Nucleotide sequence of the genome and complete amino acid sequence of a polyprotein of the tick-borne encephalitis virus

We have cloned and sequenced RNA encoding all virion and nonstructural proteins of tick-borne encephalitis virus (TBEV). Its length is 10,477 bases with a single open reading frame (nucleotides 127-10,363) encoding 3412 amino acids. The 5'- and 3'-noncoding regions have stem- and- loop structure. The polyprotein precursor is proteolytically cleaved, apparently, by a mechanism resembling that proposed for the expression of polyproteins of other flaviviruses, such as yellow fever, West Nile and Kunjin viruses. The deduced TBEV gene order is 5'-C-preM (M)-E-NS1-NS2A-NS2B-NS3-NS4A-NS4B-NS5++ +-3'. The genome and the polyprotein of TBEV and other flaviviruses appears to be structurally similar, although these flaviviruses are transmitted to and from their vertebrate hosts by different carriers, such as ticks or mosquitoes. Analysis of sequence homologies of polyproteins of flaviviruses suggests that TBEV is more closely related to yellow fever virus than to other serological subgroups of flaviviruses (West Nile or Dengue viruses). The hydrophobic profiles of the flaviviruses are highly conservative. Nonstructural proteins NS2A, NS2B, NS4A and NS4B are extremely hydrophobic, suggesting that they are likely to be associated with cellular membranes. Proteins E, NS1, NS3 and NS5 are the most conservative and may be involved in general enzymatic activities related to viral replication and virion assembly.     

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.     

传染性法氏囊病病毒中国强毒株A节段cDNA基因的克隆和序列分析

以来自哈尔滨传染性法氏囊病病毒（ＩＢＤＶ） 强毒株（Ｈａｒｂｉｎ 毒株,Ｈ） 的基因组ＲＮＡ为模板,用反转录聚合酶链反应（ＲＴ－ ＰＣＲ） 的方法得到了其Ａ 节段的全长ｃＤＮＡ 片段,分５＇端（１ ６５９ｂｐ） 和３＇端（１ ４４４ｂｐ） 上下两段分别克隆到ｐＧＥＭＢ○Ｒ － Ｔ 载体上,测定了其核苷酸顺序,在长为３ １０１ ｂｐ 中含有两个阅读框ＯＲＦＡ１ 和ＯＲＦＡ２ ,分别编码１ ０１２ 个氨基酸的前体蛋白（ＶＰ２ － ４ －３） 和１４５ 个氨基酸的ＶＰ５,ＯＲＦＡ１ 和ＯＲＦＡ２ 有部分的重叠。将核苷酸序列及推测出的氨基酸序列与已报道的ＩＢＤＶ 血清Ⅰ型和Ⅱ型毒株的相应序列进行了比较,结果表明：Ｈ 毒株与其它血清Ⅰ型毒株之间,在核苷酸水平上存在２５ｂｐ － ２６７ｂｐ 的差异;在氨基酸水平上存在１７ ～４０ 个氨基酸的差异。在ＶＰ２ － ４ － ３ 内比较显示,Ｈ 毒株与Ｐ２ 、Ｃｕ－ １ 之间氨基酸的差异最小为１ ．７％ ,Ｈ 毒株与ＵＫ６６１ 之间氨基酸的差异最大为３ ．９ ％ 。变异主要发生在ＶＰ２ 的可变区（２０６ － ３５０ 位氨基酸） ,在Ｈ 毒株所特有的１２ 个氨基酸当中,该区就占５ 个,代表１ ．７６ ％ 的变异。ＶＰ４、ＶＰ３ 和ＶＰ５区各有     

The nucleotide sequence of poliovirus type 3 leon 12 a1b: comparison with poliovirus type 1.

The complete nucleotide sequence of the genome of the Sabin vaccine strain of poliovirus type 3 (P3/Leon 12 a1 b) has been determined from cDNA cloned in E. coli. The genome comprises a 5' non-coding region of 742 nucleotides, a large open reading frame of 6618 nucleotides (89% of the sequence) and a 3' non-coding region of 72 nucleotides. There is 77.4% base-sequence homology and 89.6% predicted amino-acid homology between types 1 and 3. Conservation of all glutamine-glycine and tyrosine-glycine cleavage sites suggests a mechanism of polyprotein processing similar to that established for poliovirus type 1.     

猪瘟病毒兔化弱毒株cDNA片段的克隆及序列分析

猪瘟是猪最重要的传染病之一,往往给养猪业造成重大经济损失,猪瘟的病原为猪瘟病毒（ＨＣＶ）,属黄病毒科,瘟病毒属成员,其基因组为单股正链ＲＮＡ,长度为１２３ｋｂ,仅含有一个大的开放阅读框架,编码一个含３８９８个氨基酸残基（ＡＡ）的多聚前体蛋白［１,２］。目前已经定位的蛋白有５种,即Ｎｐｒｏ、Ｃ、Ｅ０、Ｅ１和Ｅ２,它们均由ＨＣＶＲＮＡ５′端所编码,除Ｎｐｒｏ外,其它４种均为ＨＣＶ的结构蛋白［３］。Ｎｐｒｏ为具有自我催化功能的蛋白水解酶,也是多聚蛋白Ｎ端的第一个蛋白水解酶,分子量为２３ｋＤ,Ｃ为构成…     

丙型肝炎病毒准种在NS2区的变异状况初探

探讨HCV准种在NS2区的基因结构特征及变异状况。利用逆转录－巢式PCR从1份HCV慢性携带者的阳性血清及1份丙肝患者的血清中获得HCV NS2全长cDNA,将其克隆于T载体,各随机挑取5个阳性克隆进行序列测定,结果显示克隆到HCV NS2全长基因,所测克隆在核苷酸水平和氨基酸水平互不相同。该慢性携带者HCV NS2区序列以完整读码框架（ORF）为主,一个于HCV多聚蛋白第835位氨基酸的位置出现终止信号,而该丙型肝炎患者以NS2N端发现终止信号的序列为主,其中三个于第835位氨基酸的位置出现终止信号,一个于第887位氨基酸的位置出现终止信号,仅一个克隆的序列为完整ORF。对ORF完整的序列进行比较,发现丙型肝炎患者氨基酸变异主要集中于N端,蛋白二级结构模拟显示丙肝患者NS2与慢性携带者的优势二级结构类似,研究表明从我们选择的两种感染者的HCV NS2序列看,不同临床类型的HCV病人体内的HCV准种在NS2区存在差异,这种差异可能与病毒存在于机体的状态一定的一致性。     

The hepatitis C virus Core protein is a potent nucleic acid chaperone that directs dimerization of the viral (+) strand RNA in vitro

The hepatitis C virus (HCV) is an important human pathogen causing chronic hepatitis, liver cirrhosis and hepatocellular carcinoma. HCV is an enveloped virus with a positive-sense, single-stranded RNA genome encoding a single polyprotein that is processed to generate viral proteins. Several hundred molecules of the structural Core protein are thought to coat the genome in the viral particle, as do nucleocapsid (NC) protein molecules in Retroviruses, another class of enveloped viruses containing a positive-sense RNA genome. Retroviral NC proteins also possess nucleic acid chaperone properties that play critical roles in the structural remodelling of the genome during retrovirus replication. This analogy between HCV Core and retroviral NC proteins prompted us to investigate the putative nucleic acid chaperoning properties of the HCV Core protein. Here we report that Core protein chaperones the annealing of complementary DNA and RNA sequences and the formation of the most stable duplex by strand exchange. These results show that the HCV Core is a nucleic acid chaperone similar to retroviral NC proteins. We also find that the Core protein directs dimerization of HCV (+) RNA 3' untranslated region which is promoted by a conserved palindromic sequence possibly involved at several stages of virus replication.     

Hepatitis C virus-encoded NS2-3 protease: cleavage-site mutagenesis and requirements for bimolecular cleavage.

Cleavage at the 2/3 site of hepatitis C virus (HCV) is thought to be mediated by a virus-encoded protease composed of the region of the polyprotein encoding NS2 and the N-terminal one-third of NS3. This protease is distinct from the NS3 serine protease, which is responsible for downstream cleavages in the nonstructural region. Site-directed mutagenesis of residues surrounding the 2/3 cleavage site showed that cleavage is remarkably resistant to single-amino-acid substitutions from P5 to P3' (GWRLL decreases API). The only mutations which dramatically inhibited cleavage were the ones most likely to alter the conformation of the region, such as Pro substitutions at the P1 or P1' position, deletion of both amino acids at P1 and P1', or simultaneous substitution of multiple Ala residues. Cotransfection experiments were done to provide additional information on the polypeptide requirements for bimolecular cleavage. Polypeptides used in these experiments contained amino acid substitutions and/or deletions in NS2 and/or the N-terminal one-third of NS3. Polypeptides with defects in either NS2 or the N-terminal portion of NS3 but not both were cleaved when cotransfected with constructs expressing intact versions of the defective region. Cotransfection experiments also showed that certain defective NS2-3 constructs partially inhibited cleavage of wild-type polypeptides. Although these results show that inefficient cleavage can occur in a bimolecular reaction, they suggest that both molecules must contribute a functional subunit to allow formation of a protease which is capable of cleavage at the 2/3 site. This reaction may resemble the cis cleavage thought to occur at the 2/3 site during processing of the wild-type HCV polyprotein.     

Characterization of the hepatitis C virus-encoded serine proteinase: determination of proteinase-dependent polyprotein cleavage sites.

Processing of the hepatitis C virus (HCV) H strain polyprotein yields at least nine distinct cleavage products: NH2-C-E1-E2-NS2-NS3-NS4A-NS4B-NS5A-NS5B-CO OH. As described in this report, site-directed mutagenesis and transient expression analyses were used to study the role of a putative serine proteinase domain, located in the N-terminal one-third of the NS3 protein, in proteolytic processing of HCV polyproteins. All four cleavages which occur C terminal to the proteinase domain (3/4A, 4A/4B, 4B/5A, and 5A/5B) were abolished by substitution of alanine for either of two predicted residues (His-1083 and Ser-1165) in the proteinase catalytic triad. However, such substitutions have no observable effect on cleavages in the structural region or at the 2/3 site. Deletion analyses suggest that the structural and NS2 regions of the polyprotein are not required for the HCV NS3 proteinase activity. NS3 proteinase-dependent cleavage sites were localized by N-terminal sequence analysis of NS4A, NS4B, NS5A, and NS5B. Sequence comparison of the residues flanking these cleavage sites for all sequenced HCV strains reveals conserved residues which may play a role in determining HCV NS3 proteinase substrate specificity. These features include an acidic residue (Asp or Glu) at the P6 position, a Cys or Thr residue at the P1 position, and a Ser or Ala residue at the P1' position.     

Molecular structure of the Japanese hepatitis C viral genome

The amino acid sequence of the polyprotein deduced from the nucleotide sequence of the Japanese hepatitis C virus genome (N. Kato et. al. (1990) Proc. Natl. Acad. Sci. USA 87, 9524–9528)indicated that this virus is a member of a new class of positive-stranded RNA viruses. Several domains of this polyprotein also showed weak homology with those of flaviviruses and pestiviruses including the chymotrypsin-like serine proteinase. NTPase and RNA-dependent RNA polymerase