Complete nucleotide sequence of the mRNA coding for the N protein of vesicular stomatitis virus (New Jersey serotype)

Vesicular Stomatitis Virus Transmission: A Comparison of Incriminated Vectors

Vesicular stomatitis (VS) is a viral disease of veterinary importance, enzootic in tropical and subtropical regions of the Americas. In the U.S., VS produces devastating economic losses, particularly in the southwestern states where the outbreaks display an occurrence pattern of 10-year intervals. To date, the mechanisms of the geographic spread and maintenance cycles during epizootics remain unclear. This is due, in part, to the fact that VS epidemiology has a complex of variables to consider, including a broad range of vertebrate hosts, multiple routes of transmission, and an extensive diversity of suspected vector species acting as both mechanical and biological vectors. Infection and viral progression within vector species are highly influenced by virus serotype, as well as environmental factors, including temperature and seasonality; however, the mechanisms of viral transmission, including non-conventional pathways, are yet to be fully studied. Here, we review VS epidemiology and transmission mechanisms, with comparisons of transmission evidence for the four most incriminated hematophagous dipteran taxa: Aedes mosquitoes, Lutzomyia sand flies, Simulium black flies, and Culicoides biting midges.

Requirement for cyclophilin A for the replication of vesicular stomatitis virus New Jersey serotype

Several host proteins have been shown to play key roles in the life-cycle of vesicular stomatitis virus (VSV). We have identified an additional host protein, cyclophilin A (CypA), a chaperone protein possessing peptidyl cis-trans prolyl-isomerase activity, as one of the cellular factors required for VSV replication. Inhibition of the enzymatic activity of cellular CypA by cyclosporin A (CsA) or SDZ-211-811 resulted in a drastic inhibition of gene expression by VSV New Jersey (VSV-NJ) serotype, while these drugs had a significantly reduced effect on the genome expression of VSV Indiana (VSV-IND) serotype. Overexpression of a catalytically inactive mutant of CypA resulted in the reduction of VSV-NJ replication, suggesting a requirement for functional CypA for VSV-NJ infection. It was also shown that CypA interacted with the nucleocapsid (N) protein of VSV-NJ and VSV-IND in infected cells and was incorporated into the released virions of both serotypes. VSV-NJ utilized CypA for post-entry intracellular primary transcription, since inhibition of CypA with CsA reduced primary transcription of VSV-NJ by 85-90 %, whereas reduction for VSV-IND was only 10 %. Thus, it seems that cellular CypA binds to the N protein of both serotypes of VSV. However, it performs an obligatory function on the N protein activity of VSV-NJ, while its requirement is significantly less critical for VSV-IND N protein function. The different requirements for CypA by two serologically different viruses belonging to the same family has highlighted the utilization of specific host factors during their evolutionary lineages.

A novel fish rhabdovirus from sweden is closely related to the Finnish rhabdovirus 903/87

A novel rhabdovirus, preliminary designated as the Sea trout rhabdovirus 28/97 (STRV 28/97), was isolated from sea trout (Salmo trutta trutta) in Sweden in 1996. The fish showed central nervous symptoms, and at the autopsy petechial bleedings in the mesenteric fat were visible. STRV 28/97 was shown to be serologically related to the vesiculotype rhabdovirus 903/87 isolated from brown trout (Salmo trutta lacustris) in Finland [1,3]. The sequences for the nucleocapsid protein, phosphoprotein, matrix protein, glycoprotein and beginning of the polymerase protein of STRV 28/97 were determined. At the amino acid level the genes were over 97% similar to virus 903/87. The nucleocapsid proteins, glycoproteins and beginning of the polymerase protein of STRV 28/97 and virus 903/87 were clustered with the vesiculoviruses and the phosphoproteins close to the vesiculoviruses in protein parsimony analysis. The matrix proteins formed a distinct clade in protein parsimony analysis.

Study of the assembly of vesicular stomatitis virus N protein: role of the P protein

To derive structural information about the vesicular stomatitis virus (VSV) nucleocapsid (N) protein, the N protein and the VSV phosphoprotein (P protein) were expressed together in Escherichia coli. The N and P proteins formed soluble protein complexes of various molar ratios when coexpressed. The major N/P protein complex was composed of 10 molecules of the N protein, 5 molecules of the P protein, and an RNA. A soluble N protein-RNA oligomer free of the P protein was isolated from the N/P protein-RNA complex using conditions of lowered pH. The molecular weight of the N protein-RNA oligomer, 513,879, as determined by analytical ultracentrifugation, showed that it was composed of 10 molecules of the N protein and an RNA of approximately 90 nucleotides. The N protein-RNA oligomer had the appearance of a disk with outer diameter, inner diameter, and thickness of 148 +/- 10 A, 78 +/- 9 A, and 83 +/- 8 A, respectively, as determined by electron microscopy. RNA in the complexes was protected from RNase digestion and was stable at pH 11. This verified that N/P protein complexes expressed in E. coli were competent for encapsidation. In addition to coexpression with the full-length P protein, the N protein was expressed with the C-terminal 72 amino acids of the P protein. This portion of the P protein was sufficient for binding to the N protein, maintaining it in a soluble state, and for assembly of N protein-RNA oligomers. With the results provided in this report, we propose a model for the assembly of an N/P protein-RNA oligomer.

Carboxy-terminal five amino acids of the nucleocapsid protein of vesicular stomatitis virus are required for encapsidation and replication of genome RNA

The encapsidation of vesicular stomatitis virus (VSV) genome RNA, a prerequisite step to the replication process by the nucleocapsid protein (N) was studied by its ability to package VSV leader RNA in vitro in a RNase-resistant form. The VSV leader RNA was derived from the SP6 transcription vector while the N protein was made in rabbit reticulocyte lysate. The in vitro encapsidation was carried out by translating N mRNA in the presence of 32P-labeled presynthesized leader RNA. The RNA encapsidation property of the N protein was completely abrogated when the C-terminal five amino acids (VEFDK-COOH) were deleted. Systematic mutational analyses within the C-terminal five amino acid regions reveal that the RNA encapsidation activity was lost in all mutants except K --> A and K --> R, indicating that C-terminal five amino acids, in particular the lysine residue play critical role in genome RNA encapsidation. To correlate the in vitro encapsidation abilities of these mutant N proteins with genome RNA replication, we have used a full-length cDNA clone of VSV genome RNA to rescue infectious virions from cells expressing L, P, and wt or mutant N proteins and measured the recovery of plaque forming units. The results indicate that the N mutants that are defective in in vitro encapsidation of leader RNA do not support replication, establishing the requirement of C-terminal five amino acids of the N protein in viral replication.

Construction and insect larval expression of recombinant vesicular stomatitis nucleocapsid protein and its use in competitive ELISA

The gene encoding the nucleocapsid (N) protein of Indiana 1 serotype vesicular stomatitis virus (VSV-IN1) was transferred into the genome of Autographa californica nuclear polyhedrosis virus (baculovirus) as a full-length non-fusion construct under the control of the polyhedrin gene promoter. Recombinant N protein was obtained from Trichoplusia ni insect larvae inoculated 72-96 h previously with the recombinant baculovirus. Polyclonal antibody (PAB) against VSV-IN1 was produced in mice using VSV-IN1 whole virus antigen concentrated from virus-infected cell culture fluids. The N protein and the PAB were used without further purification in a competitive enzyme-linked immunosorbent assay (C-ELISA) for detection of bovine, porcine, and equine origin serum antibodies against VSV-IN1. A limited number of field origin, experimental, and reference VSV antisera were evaluated using the C-ELISA and with a standard serum neutralization (SN) procedure. Sensitivity of the C-ELISA was comparable to the serotypically homologous SN procedure. Subject to further validation, similar C-ELISA tests for the other VSV serotypes, used in conjunction with the test described here, may offer the best combination of rapidity, sensitivity, simplicity, economy, and laboratory biosafety of any of the methods yet developed for VSV serodiagnosis.

Optimization of targeted RNA recombination and mapping of a novel nucleocapsid gene mutation in the coronavirus mouse hepatitis virus

We have recently described a method of introducing site-specific mutations into the genome of the coronavirus mouse hepatitis virus (MHV) by RNA recombination between cotransfected genomic RNA and a synthetic subgenomic mRNA (C. A. Koetzner, M. M. Parker, C. S. Ricard, L. S. Sturman, and P. S. Masters, J. Virol. 66:1841-1848, 1992). By using a thermolabile N protein mutant of MHV (Alb4) as the recipient virus and synthetic RNA7 (the mRNA for the nucleocapsid protein N) as the donor, we selected engineered recombinant viruses as heat-stable progeny resulting from cotransfection. We have now been able to greatly increase the efficiency of targeted recombination in this process by using a synthetic defective interfering (DI) RNA in place of RNA7. The frequency of recombination is sufficiently high that, with Alb4 as the recipient, recombinants can be directly identified without using thermal selection. The synthetic DI RNA has been used to demonstrate that the lesion in another temperature-sensitive and thermolabile MHV mutant, Alb1, maps to the N gene. Sequencing of the Alb1 N gene revealed two closely linked point mutations that fall in a region of the N molecule previously noted as being the most highly conserved region among all of the coronavirus N proteins. Analysis of revertants of the Alb1 mutant revealed that one of the two mutations is critical for the temperature-sensitive phenotype; the second mutation is phenotypically silent.

Enhancement of fish mortality by rhabdovirus infection after immunization with a viral nucleoprotein peptide

A similar sequence to a mouse immunodominant CTL peptide (SYVLQGN, single-letter amino acid code, conserved amino acids underlined) identified in the nucleoproteins of several strains of vesicular stomatitis virus (VSV) (37) was found in the nucleoproteins of viral hemorrhagic septicemia virus (VHSV) of salmonid fish (GYVYQGL in VHSV 07.71 and GYVYQGS in VHSV Makah) and not in the nucleoproteins of other rhabdoviruses. The in vivo immunization of fingerling salmonid fish (rainbow trout Onchorynchus mykiss, W) with this VHSV peptide and their subsequent challenge with VHSV resulted in the enhancement rather than in the reduction of fingerling trout mortality. Possible implications for the development of subunit vaccines against VHSV are discussed.

Structural analysis on the single-stranded genomic DNAs of the virus newly isolated from silkworm: the DNA molecules share a common terminal sequence

Recently, a parvo-like virus was newly isolated from silkworm larvae and the two viral DNAs (VD1 and VD2) with different electro-mobilities were identified. We cloned the viral DNAs in a plasmid pUC119 and demonstrated that these two DNAs were not a bimorphic molecules though they shared a common terminal sequence of 53 nucleotides. In addition, the sequence at the 5' terminus of each strand of the viral DNA was located in inverted form at its 3' terminus. On the other hand, the nucleotide sequences of VD1 and VD2 were different from that of the Bombyx densovirus (Ina isolate) DNA.

An L (polymerase)-deficient rabies virus defective interfering particle RNA is replicated and transcribed by heterologous helper virus L proteins

A rabies virus-derived defective interfering particle (DI) was isolated and characterized. The DI genome contained an internal deletion of 6.4 kb spanning the 3' moiety of the pseudogene region (psi) and most of the L gene. DI-specific monocistronic N, NS, and M mRNAs as well as a G/L fusion mRNA were transcribed in cells coinfected with DI and helper virus. In addition, polycistronic DI RNAs and standard virus RNAs with internal A stretches and intergenic regions were found. Superinfection experiments showed that heterologous rabies-related viruses (Lyssavirus serotypes 2, 3, and 4) can complement the L deficiency of the DI genome. The heterologous polymerase proteins recognize correctly the replicational and transcriptional signal sequences of the Lyssavirus serotype 1-derived DI.

Autoantigenicity of Ro/SSA antigen is related to a nucleocapsid protein of vesicular stomatitis virus

The fine specificity of a reference human anti-Ro/SSA autoantibody-containing serum has been analyzed by using sequential overlapping octapeptides from the human 60-kDa Ro/SSA antigen. From preliminary data, the most antigenic octapeptide in the carboxyl-terminal 120 amino acid residues of Ro/SSA shares seven of eight amino acids with the nucleocapsid (N) protein from the Indiana serotype of vesicular stomatitis virus. A sequence comparison of Ro/SSA and N has unexpectedly revealed six small peptides shared by Ro/SSA and N. Fine specificity analysis with 531 octapeptides from the Ro/SSA sequence demonstrates that five of the six shared small peptides are bound by anti-Ro/SSA (P = 0.00017). A more powerful association is not present in 12,476 protein sequences similarly evaluated. In addition, the inclusion of single-residue gaps in Ro/SSA enlarges the sequence similarity of Ro/SSA and N for three of the five small shared antigenic peptides. This additional level of sequence similarity between Ro/SSA and N is unlikely to be the result of chance (P less than 0.0002). While a number of models may explain these data, including independent immune responses to N and Ro/SSA, these results are also consistent with anti-Ro/SSA autoantibodies being the consequence of a specific viral exposure.

Gene expression of nonsegmented negative strand RNA viruses

Nonsegmented negative strand RNA viruses comprise major human and animal pathogens in nature. This class of viruses is ubiquitous and infects vertebrates, invertebrates, and plants. Our laboratory has been working on the gene expression of two prototype nonsegmented negative strand RNA viruses, vesicular stomatitis virus (a rhabdovirus) and human parainfluenza virus 3 (a paramyxovirus). An RNA-dependent RNA polymerase (L and P protein) is packaged within the virion which faithfully copies the genome RNA in vitro and in vivo; this enzyme complex, in association with the nucleocapsid protein (N), is also involved in the replication process. In this review, we have presented up-to-date information of the structure and function of the RNA polymerases of these two viruses, the mechanisms of transcription and replication, and the role of host proteins in the life-cycle of the viruses. These detailed studies have led us to a better understanding of the roles of viral and cellular proteins in the viral gene expression.

Sequence analyses of the 3' genome end and NP gene of human parainfluenza type 2 virus: sequence variation of the gene-starting signal and the conserved 3' end

We cloned and determined the nucleotide sequences of cDNAs against nucleocapsid protein (NP) mRNA and the genomic RNA of human parainfluenza type 2 virus (PIV-2). The 3' terminal region of genomic RNA was compared among PIV-2, mumps virus (MuV), Newcastle disease virus (NDV), measles virus (MV), PIV-3, bovine parainfluenza type 3 virus (BPIV-3), Sendai virus (SV), and vesicular stomatitis virus (VSV), and an extensive sequence homology was observed between PIV-2 and MuV. Although no significant sequence relatedness was observed between PIV-2 and other viruses, the terminal four nucleotides were identical in the viruses compared, implying a specific role of these nucleotides on the replication of paramyxoviruses. A primer extension analysis elucidated the major NP mRNA initiation site with the sequence UCUAAGCC, which showed a moderate homology with the gene-starting consensus sequences of other paramyxoviruses. On the other hand, the NP mRNA was terminated at the nucleotide stretch AAAUUCUUUUU, and this sequence was conserved in all the PIV-2 genes, indicating that the oligonucleotides will form a part of the gene attenuation signal of PIV-2. Comparisons of NP protein sequence indicated a possible subgrouping of the paramyxoviruses into two groups, one of which is a group including PIV-2, PIV-4, MuV, and NDV, and another is a group including PIV-3, BPIV-3, and SV. This result supports an idea from our previous studies using polyclonal and monoclonal antibodies. Furthermore, our data indicated that the PIV-2 NP protein sequence was more closely related to MV and CDV than to other parainfluenza viruses, PIV-3 and SV.

Vesicular stomatitis virion-associated transcriptase activity was suppressed in vitro by a synthetic 21 amino acid oligopeptide prepared to mimic the carboxy-terminus of NS protein

To study the biological function of the NS protein of vesicular stomatitis virus (VSV), we prepared 21 species of synthetic oligopeptides with 11-21 amino acid residues, corresponding to every portion of the amino acid sequence of NS protein (Indiana serotype), and tested their effects on the VS virion (VSV) transcriptase activity in vitro. Only one peptide affected the virion-associated transcriptase activity of VSV Indiana, by reducing the incorporation of [3H]GMP into acid-insoluble fraction (IC50 = 26 microM). This peptide, the amino acid sequence of which corresponded to the carboxy (C)-terminal region of NS protein, also inhibited the New Jersey serotype virus transcriptase activity, as expected from a high degree of homology found between the amino acid sequences of the C-terminal regions of NS protein of both serotype viruses. Electrophoretic analysis on acrylamide gels of RNA transcripts revealed that the inhibitory synthetic peptide decreased the frequency of the initiation of transcription with no apparent effect on the chain-elongation process of viral transcription. As expected from its highly conserved amino acid sequence, these results suggest that the C-terminal domain of VSV NS protein is involved in initiating viral RNA synthesis.

Phosphoprotein and nucleocapsid protein evolution of vesicular stomatitis virus New Jersey

The entire phosphoprotein (P) and nucleocapsid (N) protein gene sequences and deduced amino acid sequences for 18 selected vesicular stomatitis virus isolates representative of the natural genetic diversity within the New Jersey serotype are reported. Phylogenetic analysis of the data using maximum parsimony allowed construction of evolutionary trees for the individual genes and the combined N, P, and glycoprotein (G) genes of these viruses. Virtually identical rates of nucleotide substitutions were found for each gene, indicating that evolution of these genes occurs at essentially the same rate. Although up to 19 and 17% sequence differences were evident in the P and N genes, respectively, no variation in gene length or evidence of recombinational rearrangements was found. However, striking evolutionary differences were observed among the amino acid sequences of vesicular stomatitis virus New Jersey N, P, and G proteins. The N protein amino acid sequence was the most highly conserved among the different isolates, indicating strong functional and structural constraints. Conversely, the P protein amino acid sequences were highly variable, indicating considerably fewer constraints or greater evolutionary pressure on the P protein. Much of the remarkable amino acid variability of the P protein resided in a hypervariable domain located between amino acids 153 and 205. The variability within this region would be consistent with it playing a structural role as a spacer to maintain correct conformational presentation of the separate active domains of this multifunctional protein. In marked contrast, the adjacent domain I of the P protein (previously thought to be under little evolutionary constraint) contained a highly conserved region. The colocalization of a short, potentially functional overlapping open reading frame to this region may explain this apparent anomaly.

Nucleotide sequence analysis of the L gene of vesicular stomatitis virus (New Jersey serotype): identification of conserved domains in L proteins of nonsegmented negative-strand RNA viruses

We have determined the nucleotide sequence of the L gene of vesicular stomatitis virus (VSV), New Jersey serotype (Ogden strain) by primer extension dideoxy sequencing of the genomic RNA with reverse transcriptase. This analysis completes the entire genomic sequence of the VSVNJ (Ogden). Comparison of the deduced amino acid sequence of this L protein with those reported for L proteins of Indiana serotype and Hazelhurst strain of New Jersey serotype revealed an extensive sequence similarity among all three proteins. The comparison was further extended to the L proteins of other nonsegmented negative-strand RNA viruses, namely the rabies virus and four members of the paramyxovirus family: measles, Newcastle disease, human parainfluenza 3, and Sendai viruses. Our findings confirmed the existence of conserved as well as unique domains in the L proteins, suggesting an evolutionary relationship among these viruses.

Replication of the genome RNAs of defective interfering particles of vesicular stomatitis and Sendai viruses using heterologous viral proteins

We have tested the ability of heterologous viral proteins to support the in vivo and in vitro replication of the RNA of defective interfering (DI) particles of two serotypes of VSV and of Sendai virus. In all the combinations of heterologous coinfections in vivo, DI particle replication was observed only in the coinfection with the VSV-Indiana DI particle and wild-type VSV-New Jersey. By quantitating RNA synthesis in reconstitution experiments we showed that with DI nucleocapsids isolated from infected cells, however, the soluble protein fraction from heterologous wild-type virus-infected cells could substitute in vitro to varying degrees for the homologous proteins in the elongation reaction of RNA replication and encapsidation. In these cases successful replication was confirmed by demonstrating the specific association of the heterologous N protein with the product nucleocapsid RNA. The initiation step, that is, the initial binding of the nucleocapsid protein to the leader RNA, in contrast, requires the homologous protein, since heterologous viral proteins could not support RNA replication and encapsidation from purified DI particles.

Complex formation with vesicular stomatitis virus phosphoprotein NS prevents binding of nucleocapsid protein N to nonspecific RNA

The interactions between the nucleocapsid protein N and either RNA or the phosphoprotein NS of vesicular stomatitis virus (VSV) were studied by the transcription of N and NS mRNAs from SP6 vectors, followed by translation in a rabbit reticulocyte lysate. Nascent N protein bound tightly to added labeled RNA, as well as to endogenous RNA in the reticulocyte lysate. This binding was demonstrated by three independent techniques. First, labeled N protein and labeled RNA migrated identically as a series of sharp, closely spaced bands in a nondenaturing gel system. Second, translated N protein behaved as a stable ribonucleoprotein complex in CsCl gradients and sedimented to the same density as the authentic N-RNA template of VSV. Third, translated N protein protected a series of labeled RNA fragments from digestion by RNase A. None of the three RNA-binding criteria was satisfied by either translated NS protein or two deletion mutants of N protein or by other components of the reticulocyte lysate. The evidence suggests that the observed binding of RNA by nascent N was not RNA sequence specific, in contrast to the encapsidation process during VSV replication. Moreover, the prior formation of N-NS complexes totally abolished the observed binding of RNA by N. Thus, we propose that NS may be responsible for conferring the sequence specificity of the RNA binding that occurs during VSV genome replication.

Resolution of multiple complexes of phosphoprotein NS with nucleocapsid protein N of vesicular stomatitis virus

The interaction of the nucleocapsid protein N and the phosphoprotein NS of vesicular stomatitis virus (VSV) was studied, free of other viral proteins, by transcription from SP6 vectors, followed by translation in a rabbit reticulocyte lysate. N-NS complex formation depended strongly on cotranslation of the two proteins; when N and NS were mixed following separate translation of each, very little complex formation occurred. Conditions were found under which at least six N-NS complexes were separated from each other by electrophoresis in a nondenaturing gel system, and the following findings were made. (i) These complexes fell into two groups; complexes 1 through 5 all had a stoichiometry of two molecules of N to one molecule of NS, whereas N-NS complex 6 had an equimolar ratio of the two proteins. (ii) N-NS complexes 1 through 5 predominated at lower concentrations of NS relative to N, but N-NS complex 6 was the major or sole product when NS was equimolar to or in excess of N. (iii) The two sets of complexes were formed by two distinct types of interactions of NS with N. The formation of N-NS complexes 1 through 5 was abolished by the removal of as few as 11 amino acid residues from the basic, highly conserved carboxy-terminal domain of NS, which is essential for the binding of NS to the N-RNA template of VSV. In contrast, formation of complex 6 was unaffected by removal of as many as 62 of the carboxy-terminal amino acids of NS, a region encompassing both the terminal basic domain and an adjacent domain which is required for VSV RNA polymerase function. The significance of these observations for the mechanism of VSV genome replication is discussed.

Sequence variability and function of measles virus 3' and 5' ends and intercistronic regions

Sequences critical for the activity of the measles virus (MV) RNA polymerase in transcription and replication were analyzed using a MV genomic cDNA library containing overlapping clones encompassing the entire MV genome. Clones corresponding to the 3' and 5' ends of the MV genome were identified and sequenced, and these sequences were confirmed by primer extension experiments. Neither (+) nor (-) strand leader RNAs were detected in MV-infected cell extracts, using high specific activity riboprobes made form these clones. Clones representing each of the MV gene boundaries were also sequenced, and variations including point mutations, insertions, and deletions were noted. Together with the sequence of the MV L gene region, this report completes the sequence determination of the MV genome.

Structure of the M2 protein gene of sonchus yellow net virus

The nucleotide sequence of the gene immediately following the nucleocapsid protein gene of sonchus yellow net virus (SYNV), a plant rhabdovirus, is presented. Serological reactions of SYNV proteins with antibodies elicited by a fusion protein constructed from the sequenced gene indicate that this gene encodes an SYNV structural protein designated M2. The 5' end of the M2 protein mRNA appears to correspond to position 1700 relative to the 3' end of SYNV RNA, because an extension product that maps to this position was synthesized by reverse transcription of polyadenylated [poly(A)+] RNA from infected tobacco that had been primed with an SYNV-specific oligodeoxyribonucleotide. The 3' end of the gene encoding the M2 protein is defined by a recombinant DNA plasmid derived from poly(A)+ RNA from SYNV-infected plants. This plasmid contains an insert with a 3'-terminal region corresponding to a uridylate-rich sequence present at positions 2832 to 2836 on SYNV genomic (g) RNA. These data thus suggest that the M2 protein mRNA is 1132 nucleotides (NT) long, excluding the poly(A) tail, and consists of a 50-NT untranslated 5' region, a 1035-NT open reading frame (ORF), and a 47-NT untranslated 3'region. The ORF is capable of encoding a 345-amino acid protein with a calculated molecular weight of 38,332. A small region of the M2 protein appears to have some similarity to the phosphoproteins of other rhabdoviruses. An identical 14-NT region occurs at the two sequenced gene junctions on SYNV gRNA and shares homology with regions separating the genes of some animal rhabdoviruses.

Intergenic sequences of the vesicular stomatitis virus genome (New Jersey serotype): evidence for two transcription initiation sites within the L gene

The intergenic sequences of vesicular stomatitis virus of the New Jersey serotype [VSV (NJ): Ogden strain] have been determined by dideoxy sequencing across the gene junctions of the viral RNA genome using deoxyoligonucleotide primers. The N-NS, NS-M, and M-G intergenic sequences of VSV (NJ) are identical to the consensus intergenic sequence for VSV of the Indiana serotype [VSV (IND)]: 3'-AUACU7GAUUGUCNNNAG-5' (genome sense; N denotes any nucleotide), where 3'-AUACU7-5' encodes the 3' terminus and the start of the polyadenylate tract of the preceding mRNA, 3'-UUGUCNNNAG-5' encodes the 5' terminus of the succeeding mRNA, and 3'-GA-5' is a nontranscribed dinucleotide. Notably, the NS-M junction of VSV (NJ) does not contain the anomalous dinucleotide 3'-CA-5' which is found at the NS-M junction of VSV (IND). In striking contrast to VSV (IND), the G-L intergenic sequence of VSV (NJ) contains a 19-base insertion between the nontranscribed dinucleotide and the consensus mRNA start sequence. During in vitro transcription, the L mRNA of VSV (NJ) may initiate at two distinct sites: the first start site (3'-CCUUAUCUUC-5') is that flanking the nontranscribed dinucleotide, and the second start site is a consensus mRNA start sequence located 20 bases downstream from the nontranscribed dinucleotide. However, the L mRNA isolated form VSV (NJ)-infected cells appears to initiate only at the consensus start sequence. The possible role of these start sites in L mRNA synthesis is discussed.

Sequences of Chandipura virus N and NS genes: evidence for high mutability of the NS gene within vesiculoviruses

The nucleotide sequence of the 3' end of the genome of Chandipura (CHP) virus, including the complete sequences of the nucleocapsid (N) and phosphoprotein (NS) genes was determined, principally from cloned cDNAs of the N and NS mRNAs. The NS mRNA of CHP virus is 908 bases in length and encodes a protein of 293 amino acids. Comparison of the CHP virus NS protein sequence with those of vesicular stomatitis virus of the New Jersey serotype (VSV (NJ)) and of the Indiana serotype (VSV (IND] revealed homologies of only 23 and 21%, respectively, with no consecutive stretches of more than four amino acids identical among the three sequences. As with the two VSV serotypes, the highest homology between the NS proteins of CHP and VSV was in a 20-amino acid region near the carboxy termini of the proteins. Of the potential phosphorylation sites, there are eight conserved serine or threonine residues among the three sequences. Despite the dissimilarity among primary sequences of the NS proteins, their overall structure, as assessed by amino acid composition and by the relative hydropathicities of the sequences, has been conserved throughout evolution. The N mRNA of CHP virus is 1291 bases long and encodes a protein of 422 amino acids. In contrast to the NS protein, the CHP N protein is at least 50% homologous to the N proteins of each of the VSV serotypes. We have identified a region near the center of these N protein sequences which is conserved among members of both the rhabdovirus and paramyxovirus families. This extent of conservation of the N protein sequences underscores the high rate of mutability of the NS protein sequences among the vesiculoviruses.

Genome RNA terminus conservation and diversity among vesiculoviruses

Sequence analysis of the RNA genome termini of various vesiculovirus standard and defective interfering (DI) particles demonstrated that some virus regulatory sequences and domains of virus N protein are highly conserved while others show considerable divergence. Clearly, distinct RNA signal sequences and protein-coding regions of these virus genomes have quite different evolutionary pressures or constraints. Terminal regions of DI-particle RNA genomes of these viruses were found to possess self-complementary stems at the RNA termini, demonstrating the conservation of this DI-particle structural feature throughout the vesiculovirus group. A high degree of conservation of the 3'-terminal sequences of recent and historic isolates of vesicular stomatitis virus New Jersey was also demonstrated.

Defective interfering particles of VSVNJ (Ogden), generated by heat treatment, contain multiple internal genomic deletions

Defective interfering (DI) particles have been isolated from a heat-resistant strain of the New Jersey (Ogden) serotype of vesicular stomatitis virus (VSV). Most of these DI particles contain various portions of all five cistrons of VSV. The two largest DI particles, NJ-121 and NJ-PG2, represent approximately 60% of the standard virus genome and contain both the positive and negative strand leader RNA templates. These two DI particles are transcriptionally active and synthesize both the positive and negative strand leader RNAs in vitro. Virion RNA probe-mRNA hybridizations and cDNA probe-virion RNA hybridizations have shown that NJ-121 contains mainly sequences from the L and G genes. In contrast, NJ-PG2 has portions of the sequences from all five genes of VSV. Smaller DI particles, NJ-121a, NJ-121b, NJ-PG1, and NJ-JM2 representing approximately 50, 38, 28, and 25% of the standard virus genome respectively, were also generated. These DI particles did not have sequences complementary to the positive strand leader RNA template. The mRNA hybridization patterns and results of the genomic RNAs hybridizing to cDNAs of N, NS, M, and G genes of these DI particles showed that they contain parts of information from all five cistrons. Most of the DI particles appear to be generated by multiple deletions throughout the standard virus genome. None of these DI particles interfered heterotypically with VSVIND-HR in BHK21, R(B77), or L2 cells. However, they interfered well with infection by VSVNJ (Hazelhurst).

Complete nucleotide sequence of the matrix protein mRNA of vesicular stomatitis virus (New Jersey serotype)

The complete nucleotide sequence of the mRNA of the matrix (M) protein of vesicular stomatitis virus [New Jersey serotype, VSV(NJ)] was derived from a cDNA clone and mRNA. The mRNA is 758 nucleotides long (excluding polyadenylic acid) and encodes a protein of 229 amino acids. The predicted amino acid sequence was compared with that of the corresponding protein of Indiana serotype [VSV(IND)] and a fish rhabdovirus, spring viremia of carp virus (SVCV). An amino acid identity of 62% was found between the M proteins of VSV(NJ) and VSV(IND) while only 24% was present between VSV(NJ) and SVCV. A highly basic NH2-terminal domain followed by a proline-proline-X-tyrosine sequence was present in all the three M polypeptides. Except for the L gene sequence, the complete nucleotide sequence of the four genes of VSV(NJ) are now known. The comparison of the amino acid sequences between the Indiana and New Jersey serotypes demonstrates a high degree of homology between these genes except for the phosphoprotein gene, NS.

A computer program for translating DNA sequences into protein

This paper describes a comprehensive program for translating one or two DNA sequences into amino acid sequences. Written in FORTRAN, it was designed for maximum flexibility of use and easy maintenance, modification and portability. It has full comments throughout.

Vesicular stomatitis virus NS proteins: structural similarity without extensive sequence homology

The complete nucleotide sequence of the NS mRNA of vesicular stomatitis virus (New Jersey serotype) was established from two cDNA clones spanning the entire coding region of the mRNA. The gene is 856 nucleotides long and can code for a polypeptide of 274 amino acids. Comparison with the nucleotide sequence of the NS gene of the Indiana serotype revealed only 41% sequence homology. The deduced amino acid sequences of the NS proteins were only 32% homologous, with no identical stretches of more than five amino acids. However, at the C-terminal domain there was a conserved region of 21 amino acids with greater than 90% homology. Surprisingly, relative hydropathicity plots also demonstrated the presence of a large number of hydrophilic amino acids sequestered similarly over the N-terminal half of the protein. In addition, the total number of serine and threonine residues, presumptive phosphorylation sites, was similar and included seven serine and three threonine residues located at identical positions. It appears that during divergent evolution of these two vesicular stomatitis virus serotypes from a common ancestor, considerable mutation occurred in the main body of the gene but the overall structure of the protein was retained. The function of the NS protein in relation to the evolution of the two viruses is discussed.