Interference and RNA homologies of New Jersey serotype isolates vesicular stomatitis virus and their defective particles

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.

Interferon induction by viruses. XIX. Vesicular stomatitis virus--New Jersey: high multiplicity passages generate interferon-inducing, defective-interfering particles

The infectious particles of plaque-derived, low multiplicity passaged wild-type VSV of New Jersey origin consistently induce about 1800 units of interferon (IFN)/10(7) aged chick embryo cells. This inducing capacity is sensitive to both uv radiation and heat (50 degrees). Virus obtained after two successive high multiplicity passages in GMK-Vero cells consistently induced over 25,000 units of IFN/10(7) cells. The IFN induction dose-response curve showed that one IFN-inducing particle (IFP) per cell sufficed to produce a quantum yield of IFN, but infection with two or more IFPs led initially to a marked suppression in the yield of IFN. IFN induction was attributed to two distinct defective particles that differed in size, both containing snap-back RNA, i.e., covalently linked, self-complementary [+/-]RNA. The IFN-inducing capacity of these defective-interfering particles was not inactivated by uv or heat. However heat did eliminate the IFN suppressing activity observed at higher multiplicities, implicating a heat-sensitive component in the virion as a regulator of IFN yield, and involving possibly the virion transcriptase and 3'-leader RNA product.

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).

Tubulin: a factor necessary for the synthesis of both Sendai virus and vesicular stomatitis virus RNAs

Tubulin acts as a positive transcription factor for in vitro RNA synthesis by two different negative-strand viruses: Sendai virus, a paramyxovirus; vesicular stomatitis virus (VSV), a rhabdovirus. A monoclonal antibody directed against beta-tubulin completely inhibited not only mRNA synthesis and RNA replication catalyzed in vitro by extracts of cells infected with either virus but also mRNA synthesis by detergent-disrupted purified virions. The synthesis of both a leader-like RNA and the NP mRNA directed by detergent-disrupted purified Sendai virions was shown to be totally dependent on the addition of purified tubulin. The addition of purified tubulin, although not required, also stimulated mRNA synthesis directed by detergent-disrupted VSV virions 2- to 7-fold. Finally, there appears to be an association between tubulin and the L protein of VSV, since both monoclonal and polyclonal anti-tubulin antisera specifically immunoprecipitated not only tubulin but also the L protein of two different VSV serotypes from the soluble protein fraction of infected cells.

Characterization of New Jersey vesicular stomatitis virus isolates from horses and black flies during the 1982 outbreak in Colorado

Vesicular stomatitis viruses isolated from horses, afflicted during the recent outbreak in the western United States, and from black flies (Simuliidae) were characterized with respect to the homology of their genomic RNAs and the mobility of their proteins in polyacrylamide gels. All the isolates were very similar, if not identical, with respect to these two parameters. When the black fly isolate was compared to other VSV isolates, this virus appeared to belong in the Hazelhurst subgroup of the New Jersey serotype of VSV. Since the other viruses in this division were obtained from infected swine, the natural host range of this subgroup has been extended to horses.

In vitro and in vivo inhibition of primary transcription of vesicular stomatitis virus by a defective interfering particle

A unique defective interfering (DI) particle, generated by a heat-resistant (HR) mutant of Indiana serotype vesicular stomatitis virus, was capable of inhibiting primary transcription by heterologous New Jersey serotype virions. The correlation between this phenomenon and the lowering of viral yields from doubly infected cells was investigated by the construction of chimeric DI particles containing the HR DI particle genome with a thermolabile polymerase. At the nonpermissive temperature, these DI particles were unable to self-transcribe, inhibit virion primary transcription, or reduce virion yield, but were able to be replicated. These results suggested that self-transcription of the HR DI particle genome was a prerequisite for heterotypic interference, but not for its own replication. Inhibition of virion primary transcription by HR DI ribonucleocapsids was also observed in vitro. At low HR DI to virion ribonucleocapsid ratios, the extent of inhibition was concentration dependent, whereas at high ratios, the amount of inhibition was concentration independent, approaching a limiting maximum value. A speculative mathematical model, which quantitatively accounts for these data, is presented. According to this model, the higher affinity for polymerase molecules by the HR DI ribonucleocapsids is explained in terms of dissociation events during transcription, which are more frequent in the longer virion ribonucleocapsids.