNA 5' untranslated region (5' UTR). Here, we further investigate the role of downstream insulin signaling molecules on apoB mRNA translation, and the mechanism of apoB mRNA translation itself. Transfection studies in HepG2 cells expressing deletion constructs of the apoB 5' UTR showed that the cis-acting region responding to insulin was localized within the first 64 nucleotides. Experiments using chimeric apoB UTR-luciferase constructs transfected into HepG2 cells followed by treatment with wortmannin, a PI-3K inhibitor, and rapamycin, an mTOR inhibitor, showed that signaling via PI-3K and mTOR pathways is necessary for insulin-mediated inhibition of chimeric 5' UTR-luciferase expression. In vitro translation of chimeric cRNA confirmed that the effects observed were translational in nature. Furthermore, using RNA-EMSA we found that wortmannin pretreatment blocked insulin-mediated inhibition of the binding of RNA-binding factor(s), migrating near the 110 kDa marker, to the 5' UTR. Radiolabeling studies in HepG2 cells also showed that insulin-mediated control of the synthesis of endogenously expressed full length apoB100 is mediated via the PI-3K and mTOR pathways. Finally, using dual-cistronic luciferase constructs we demonstrate that apoB 5' UTR may have weak internal ribosomal entry (IRES) translation which is not affected by insulin stimulation, and may function to stimulate basal levels of apoB mRNA translation.     

HCV RNA-dependent RNA polymerase replicates in vitro the 3' terminal region of the minus-strand viral RNA more efficiently than the 3' terminal region of the plus RNA.

The NS5B protein, or RNA-dependent RNA polymerase of the hepatitis virus type C, catalyzes the replication of the viral genomic RNA. Little is known about the recognition domains of the viral genome by the NS5B. To better understand the initiation of RNA synthesis on HCV genomic RNA, we used in vitro transcribed RNAs as templates for in vitro RNA synthesis catalyzed by the HCV NS5B. These RNA templates contained different regions of the 3' end of either the plus or the minus RNA strands. Large differences were obtained depending on the template. A few products shorter than the template were synthesized by using the 3' UTR of the (+) strand RNA. In contrast the 341 nucleotides at the 3' end of the HCV minus-strand RNA were efficiently copied by the purified HCV NS5B in vitro. At least three elements were found to be involved in the high efficiency of the RNA synthesis directed by the HCV NS5B with templates derived from the 3' end of the minus-strand RNA: (a) the presence of a C residue as the 3' terminal nucleotide; (b) one or two G residues at positions +2 and +3; (c) other sequences and/or structures inside the following 42-nucleotide stretch. These results indicate that the 3' end of the minus-strand RNA of HCV possesses some sequences and structure elements well recognized by the purified NS5B.     

The synthesis of minus-strand RNA of bamboo mosaic potexvirus initiates from multiple sites within the poly(A) tail

The 3' terminus of the bamboo mosaic potexvirus (BaMV) contains a poly(A) tail, the 5' portion of which participates in the formation of an RNA pseudoknot required for BaMV RNA replication. Recombinant RNA-dependent RNA polymerase (RdRp) of BaMV binds to the pseudoknot poly(A) tail in gel mobility shift assays (C.-Y. Huang, Y.-L. Huang, M. Meng, Y.-H. Hsu, and C.-H. Tsai, J. Virol. 75:2818-2824, 2001). Approximately 20 nucleotides of the poly(A) tail adjacent to the 3' untranslated region (UTR) are protected from diethylpyrocarbonate modification, suggesting that this region may be used to initiate minus-strand RNA synthesis. The 5' terminus of the minus-strand RNA synthesized by the RdRp in vitro was examined using 5' rapid amplification of cDNA ends (RACE) and DNA sequencing. Minus-strand RNA synthesis was found to initiate from several positions within the poly(A) tail, with the highest frequency of initiation being from the 7th to the 10th adenylates counted from the 5'-most adenylate of the poly(A) tail. Sequence analyses of BaMV progeny RNAs recovered from Nicotiana benthamiana protoplasts which were inoculated with mutants containing a mutation at the 1st, 4th, 7th, or 16th position of the poly(A) tail suggested the existence of variable initiation sites, similar to those found in 5' RACE experiments. We deduce that the initiation site for minus-strand RNA synthesis is not fixed at one position but resides opposite one of the 15 adenylates of the poly(A) tail immediately downstream of the 3' UTR of BaMV genomic RNA.