Expression of Sindbis virus nsP1 and methyltransferase activity in Escherichia coli.

We have constructed two plasmids, pSR5-42 and pSR5-Toto, which under lac control expressed the SVLM21 and the SVToto forms, respectively, of the Sindbis virus nonstructural protein, nsP1. The induced protein, which was the major protein made following induction with IPTG, had an apparent molecular weight of 60,000 and an amino terminal sequence in agreement with that expected for nsP1. Following induction with IPTG, cells carrying pSR5-42 (which contains the SVLM21 gene sequence) generated much higher RNA methyltransferase activity than cells carrying pSR5-Toto (which contains the SVToto gene sequence). This result is in agreement with what is observed when methyltransferase is measured in cells infected with SVLM21 and SVSTD (or SVToto), respectively. These results provide strong evidence that nsP1 has methyltransferase activity in the absence of any other viral nonstructural proteins.     

Suppressor mutations that allow sindbis virus RNA polymerase to function with nonaromatic amino acids at the N-terminus: evidence for interaction between nsP1 and nsP4 in minus-strand RNA synthesis

The alphavirus RNA polymerase, nsP4, invariably has a Tyr residue at the N-terminus. Previously we reported that the N-terminal Tyr residue of nsP4 of Sindbis virus, the type species of the genus Alphavirus, can be substituted with Phe, Trp, or His without altering the wild-type phenotype in cultured cells but that other substitutions tested, except for Met, were lethal or quasilethal. Here we report the identification of two suppressor mutations in nsP4 (Glu-191 to Leu and Glu-315 to Gly, Val, or Lys) and one in nsP1 (Thr-349 to Lys) that allow nsP4 with nonaromatic amino acids at the N-terminus to function at 30 degrees C. The suppressor mutation at nsP4 Glu-315 occurred most frequently. All three suppressor mutations suppressed the effects of Ala, Arg, or Leu at the N-terminus of nsP4 with almost equal efficiency and thus the effect of the suppressing mutation is independent of the nsP4 N-terminal residue. Reconstructed mutants containing nsP1-T349K or nsP4-E315G combined with Ala-nsP4 had a defect in minus-strand RNA synthesis at 40 degrees C. A double mutant containing nsP4-Q191L combined with Ala-nsP4 was unstable and could not be tested for RNA synthesis because it reverted to temperature-independence too rapidly. Combinations of nsP1-T349K or nsP4-E315G with Leu, Arg, His, or any aromatic amino acid at the N-terminus of nsP4 also made the mutant viruses temperature sensitive. The results from this study and from a previous report on the shutoff of minus-strand RNA synthesis at 40 degrees C with the nsP1-A348T mutation in ts11 suggests that the N-terminus nsP4 interacts with nsP1 during initiation of minus-strand RNA synthesis.     

Cleavage between nsP1 and nsP2 initiates the processing pathway of Sindbis virus nonstructural polyprotein P123

The cleavage between nsP1 and nsP2 and that between nsP2 and nsP3 in the Sindbis virus nonstructural polyproteins was studied with respect to order of processing and enzyme-substrate relationships, using site-specific mutants in which the cleavage sites had been altered. The penultimate Gly in nsP1 or nsP2 or both was substituted by Ala, Val, or Glu, and processing was studied in vitro. Substitution with Ala resulted in partial cleavage whereas substitution with Val or Glu totally abolished cleavage at the mutagenized site. Abolishment of cleavage at the nsP2/nsP3 site did not affect processing at the nsP1/nsP2 site in the precursor polyprotein P123, and nsP1 and P23 were produced. When cleavage at the nsP1/nsP2 site was abolished, however, processing at the nsP2/nsP3 site was also prevented and P123 accumulated. To investigate why cleavage at the nsP1/nsP2 site should be required for cleavage at the nsP2/nsP3 site, the mutagenized polypeptides were used as enzymes in trans-cleavage experiments. We found that P123 can cleave the nsP1/nsP2 site but not the nsP2/nsP3 site, whereas P23 can cleave the nsP2/nsP3 site very efficiently. Thus, cleavage at the nsP1/nsP2 site by P123 is required to produce an enzyme capable of cleaving the nsP2/nsP3 site. Release of nsP4 from P1234 appears to be independent of the other cleavages and occurs primarily immediately after translation. These mutations were also transferred into a full-length cDNA clone of Sindbis virus and virus was recovered. Mutants defective in the cleavage of the nsP2/nsP3 site were temperature sensitive, growing at a slightly reduced rate compared to wild-type virus at 30 degrees but growing poorly at 40 degrees. Mutants defective in the cleavage of both the nsP1/nsP2 site and the nsP2/nsP3 site were viable but grew poorly compared with wild-type at any temperature.     

Evidence for an autoprotease activity of sindbis virus capsid protein

Sindbis virus capsid protein is virtually the only product formed when viral 26 S RNA is added to a mouse Krebs ascites cell-free protein synthesis system. However, substitution of arginine and proline by the respective analogues canavanine and azetidine-2-carboxylate inhibits capsid production and larger polypeptides accumulate. The latter are converted to capsid in pulse-chase experiments when the normal amino acids are added during the chase, but not if the chase period contains only the analogues in the reaction mixture. These results support an autoprotease model for the co-translational cleavage of Sindbis virus capsid proteins.     

Mutations that confer resistance to mycophenolic acid and ribavirin on Sindbis virus map to the nonstructural protein nsP1.

SVMPA, a mutant of Sindbis virus derived by serial passage on Aedes albopictus mosquito cells maintained after infection in the presence of mycophenolic acid (MPA), is resistant not only to MPA but also to ribavirin. Both of these compounds inhibit the synthesis of GMP and thereby reduce the level of GTP. We had suggested earlier that SVMPA had become resistant to MPA because it coded for an altered RNA guanylyltransferase enzyme with an increased affinity for GTP, enabling it to replicate in cells with reduced levels of GTP. We now report that the MPA-resistant phenotype of SVMPA has been mapped to the coding region for the nonstructural viral protein, nsP1. By replacing the nucleotide sequence between 88 and 1404 of the infectious clone of Sindbis virus (i.e., the Toto 1101 plasmid) with the corresponding sequence from SVMPA cDNA, we were able to generate recombinant Sindbis virus expressing the drug-resistant phenoptype. SVMPA has three base substitutions in the region between nucleotides 88 and 1404 which lead to predicted amino acid changes in the Sindbis virus nsP1 protein: the replacement of Gln at residue 21 by Lys, Ser at residue 23 by Asn, and Val at residue 302 by Met. These results, taken together with previous data from our laboratory associating the RNA methyltransferase with nsP1, (1) are consistent with the idea that an alteration of the RNA guanylyltransferase is responsible for the MPA-resistant phenotype and (2) support the idea that an important function of nsP1 relates to the modification of the 5' terminus of the Sindbis virus mRNAs.     

Temperature sensitive shut-off of alphavirus minus strand RNA synthesis maps to a nonstructural protein, nsP4

Minus strand RNA synthesis by the positive strand alphaviruses, Sindbis and Semliki Forest viruses, normally occurs early in infection, is coupled to synthesis of viral nonstructural proteins and to formation of viral replication complexes, and terminates and does not occur late in infection. Previously, ts24 of the A complementation group of Sindbis virus RNA-negative mutants was found to possess, among its other temperature sensitive defects, a temperature sensitivity in the normal cessation of minus strand synthesis which enabled minus strands to be synthesized late in infection at 40 degrees in the absence of protein synthesis. Revertants of ts24 (ts24R1, ts24R2) retained the defect in the shutoff of minus strand synthesis, indicating the lesion was not conditionally lethal and could map outside the A cistron. The studies reported here used an infectious clone of Sindbis virus to identify the mutation responsible for this phenotype. Hybrid viruses were prepared from constructs containing restriction fragments of the cDNA of ts24R1 in place of the corresponding fragments in the infectious SIN HR clone and screened for their ability to synthesize minus strands at 40 degrees in the presence of cycloheximide. A unique base change of an A for a C residue at nt 6339, predicting a change from glutamine to lysine at amino acid 195 in nsP4, was found in genomes of ts24, ts24R1, and ts24R2. Other nucleotide changes present at the 5' and 3' termini did not affect minus strand synthesis. The substitution of the parental Sindbis virus sequence that encompassed nt 6339 in an infectious clone of the ts24R1 revertant eliminated the mutant phenotype. We conclude that the ability to continue minus strand synthesis at 40 degrees exhibited by ts24 and its revertants is caused by an alteration in nsP4, which is the alphavirus replicase or an essential component of the replicase. We hypothesize that this domain of nsP4 functions to fix the minus strand as the stable template of alphavirus replication complexes.     

Human astrovirus C-terminal nsP1a protein is involved in RNA replication

Human astrovirus nonstructural C-terminal nsP1a protein, which contains a hypervariable region (HVR) and colocalizes with the endoplasmic reticulum and viral RNA, has been suggested to be involved in the RNA replication process. Four viruses differing only in their C-terminal nsP1a protein, corresponding to HVR-derived genotypes IV, V, VI, and XII, were all able to replicate in CaCo-2 cells but displayed differences in their RNA replication and growth properties. Two overall patterns of replication were observed: types IV and V on one side, and types VI and XII on the other. The main detected differences were on the levels of antigenomic and subgenomic RNAs, being the latter significantly higher in types IV and V. Accordingly, quantification of viral RNA load in feces from children with gastroenteritis showed that HVR-derived genotypes IV and V occur in significantly higher numbers. In consequence, it may be concluded that the variability of the C-terminal nsP1a gene affects the virus replication phenotype.     

Characterization of purified Sindbis virus nsP4 RNA-dependent RNA polymerase activity in vitro

The Sindbis virus RNA-dependent RNA polymerase (nsP4) is responsible for the replication of the viral RNA genome. In infected cells, nsP4 is localized in a replication complex along with the other viral non-structural proteins. nsP4 has been difficult to homogenously purify from infected cells due to its interactions with the other replication proteins and the fact that its N-terminal residue, a tyrosine, causes the protein to be rapidly turned over in cells. We report the successful expression and purification of Sindbis nsP4 in a bacterial system, in which nsP4 is expressed as an N-terminal SUMO fusion protein. After purification the SUMO tag is removed, resulting in the isolation of full-length nsP4 possessing the authentic N-terminal tyrosine. This purified enzyme is able to produce minus-strand RNA de novo from plus-strand templates, as well as terminally add adenosine residues to the 3′ end of an RNA substrate. In the presence of the partially processed viral replicase polyprotein, P123, purified nsP4 is able to synthesize discrete template length minus-strand RNA products. Mutations in the 3′ CSE or poly(A) tail of viral template RNA prevent RNA synthesis by the replicase complex containing purified nsP4, consistent with previously reported template requirements for minus-strand RNA synthesis. Optimal reaction conditions were determined by investigating the effects of time, pH, and the concentrations of nsP4, P123 and magnesium on the synthesis of RNA.     

Nucleoside triphosphatase and RNA helicase activities associated with GB virus B nonstructural protein 3.

GB virus B (GBV-B) is a positive-stranded RNA virus that belongs to the Flaviviridae family. This virus is closely related to hepatitis C virus (HCV) and causes acute hepatitis in tamarins (Saguinus species). Nonstructural protein 3 (NS3) of GBV-B contains sequence motifs predictive of three enzymatic activities: serine protease, nucleoside triphosphatase (NTPase), and RNA helicase. The N-terminal serine protease has been characterized and shown to share similar substrate specificity with the HCV NS3 protease. In this report, a full-length GBV-B NS3 protein was expressed in Escherichia coli and purified to homogeneity. This recombinant protein was shown to possess polynucleotide-stimulated NTPase and double-stranded RNA (dsRNA) unwinding activities. Both activities were abolished by a single amino acid substitution, from the Lys (K) residue in the conserved walker motif A (or Ia) "AXXXXGK(210)S" to an Ala (A), confirming that they are intrinsic to GBV-B NS3. Kinetic parameters (K(m) and k(cat)) for hydrolysis of various NTPs or dNTPs were obtained. The dsRNA unwinding activity depends on the presence of divalent metal ions and ATP and requires an RNA duplex substrate with 3' unpaired regions (RNAs with 5' unpaired regions only or with blunt ends are not suitable substrates for this enzyme). This indicates that GBV-B NS3 RNA helicase unwinds dsRNA in the 3' to 5' direction. Direct interaction of the GBV-B NS3 protein with a single-stranded RNA was established using a gel-based RNA bandshift assay. Finally, a homology model of GBV-B NS3 RNA helicase domain based on the 3-dimensional structure of the HCV NS3 helicase that shows a great similarity in overall structure and surface charge distribution between the two proteins was proposed.     

Expression,purification, and characterization of the RNA 5'-triphosphatase activity of dengue virus type 2 nonstructural protein 3

Dengue virus type 2 (DEN2), a member of the Flaviviridae family of positive-strand RNA viruses, contains a single RNA genome having a type I cap structure at the 5' end. The viral RNA is translated to produce a single polyprotein precursor that is processed to yield three virion proteins and at least seven nonstructural proteins (NS) in the infected host. NS3 is a multifunctional protein having a serine protease catalytic triad within the N-terminal 180 amino acid residues which requires NS2B as a cofactor for activation of protease activity. The C-terminal portion of this catalytic triad has conserved motifs present in several nucleoside triphosphatases (NTPases)/RNA helicases. In addition, subtilisin-treated West Nile (WN) virus NS3 from infected cells was reported to have 5'-RNA triphosphatase activity, suggesting its role in the synthesis of the 5'-cap structure. In this study, full-length DEN2 NS3 was expressed with an N-terminal histidine tag in Escherichia coli and purified in a soluble form. The purified protein has 5'-RNA triphosphatase activity that cleaves the gamma-phosphate moiety of the 5'-triphosphorylated RNA substrate. Biochemical and mutational analyses of the NS3 protein indicate that the nucleoside triphosphatase and 5'-RNA triphosphatase activities of NS3 share a common active site.     

Japanese encephalitis virus nonstructural protein NS3 has RNA binding and ATPase activities

Sequence data suggest that Japanese encephalitis virus (JEV) protein NS3 is a multifunctional protein with sequence motifs characteristic of a protease and a helicase. To examine the functions of JEV-NS3, a fusion protein of NS3 inEscherichia coli was generated. Analysis by Western blot using monospecific rabbit antisera generated against the fusion protein (anti-MBJEN3) showed that NS3 was localized in the membrane fraction of JEV-infected cells and the particulate fraction of bacteria extracts. The addition of anti-MBJEN3 sera reduced JEV-specific RNA synthesis activity in a in vitro system. In addition, NS3 was shown to exhibit RNA binding and ATPase activities, suggesting this protein has an important role in viral RNA replication in virus-infected cells.     

丙型肝炎病毒非结构蛋白NS3对端粒酶活性的影响

目的研究丙型肝炎病毒非结构区3(HCV NS3)蛋白对端粒酶活性的影响,以探讨HCV NS3蛋白在HCV致癌中的作用,并观察端粒酶活性原位检测法的应用价值.方法利用HCV NS3真核细胞表达质粒pRcHCNS3-5′(表达HCV NS3 N端多肽),pRcHCNS3-3′(表达HCV NS3C端多肽)和空白质粒pRcCMV转染NIH3T3细胞,分别获得11、11和8个阳性克隆;采用链霉素抗生物素-过氧化物酶法(SP)免疫组织化学方法检测转染的NIH3T3细胞中HCV NS3蛋白表达,并通过端粒酶活性原位检测法和端粒酶聚合酶链反应(PCR)酶联免疫吸附反应(ELISA)技术分别检测转染前后NIH3T3细胞端粒酶活性的定位和定量变化.结果 HCV NS3表达质粒pRcHCNS3-5′或pRcHCNS3-3′转染的NIH3T3细胞均表达HCV NS3蛋白,HCV NS3蛋白阳性信号均位于细胞质中,并以前者表达的阳性信号为强(χ2=6.667,P<0.05),各组细胞端粒酶活性存在显著差异(F=143.083,P<0.01),其中质粒pRcHCNS3-5′转染的NIH3T3细胞端粒酶活性最强,11个克隆均呈阳性,质粒pRcHCNS3-3′转染的细胞次之(P<0.05),空白质粒pRcCMV转染细胞和未转染NIH3T3细胞最弱;HCV NS3蛋白的表达水平和端粒酶活性强度之间具有显著相关性(rs=0.808 4,P<0.01);采用端粒酶活性原位检测方法和端粒酶PCR ELISA技术检测结果具有较好的一致性(rs=0.501 96,P<0.01).结论 (1) HCV NS3蛋白可能是通过内源性机制激活细胞端粒酶导致宿主细胞恶性转化;(2) HCV NS3蛋白 N端多肽对宿主细胞端粒酶的激活作用强于C端多肽;(3) 进一步证实端粒酶活性原位检测法是一种适合于病理形态与功能研究的技术.     

Antigenic variation in the influenza A virus nonstructural protein, NS1

The antigenic structure of the nonstructural (NS1) protein encoded by influenza type A virus was examined using monoclonal antibodies prepared against purified NS1 inclusions isolated from the cytoplasm of infected cells. Topographical analysis by competitive radioimmunoassay indicated that three different overlapping antigenic regions were present on the NS1 of A/WSN/33 (H1N1). Immunoprecipitation studies using infected cell lysates showed that antigenic determinants on A/WSN/33 NS1 are common to NS1 proteins encoded by a wide range of viruses of human, swine, equine, and avian origin. Several avian strains, however, were found to encode antigenically variant NS1 proteins which had either extensive changes in one or more antigenic regions or small changes in epitopes within a region suggestive of antigenic drift. There was no correlation between surface antigen subtype and the antigenic profile of the NS1 protein. The antigenic relationships of NS1 proteins shown in this study are in agreement with the available sequence data.     

Protective activity of a bacterial plasmid, bearing the gene for the tick-borne encephalitis virus NS1 nonstructural protein

Three intramuscular injections (50 micrograms each) with bacterial plasmid pMV45 carrying nonstructural gene of NS1 protein of tick-borne encephalitis (TBE) virus protected 88% Balb/c mice from lethal challenge with the virus. Antibodies to NS1 nonstructural protein were detected in the sera of vaccinated mice after the challenge. Absence of antibodies to E structural protein indicated absence of manifest infectious process in mice vaccinated with plasmid and challenged with a lethal dose of TBE virus.     

Proteolytic maturation of the 206-kDa nonstructural protein encoded by turnip yellow mosaic virus RNA.

The longest open reading frame of turnip yellow mosaic virus genomic RNA (ORF-206) encodes a 206-kDa nonstructural protein. The most prominent in vitro translation products of ORF-206 are the full-length p206 and a shorter N-coterminal 150-kDa protein. We have confirmed these assignments by immunoprecipitation of in vitro translation products with antisera raised to N-terminal and C-terminal regions encoded by ORF-206. The mechanism by which the 150-kDa protein arises from ORF-206 was investigated by in vitro translation of deletion and substitution derivatives transcribed from pTYMC, a cDNA clone of TYMV RNA. The following observations demonstrate that the 150-kDa protein and a C-terminal 70-kDa protein arise from ORF-206 by autoproteolysis: (1) Two regions encoded by ORF-206 were necessary for the formation of the 150-kDa protein: a domain between amino acids 555 and 1051, postulated to encode a protease, and the region between amino acids 1253 and 1261, thought to constitute the protease recognition and/or cleavage site. (2) Mutants with substitutions between amino acids 1253 and 1261 that produce low levels of the 150-kDa protein in in vitro translations also have high levels of p206 and low levels of the 70-kDa protein. (3) The rate of formation of the 150-kDa protein is dilution insensitive, suggesting that proteolysis occurs mainly in cis.