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

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.

Viral RNA and protein synthesis in two LLC-MK2 cell lines persistently infected with human parainfluenza virus 3

Two lines of LLC-MK2 cells persistently infected with human parainfluenza virus 3 (HPIV-3) have been maintained in culture for approximately 3 years. Subgenomic RNAs (putative defective interfering particle genomes) were detected in virions released from both persistently infected cultures. In one of the persistently infected cell lines cyclic variation in the production of virions containing standard virus genomic-size (50S) RNA and subgenomic RNA was observed. The molar ratio of subgenomic RNA to 50S RNA ranged from less than 0.1/1 to 8.7/1. Northern blot analyses revealed that the patterns of viral mRNA synthesis in persistently infected cells from both cultures were similar to those of standard virus infected cells. Furthermore, the intracellular viral-specific proteins had electrophoretic mobilities similar to the corresponding proteins in standard virus-infected cells. Nucleotide sequence analysis of cloned M gene from virus after 29 months of persistence (147 passages) revealed only one variable conservative amino acid change in two clones analyzed from each cell line, indicating that the M protein is not likely to be involved in the maintenance of the persistent infections. The possible mechanisms by which the persistent state is maintained are discussed.

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.

The 5'-terminal sequence of VSV(NJ) (Ogden): is the interaction of the NS protein with the NS binding site responsible for heterotypic interference activity?

The 5'-terminal sequence of VSV(NJ) (Ogden) and VSV(NJ) (Hazelhurst) was compared in an attempt to understand why the defective interfering particle, DI-LT, heterotypically interferes with VSV(NJ) (Ogden) but not with VSV(NJ) (Hazelhurst). The 5'-terminal sequence of VSV(NJ) (Ogden) genomic RNA was determined by direct RNA sequencing and by DNA sequencing of cDNA clones of the 3'-terminal sequence of VSV(NJ) (Ogden) DI particle genome. Primer extension analysis of the 5'-terminus of VSV(NJ) (Ogden) standard genomic RNA confirmed these data. Within the last 47 nucleotides, equivalent to the negative-strand leader RNA, the only nucleotide changes between VSV(NJ) (Ogden) and VSV(NJ) (Hazelhurst) occur between nucleotides 19 and 26, representing part of the putative NS binding region described by Isaac and Keene (J. Virol. 43, 241-249 (1982] for VSV(IND) DI particles. The spacer (S) region, located between the polyadenylation signal of the L gene and the 47th nucleotide of the leader RNA, contains more differences. The polyadenylation signal of the L gene is fully conserved, but the remainder of the L gene region (177 nucleotides) has highly diverged between VSV(NJ) (Ogden) and VSV(NJ) (Hazelhurst). The changes in the NS binding region of the negative-strand leader RNA provide further evidence for the divergent evolution of VSV(NJ) (Ogden) and VSV(NJ) (Hazelhurst). The NS binding region has been implicated as a crucial site for the initiation of RNA transcription and replication. The interaction of the NS protein with this site may determine the ability of DI particles to interfere heterotypically.

A defective interfering RNA that contains a mosaic of a plant virus genome

A symptom-modulating RNA associated with tomato bushy stunt virus (TBSV) was investigated with respect to physical and biological properties. Linear RNA of approximately 396 nucleotides was packaged in viral coat protein and was dependent on TBSV for replication. Coinoculation of the small RNA with TBSV resulted in the attenuation of TBSV-induced symptoms and depression of virus synthesis in whole plants. Nucleotide sequence analysis revealed that the symptom-modulating RNA was derived from 5', 3', and internal segments of the TBSV genome. The identification of this symptom-modulating RNA as a co-linear deletion mutant of the helper virus genome establishes it as the first definitive defective interfering RNA (DI RNA) to be identified in association with a plant virus.