Requirements and functions of vesicular stomatitis virus L and NS proteins in the transcription process in vitro

The L and NS proteins of vesicular stomatitis virus were purified from transcribing ribonucleoprotein complex and were used to study their requirements and functions during reconstitution of RNA synthesis in vitro. The requirements for L and NS proteins for optimal RNA synthesis were found to be catalytic and stoichiometric, respectively. Addition of increasing amounts of NS protein to N-RNA template and saturating L protein, the ratio of N-mRNA to leader RNA synthesis increased linearly. In contrast, when the concentration of L protein was increased the corresponding ratio remained constant. These results, coupled with the observation that the L protein is involved in the initiation of RNA synthesis, suggest that the NS protein is involved in the RNA chain elongation step. The NS protein possibly interacts with both the L protein and the template N-RNA and unwinds the latter to facilitate the movement of L protein on the template RNA.     

Phosphorylation within a specific domain of the phosphoprotein of vesicular stomatitis virus regulates transcription in vitro

We have investigated the functional significance of phosphoserine residues that lie in the L protein-binding domain between amino acids 213 and 247 of the phosphoprotein (NS) of vesicular stomatitis virus. A series of mutant NS proteins were made by cell-free translation of mRNAs transcribed from the cloned gene. Site-directed substitution of alanine for both serine 236 and serine 242 essentially abolished RNA synthesis catalyzed by the NS-L complex. Substitution of either of these serines reduced RNA synthesis by 75%. Serine 218 played no major role in RNA synthesis. Phosphorylation of NS by the L protein was abrogated by substitution of either serine 236 or serine 242. These results indicate that phosphorylation of serines 236 and 242 in the NS protein regulates its binding with the L protein and the N-RNA template and is essential for activation of viral RNA synthesis.     

Phosphorylation of Vesicular Stomatitis Virus In Vivo and In Vitro

The structural protein, NS, of purified vesicular stomatitis virus (VSV) is a phosphoprotein. In infected cells phosphorylated NS is found both free in the cytoplasm and as part of the viral ribonucleoprotein (RNP) complex containing both the 42S RNA and the structural proteins L, N, and NS, indicating that phosphorylation occurs as an early event in viral maturation. VSV contains an endogenous protein kinase activity, probably of host region, which catalyzes the in vitro phosphorylation of the viral proteins NS, M, and L, but not of N or G. The phosphorylated sites on NS appear to be different in the in vivo and in vitro reactions, and are differentially sensitive to alkaline phosphatase. After removal of the membrane components of purified VSV with a dextran-polyethylene glycol two-phase separation, the kinase activity remains tightly associated with the viral RNP. However, viral RNP isolated from infected cells shows only a small amount of kinase activity. The protein kinase enzyme appears to be a cellular contaminant of purified VSV because an activity from the uninfected cell extract can phosphorylate in vitro the dissociated viral proteins NS and M. The virion-associated activity may be derived either from the cytoplasm or the plasma membrane of the host cell since both of these cellular components contain protein kinase activity similar to that found in purified VSV.     

Sensitivity of the Polymerase of Vesicular Stomatitis Virus to 2′ Substitutions in the Template and Nucleotide Triphosphate during Initiation and Elongation

The RNA synthesis machinery of non-segmented negative-sense RNA viruses comprises a ribonucleoprotein complex of the genomic RNA coated by a nucleocapsid protein (N) and associated with polymerase. Work with vesicular stomatitis virus (VSV), a prototype, supports a model of RNA synthesis whereby N is displaced from the template to allow the catalytic subunit of the polymerase, the large protein (L) to gain access to the RNA. Consistent with that model, purified L can copy synthetic RNA that contains requisite promoter sequences. Full processivity of L requires its phosphoprotein cofactor and the template-associated N. Here we demonstrate the importance of the 2′ position of the RNA template and the substrate nucleotide triphosphates during initiation and elongation by L. The VSV polymerase can initiate on both DNA and RNA and can incorporate dNTPs. During elongation, the polymerase is sensitive to 2′ modifications, although dNTPs can be incorporated, and mixed DNA-RNA templates can function. Modifications to the 2′ position of the NTP, including 2′,3′-ddCTP, arabinose-CTP, and 2′-O-methyl-CTP, inhibit polymerase, whereas 2′-amino-CTP is incorporated. The inhibitory effects of the NTPs were more pronounced on authentic N-RNA with the exception of dGTP, which is incorporated. This work underscores the sensitivity of the VSV polymerase to nucleotide modifications during initiation and elongation and highlights the importance of the 2′-hydroxyl of both template and substrate NTP. Moreover, this study demonstrates a critical role of the template-associated N protein in the architecture of the RNA-dependent RNA polymerase domain of L.     

Utilization of homotypic and heterotypic proteins of vesicular stomatitis virus by defective interfering particle genomes for RNA replication and virion assembly: implications for the mechanism of homologous viral interference

Defective interfering (DI) particles of Indiana serotype of vesicular stomatitis virus (VSV(Ind)) are capable of interfering with the replication of both homotypic VSV(Ind) and heterotypic New Jersey serotype (VSV(NJ)) standard virus. In contrast, DI particles from VSV(NJ) do not interfere with the replication of VSV(Ind) standard virus but do interfere with VSV(NJ) replication. The differences in the interfering activities of VSV(Ind) DI particles and VSV(NJ) DI particles against heterotypic standard virus were investigated. We examined the utilization of homotypic and heterotypic VSV proteins by DI particle genomic RNAs for replication and maturation into infectious DI particles. Here we show that the RNA-nucleocapsid protein (N) complex of one serotype does not utilize the polymerase complex (P and L) of the other serotype for RNA synthesis, while DI particle genomic RNAs of both serotypes can utilize the N, P, and L proteins of either serotype without serotypic restriction but with differing efficiencies as long as all three proteins are derived from the same serotype. The genomic RNAs of VSV(Ind) DI particles assembled and matured into DI particles by using either homotypic or heterotypic viral proteins. In contrast, VSV(NJ) DI particles could assemble only with homotypic VSV(NJ) viral proteins, although the genomic RNAs of VSV(NJ) DI particles could be replicated by using heterotypic VSV(Ind) N, P, and L proteins. Thus, we concluded that both efficient RNA replication and assembly of DI particles are required for the heterotypic interference by VSV DI particles.     

Translation of Vesicular Stomatitis Messenger RNA by Extracts from Mammalian and Plant Cells

RNA was isolated from polyribosomes of vesicular stomatitis virus (VSV)-infected cells and tested for its ability to direct protein synthesis in extracts of animal and plant cells. In cell-free, non-preincubated extracts of rabbit reticulocytes, the 28S VSV RNA stimulated synthesis of a protein the size of the vesicular stomatitis virus L protein whereas the 13 to 15S RNA directed synthesis of the VSV M, N, NS, and possibly G proteins. In wheat germ extracts, 13 to 15S RNA also directed synthesis of the N, NS, M, and possibly G proteins. Analysis of extracts labeled with formyl [(35)S]methionine showed that the 28S RNA directed the initiation of synthesis of one protein, whereas the 13 to 15S RNA directed initiation of at least four proteins. It is concluded that the 28S RNA encodes only the L protein, whereas the 13 to 15S RNA is a mixture of species, presumably monocistronic, which code for the four other known vesicular stomatitis virus proteins.