丙型肝炎病毒RNA打点杂交检测方法同RT－PCR方法的比较

采用ＨＣＶ基因组结构区Ｃ区ｃＤＮＡ探针和非结构区ＮＳ３－４区ｃＤＮＡ探针,建立了用打点杂交（ｄｏｔｂｌｏｔｈｙｂｒｉｄｉｚａｔｉｏｎ）检测血清中ＨＣＶＲＮＡ的方法,同采用ＨＣＶ基因组５’端非编码区的一对寡核苷酸引物通过逆转录－聚合酶链式反应（ＲＴ－ＰＣＲ）检测血清中ＨＣＶＲＮＡ的方法相比较,发现两种方法都能快速早期和特异地检出血清中ＨＣＶＲＮＡ,但ＲＴ－ＰＣＲ法敏感性优于ＲＮＡ打点杂交法。对于无血清学指标的慢性ＮＡＮＢ肝炎病人的诊断,可采用这两种方法。这两种方法的敏感性在很大程度上依赖于引物和探针的敏感性,以及ＲＮＡ提取方法。ＲＴ－ＰＣＲ法适用于诊断病毒血症和复制,打点杂交法适用于研究ＨＣＶＲＮＡ量的变化,对治疗的评价,以及为实验筛选较高滴度的ＨＣＶＲＮＡ阳性样本。     

Poliovirus RNA recombination: mechanistic studies in the absence of selection.

Direct and quantitative detection of recombinant RNA molecules by polymerase chain reaction (PCR) provides a novel method for studying recombination in RNA viruses without selection for viable progeny. The parental poliovirus strains used in this study contained polymorphic marker loci approximately 600 bases apart; both exhibited wild-type growth characteristics. We established conditions under which the amount of PCR product was linearly proportional to the amount of input template, and the reproducibility was high. Recombinant progeny were predominantly homologous and arose at frequencies up to 2 x 10(-3). Recombination events increased in frequency throughout replication, indicating that there is no viral RNA sequestration or inhibition of recombination late in infection as proposed in earlier genetic studies. Previous studies have demonstrated that poliovirus recombination occurs by a copy-choice mechanism in which the viral polymerase switches templates during negative-strand synthesis. Varying the relative amount of input parental virus markedly altered reciprocal recombination frequencies. This, in conjunction with the kinetics data, indicated that acceptor template concentration is a determinant of template switching frequency. Since positive strands greatly outnumber negative strands throughout poliovirus infection, this would explain the bias toward recombination during negative-strand synthesis.     

Construction of recombinant DNA molecules by the use of a single stranded DNA generated by the polymerase chain reaction: its application to chimeric hepatitis A virus/poliovirus subgenomic cDNA.

In order to study the importance of VP4 in picornavirus replication and translation, we replaced the hepatitis A virus (HAV) VP4 with the poliovirus (PV1) VP4. Using a modification of oligonucleotide site directed mutagenesis and the polymerase chain reaction (PCR), we created a subgenomic cDNA chimera of hepatitis A virus in which the precise sequences coding for HAV VP4 capsid protein were replaced by the sequences coding for the poliovirus VP4 capsid protein. The method involved the use of PCR primers corresponding to the 3' and 5' ends of the poliovirus VP4 sequence and that had HAV VP4 3' and 5' flanking sequences on their 5'ends. Single stranded DNA of 240 and 242 nt containing the 204 nt coding for the complete poliovirus VP4 were produced by using a limiting amount of one of the primers in a PCR reaction. These single stranded PCR products were used like mutagenic oligonucleotides on a single stranded phagemid containing the first 2070 bases of the HAV genome. Using this technique, we precisely replaced the HAV VP4 gene by the poliovirus VP4 gene as determined by DNA sequencing. The cDNA was transcribed into RNA and translated in vitro. The resulting protein could be precipitated by antibody to poliovirus VP4 but not to HAV VP4.     

一种标记cDNA芯片探针的新方法

探讨mRNA长片段反转录PCR技术(RT-LDPCR)在cDNA芯片微量探针标记和信号放大中的应用.首先提取BEP2D细胞的总RNA,然后用两种不同的方法进行标记,一种为RT-LDPCR,用荧光素Cy3-dCTP进行标记;另一种为传统的RNA反转录,用荧光素Cy5-dCTP进行标记.将两种方法标记好的探针等量混合后与含有440个点(44个基因)的cDNA芯片同时杂交,发现二者具有很高的一致性(0.5＜Cy3/Cy5＞2.0).由于RNA反转录法为cDNA芯片探针标记的传统方法,从而验证了RT-LDPCR用于cDNA芯片探针标记的可行性.RT-LDPCR具有对样品总RNA的需要量少和可对样品中信号进行放大的优点,特别适合于对材料来源受到限制的RNA进行标记.     

庚型肝炎病毒全长基因在体外的表达

利用第二军医大学微生物学教研室克隆的庚型肝炎病毒 (HGV)全长基因组 (HGVqz) ,构建由不同启动子调控的HGV表达载体 ,将 2种表达载体及HGV全长基因片段进行体外表达 ,探讨此HGV全长基因克隆的功能。利用脂质体将HGV全长基因cDNA以及表达载体转入Changliver或NIH 3T3细胞进行瞬时表达 ,分别提取转染72h后转染细胞的RNA及蛋白质进行RT PCR及Westernblotting ,以检测HGV基因的表达。RT PCR及Westernblotting结果表明 ,HGV全长基因cDNA以及 2种表达载体均可以在体外培养的细胞内表达 ,其表达产物为HGV前体蛋白 ,分子量约为 310ku。第二军医大学微生物学教研室克隆的HGV全长基因具有正确的开读框架和可表达性 ,能表达HGV前体蛋白 ,但在体外培养细胞内不能完成前体蛋白的剪切     

应用激光显微切割技术检测单个结肠细胞的基因表达

目的：探讨检测单个结肠细胞的基因表达的方法。方法：应用激光显微切割技术(1aser micmdissection)从冰冻切片上将单个结肠细胞切下,提取总RNA,将RNA逆转录成cDNA,采用巢式逆转录聚合酶链反应(nested RT—PCR)检测mRNA的表达。结果：在显微镜下用紫外激光显微切割机,将单个结肠细胞成功切下,提取RNA后,逆转录成cDNA,经过巢式RT—PCR扩增后,扩增产物在琼脂糖凝胶上清晰可见。结论：联合应用激光显微切割和巢式RT—PCR可以检测单个结肠细胞的基因表达。     

RT—nested PCR检测肾综合征出血热患者血清病毒核酸

采用异硫氰酸胍－酚－氯仿（ＡＧＰＣ）一步法提取病毒ＲＮＡ,并依据肾综合征出血热病毒（ＨＦＲＳＶ）核蛋白（ＮＰ）编码基因保守区核苷酸序列合成两对巢式引物,建立了逆转录巢式聚合酶链反应（ＲＴ－ｎｅｓｔｅｄＰＣＲ）检测ＨＦＲＳＶＲＮＡ方法,应用此法对ＨＦＲＳＶ感染的ＶｅｒｏＥ６细胞培养液及ＨＦＲＳ患者血清中的病毒ＲＮＡ进行检测。结果显示,感染细胞培养液及３５例ＨＦＲＳ患者血清均为阳性,正常的ＶｅｒｏＥ６     

Characterization of poliovirus clones containing lethal and nonlethal mutations in the genome-linked protein VPg.

Viral RNA synthesis was assayed in HeLa cells transfected with nonviable poliovirus RNA mutated in the genome-linked protein VPg-coding region. The transfecting RNA was transcribed in vitro from full-length poliovirus type 1 (Mahoney) cDNA containing a VPg mutagenesis cartridge. Hybridization experiments using ribonucleotide probes specific for the 3' end of positive- and negative-sense poliovirus RNA indicated that all mutant RNAs encoding a linking tyrosine in position 3 or 4 of VPg were replicated even though no virus was produced. VPg, but no VPg precursor, was found to be linked to the 5' end of the newly synthesized RNA. Encapsidated mutant RNAs were not found in transfected-cell lysates. After extended maintenance of transfected HeLa cells, a viable revertant of one of the nonviable RNAs was recovered; the revertant lost the lethal lesion in VPg by restoring the wild-type amino acid, but it retained all other nucleotide changes introduced during construction of the mutagenesis cartridge. Mutant RNA encoding phenylalanine or serine rather than tyrosine, the linking amino acid in VPg, was not replicated in transfected cells. A chimeric mutant containing the VPg-coding region of coxsackievirus within the poliovirus genome was viable but displayed impaired multiplication. A poliovirus-coxsackievirus chimera lacking a linking tyrosine in VPg was nonviable and replication-negative. The results indicate that a linkage-competent VPg is necessary for poliovirus RNA synthesis to occur but that a step in poliovirus replication other than initiation of RNA synthesis can be interrupted by lethal mutations in VPg.     

Polyadenylic acid on poliovirus RNA. II. poly(A) on intracellular RNAs.

The content, size, and mechanism of synthesis of 3'-terminal poly(A) on the various intracellular species of poliovirus RNA have been examined. All viral RNA species bound to poly(U) filters and contained RNase-resistant stretches of poly(A) which could be analyzed by electrophoresis in polyacrylamide gels. At 3 h after infection, the poly(A) on virion RNA, relicative intermediate RNA, polyribosomal RNA, and total cytoplasmic 35S RNA was heterogeneous in size with an average length of 75 nucleotides. By 6 h after infection many of the intracellular RNA's had poly(A) of over 150 nucleotides in length, but the poly(A) in virion RNA did not increase in size suggesting that the amount of poly(A) which can be encapsidated is limited. At all times, the double-stranded poliovirus RNA molecules had poly(A) of 150 to 200 nucleotides. Investigation of the kinetics of poly(A) appearance in the replicative intermediate and in finished 35S molecules indicated that poly(A) is the last portion of the 35S RNA to be synthesized; no nascent poly(A) could be detected in the replicative intermediate. Although this result indicates that poliovirus RNA is synthesized 5' leads to 3' like other RNA's, it also suggests that much of the poly(A) found in the replicative intermediate is an artifact possibly arising from the binding of finished 35S RNA molecules to the replicative intermediate during extraction. The addition of poly(A) to 35S RNA molecules was not sensitive to guanidene.