Defective T particles of vesicular stomatitis virus. I. Preparation, morphology, and some biologic properties

Defective viral genomes: advances in understanding their generation, function, and impact on infection outcomes

Defective viral genomes (DVGs) are truncated derivatives of their parental viral genomes generated during an aberrant round of viral genomic replication. Distinct classes of DVGs have been identified in most families of both positive- and negative-sense RNA viruses. Importantly, DVGs have been detected in clinical samples from virally infected individuals and an emerging body of association studies implicates DVGs in shaping the severity of disease caused by viral infections in humans. Consequently, there is growing interest in understanding the molecular mechanisms of de novo DVG generation, how DVGs interact with the innate immune system, and harnessing DVGs as novel therapeutics and vaccine adjuvants to attenuate viral pathogenesis. This minireview focuses on single-stranded RNA viruses (excluding retroviridae), and summarizes the current knowledge of DVG generation, the functions and diversity of DVG species, the roles DVGs play in influencing disease progression, and their application as antivirals and vaccine adjuvants.

Defective Interfering Particles of Influenza Virus and Their Characteristics, Impacts, and Use in Vaccines and Antiviral Strategies: A Systematic Review

Defective interfering particles (DIPs) are particles containing defective viral genomes (DVGs) generated during viral replication. DIPs have been found in various RNA viruses, especially in influenza viruses. Evidence indicates that DIPs interfere with the replication and encapsulation of wild-type viruses, namely standard viruses (STVs) that contain full-length viral genomes. DIPs may also activate the innate immune response by stimulating interferon synthesis. In this review, the underlying generation mechanisms and characteristics of influenza virus DIPs are summarized. We also discuss the potential impact of DIPs on the immunogenicity of live attenuated influenza vaccines (LAIVs) and development of influenza vaccines based on NS1 gene-defective DIPs. Finally, we review the antiviral strategies based on influenza virus DIPs that have been used against both influenza virus and SARS-CoV-2. This review provides systematic insights into the theory and application of influenza virus DIPs.

Defective Interfering Particles of Negative-Strand RNA Viruses

Viral defective interfering particles (DIPs) were intensely studied several decades ago but research waned leaving open many critical questions. New technologies and other advances led to a resurgence in DIP studies for negative-strand RNA viruses. While DIPs have long been recognized, their exact contribution to the outcome of acute or persistent viral infections has remained elusive. Recent studies have identified defective viral genomes (DVGs) in human infections, including respiratory syncytial virus and influenza, and growing evidence indicates that DVGs influence disease severity and may contribute to viral persistence. Further, several studies have advanced our understanding of key viral and host factors that regulate DIP formation and activity. Here we review these discoveries and highlight key questions moving forward.

Collective Viral Spread Mediated by Virion Aggregates Promotes the Evolution of Defective Interfering Particles

Recent insights have revealed that viruses use a highly diverse set of strategies to release multiple viral genomes into the same target cells, allowing the emergence of beneficial, but also detrimental, interactions among viruses inside infected cells. This has prompted interest among microbial ecologists and evolutionary biologists in studying how collective dispersal impacts the outcome of viral infections. Here, we have used vesicular stomatitis virus as a model system to study the evolutionary implications of collective dissemination mediated by viral aggregates, since this virus can spontaneously aggregate in the presence of saliva. We find that saliva-driven aggregation has a dual effect on viral fitness; whereas aggregation tends to increase infectivity in the very short term, virion aggregates are highly susceptible to invasion by noncooperative defective variants after a few viral generations.

A growing number of studies report that viruses can spread in groups in so-called collective infectious units. By increasing the cellular multiplicity of infection, collective dispersal may allow for social-like interactions, such as cooperation or cheating. Yet, little is known about how such interactions evolve. In previous work with vesicular stomatitis virus, we showed that virion aggregation accelerates early infection stages in most cell types, providing a short-term fitness benefit to the virus. Here, we examine the effects of virion aggregation over several infection cycles. Flow cytometry, deep sequencing, infectivity assays, reverse transcription-quantitative PCR, and electron microscopy revealed that virion aggregation rapidly promotes the emergence of defective interfering particles. Therefore, virion aggregation provides immediate fitness benefits to the virus but incurs fitness costs after a few viral generations. This suggests that an optimal strategy for the virus is to undergo virion aggregation only episodically, for instance, during interhost transmission.

Defective viral genomes are key drivers of the virus-host interaction

Viruses survive often harsh host environments, yet we know little about the strategies they utilize to adapt and subsist given their limited genomic resources. We are beginning to appreciate the surprising versatility of viral genomes and how replication-competent and -defective virus variants can provide means for adaptation, immune escape and virus perpetuation. This Review summarizes current knowledge of the types of defective viral genomes generated during the replication of RNA viruses and the functions that they carry out. We highlight the universality and diversity of defective viral genomes during infections and discuss their predicted role in maintaining a fit virus population, their impact on human and animal health, and their potential to be harnessed as antiviral tools.

This Review describes recent findings on the biogenesis and the role of defective viral genomes during replication of RNA viruses and discusses their impact on viral dynamics and evolution.

The Impact of Defective Viruses on Infection and Immunity

Defective viral genomes (DVGs) are generated during viral replication and are unable to carry out a full replication cycle unless coinfected with a full-length virus. DVGs are produced by many viruses, and their presence correlates with alterations in infection outcomes. Historically, DVGs were studied for their ability to interfere with standard virus replication as well as for their association with viral persistence. More recently, a critical role for DVGs in inducing the innate immune response during infection was appreciated. Here we review the role of DVGs of RNA viruses in shaping outcomes of experimental as well as natural infections and explore the mechanisms by which DVGs impact infection outcome.

Defective (interfering) viral genomes re-explored: impact on antiviral immunity and virus persistence

Defective viral genomes (DVGs) are natural products of virus replication that occur in many positive and negative sense RNA viruses, including Ebola, dengue and respiratory syncytial virus. DVGs, which have severe genomic truncations and require a helper virus to replicate, have three well-described functions: interference with standard virus replication, immunostimulation, and establishment of virus persistence. These functions of DVGs were first described almost 50 years ago, yet only recent studies have shown the molecular intersection between their immunostimulatory and pro-persistence activities. Here, we review more than half a century of scientific literature on the immunostimulatory and pro-persistence functions of DVGs. We highlight recent advances in the field and the critical role DVGs have in both the acute and long-term virus-host interactions.

An overview of process intensification and thermo stabilization for upscaling of Peste des petits ruminants vaccines in view of global control and eradication

Peste des petits ruminants (PPR) has been recognized as a globally distributed disease affecting the small ruminant population. The disease results in severe economic losses mainly to small land holders and low input farming systems. The control of PPR is mainly achieved through vaccination with available live attenuated vaccines. The thermo labile nature of PPR virus poses a major constraint in production of quality vaccines which often results in vaccine failures. The lack of quality vaccine production jeopardize the wide vaccination coverage especially in countries with poor infrastructure due to which PPR persists endemically. The vaccine production system may require augmentation to attain consistent and quality vaccines through efforts of process intensification integrated with suitable stabilizer formulations with appropriate freeze drying cycles for improved thermo tolerance. Manufacturing of live attenuated PPR vaccines during batch cultures might introduce defective interfering particles (DIPs) as a result of high multiplicity of infection (MOI) of inoculums, which has a huge impact on virus dynamics and yield. Accumulation of DIPs adversely affects the quality of the manufactured vaccines which can be avoided through use of appropriate MOI of virus inoculums and quality control of working seed viruses. Therefore, adherence to critical manufacturing standard operating procedures in vaccine production and ongoing efforts on development of thermo tolerant vaccine will help a long way in PPR control and eradication programme globally. The present review focuses on the way forward to achieve the objectives of quality vaccine production and easy upscaling to help the global PPR control and eradication by mass vaccination as an important tool.

A Defective Interfering Influenza RNA Inhibits Infectious Influenza Virus Replication in Human Respiratory Tract Cells: A Potential New Human Antiviral

Defective interfering (DI) viruses arise during the replication of influenza A virus and contain a non-infective version of the genome that is able to interfere with the production of infectious virus. In this study we hypothesise that a cloned DI influenza A virus RNA may prevent infection of human respiratory epithelial cells with infection by influenza A. The DI RNA (244/PR8) was derived by a natural deletion process from segment 1 of influenza A/PR/8/34 (H1N1); it comprises 395 nucleotides and is packaged in the DI virion in place of a full-length genome segment 1. Given intranasally, 244/PR8 DI virus protects mice and ferrets from clinical influenza caused by a number of different influenza A subtypes and interferes with production of infectious influenza A virus in cells in culture. However, evidence that DI influenza viruses are active in cells of the human respiratory tract is lacking. Here we show that 244/PR8 DI RNA is replicated by an influenza A challenge virus in human lung diploid fibroblasts, bronchial epithelial cells, and primary nasal basal cells, and that the yield of challenge virus is significantly reduced in a dose-dependent manner indicating that DI influenza virus has potential as a human antiviral.

Quantitative characterization of defective virus emergence by deep sequencing

Populations of RNA viruses can spontaneously produce variants that differ in genome size, sequence, and biological activity. Defective variants that lack essential genes can nevertheless reproduce by coinfecting cells with viable virus, a process that interferes with virus growth. How such defective interfering particles (DIPs) change in abundance and biological activity within a virus population is not known. Here, a prototype RNA virus, vesicular stomatitis virus (VSV), was cultured for three passages on BHK host cells, and passages were subjected to Illumina sequencing. Reads from the initial population, when aligned to the full-length viral sequence (11,161 nucleotides [nt]), distributed uniformly across the genome. However, during passages two plateaus in read counts appeared toward the 5' end of the negative-sense viral genome. Analysis by normalization and a simple sliding-window approach revealed plateau boundaries that suggested the emergence and enrichment of at least two truncated species having medium (∼5,900 nt) and short (∼4,000 nt) genomes. Relative measures of full-length and truncated species based on read counts were validated by quantitative reverse transcription-PCR (qRT-PCR). Limit-of-detection analysis suggests that deep sequencing can be more sensitive than complementary measures for detecting and quantifying defective particles in a population. Further, particle counts from transmission electron microscopy, coupled with infectivity assays, linked the rise in smaller genomes with an increase in truncated particles and interference activity. In summary, variation in deep sequencing coverage simultaneously shows the size, location, and relative level of truncated-genome variants, revealing a level of population heterogeneity that is masked by other measures of viral genomes and particles.

IMPORTANCE

We show how deep sequencing can be used to characterize the emergence, diversity, and relative abundance of truncated virus variants in virus populations. Adaptation of this approach to natural isolates may elucidate factors that influence the stability and persistence of virus populations in nature.

The length of vesicular stomatitis virus particles dictates a need for actin assembly during clathrin-dependent endocytosis

Microbial pathogens exploit the clathrin endocytic machinery to enter host cells. Vesicular stomatitis virus (VSV), an enveloped virus with bullet-shaped virions that measure 70 x 200 nm, enters cells by clathrin-dependent endocytosis. We showed previously that VSV particles exceed the capacity of typical clathrin-coated vesicles and instead enter through endocytic carriers that acquire a partial clathrin coat and require local actin filament assembly to complete vesicle budding and internalization. To understand why the actin system is required for VSV uptake, we compared the internalization mechanisms of VSV and its shorter (75 nm long) defective interfering particle, DI-T. By imaging the uptake of individual particles into live cells, we found that, as with parental virions, DI-T enters via the clathrin endocytic pathway. Unlike VSV, DI-T internalization occurs through complete clathrin-coated vesicles and does not require actin polymerization. Since VSV and DI-T particles display similar surface densities of the same attachment glycoprotein, we conclude that the physical properties of the particle dictate whether a virus-containing clathrin pit engages the actin system. We suggest that the elongated shape of a VSV particle prevents full enclosure by the clathrin coat and that stalling of coat assembly triggers recruitment of the actin machinery to finish the internalization process. Since some enveloped viruses have pleomorphic particle shapes and sizes, our work suggests that they may use altered modes of endocytic uptake. More generally, our findings show the importance of cargo geometry for specifying cellular entry modes, even when the receptor recognition properties of a ligand are maintained.

A confocal and electron microscopic comparison of interferon beta-induced changes in vesicular stomatitis virus infection of neuroblastoma and nonneuronal cells

Vesicular stomatitis virus (VSV) replication is highly sensitive to interferon (IFN)-induced antiviral responses. Pretreatment of sensitive cultured cells with IFNbeta results in a 10(4)-fold reduction in the release of infectious VSV particles. However, differences exist between the mechanisms of reduced infectious particle titers in cell lines of neuroblastoma and nonneuronal lineage. In L929-fibroblast-derived cells, using immunofluorescence confocal microscopy, infection under control conditions reveals the accumulation of VSV matrix, phosphoprotein (P), and nucleocapsid (N) proteins over time, with induced cellular morphological changes indicative of cytopathic effects (CPEs). Upon observing L929 cells that had been pretreated with IFNbeta, neither detectable VSV proteins nor CPEs were seen, consistent with type I IFN antiviral protection. When using the same techniques to observe VSV infections of NB41A3 cells, a neuroblastoma cell line, aside from similar viral progression in the untreated control cells, IFNbeta-treated cells illustrated a severely attenuated VSV infection. Attenuated VSV progression was observed through detection of VSV matrix, P, and N proteins in isolated cells during the first 8 h of infection. However, by 18-24 h postinfection all neuroblastomas had succumbed to the viral infection. Finally, upon closer inspection of IFNbeta-treated NB41A3 cells, no detectable changes in VSV protein localization were identified compared with untreated, virally infected neuroblastomas. Next, to extend our study to test our hypothesis that virion assembly is compromised within type I IFN-treated neuroblastoma cells, we employed electron microscopy to examine our experimental conditions at the ultrastructural level. Using VSV-specific antibodies in conjunction with immuno-gold reagents, we observed several similarities between the two cell lines, such as identification of viroplasmic regions containing VSV N and P proteins and signs of stress-induced CPEs of VSV-infected cells, which had either been mock-treated or pretreated with interferon-beta (IFNbeta). One difference we observed between nonneuronal and neuroblastoma cells was more numerous actively budding VSV virions across untreated L929 plasma membranes compared with untreated NB41A3 cells. Additionally, IFNbeta-treated, VSV-infected L929 cells exhibited neither cytoplasmic viroplasm nor viral protein expression. In contrast, IFNbeta-treated, VSV-infected NB41A3 cells showed evidence of VSV infection at a very low frequency as well as small-scale viroplasmic regions that colocalized with viral N and P proteins. Finally, we observed that VSV viral particles harvested from untreated VSV-infected L929 and NB41A3 cells were statistically similar in size and shape. A portion of VSV virions from IFNbeta-treated, virally infected NB41A3 cells were similar in size and shape to virus from both untreated cell types. However, among the sampling of virions, pleomorphic viral particles that were identified from IFNbeta-treated, VSV-infected NB41A3 cells were different enough to suggest a misassembly mechanism as part of the IFNbeta antiviral state in neuroblastoma cells.

A defective interference-like phenomenon of human hepatitis B virus in chronic carriers

Defective interfering (DI) particles have been found in many RNA and DNA viruses of bacteria, plants, and animals since their first discovery in influenza virus. However, this fundamental phenomenon has not been demonstrated in human natural infections. Using a new approach, here we provide the first experimental evidence for the existence of DI-like viruses in human chronic carriers of hepatitis B virus (HBV). Functional characterization of naturally occurring core internal deletion (CID) variants of HBV revealed all of the features of DI particles. When equal amounts of wild-type and CID variant DNAs were cotransfected into a human hepatoma cell line, Huh7, a three- to fivefold enrichment of CID variants was most often observed. The fluctuations of the virus populations between CID variants and helper HBV in three chronic carriers are reminiscent of the cycling phenomenon in other DI viral systems. This finding has important implications for chronic viral hepatitis and other chronic progressive viral diseases.

Multiple mechanisms for the inhibition of entry and uncoating of superinfecting Semliki Forest virus

Recombinant Semliki Forest viruses (SFV) that express one or none of the viral structural proteins were used to infect cells and to analyze the fate of incoming superinfecting wild-type viruses. It was found that in addition to the previously described block in replication that superinfecting viruses encounter within 15 min of infection, other mechanisms of superinfection inhibition occurred at later times. Over a 6-hr infection period, inhibition was seen in binding of virus to the cell surface, in acid-activated penetration into the cytoplasm, and in uncoating of nucleocapsids. For each of these processes, the inhibitory mechanism was investigated. In summary, we found that infection evoked several independent mechanisms for blocking the entry and uncoating of superinfecting viruses. The results also offered new insights into the normal processes of penetration and uncoating of SFV.

Penetration of cells by herpes simplex virus does not require a low pH-dependent endocytic pathway

Agents that perturb endocytosis or that alter the pH of endosomes were shown to have little or no effect on plaque formation by herpes simplex virus (HSV), whereas plaque formation by vesicular stomatitis virus was inhibited as expected. A number of agents were tested for their ability to inhibit early events in HSV infection. Amantadine, chloroquine and trifluoperazine, whose actions are known to alter the endocytic pathway, showed no selective inhibitory effects on early events in HSV infection. Wheat germ agglutinin and heparin, known inhibitors of HSV infection, blocked the adsorption of virus to cells, as expected. Succinylated concanavalin A blocked plaque formation without inhibiting virus adsorption but could enhance the elution of bound virus. To a greater or lesser extent, succinylated concanavalin A, dithiothreitol, colchicine, monensin and cytochalasin B all inhibited or reduced the rate of events subsequent to adsorption and prior to early viral protein synthesis. Evidence is presented to suggest that each of these agents has a different mode of action. On the basis of these results and others, we conclude that endocytosis is probably not required for infection by HSV (at least not the low pH-dependent endocytic pathway) and that events occurring at the cell surface trigger virion-cell fusion leading to infection.

Characterization of a macrophage-tropic HIV strain that does not alter macrophage cytokine production yet protects macrophages from superinfection by vesicular stomatitis virus

Macrophages, unlike CD4+ T cells, can be productively infected by human immunodeficiency virus (HIV) without prior cellular activation. Cytopathic infection ensues without the induction of tumor necrosis factor alpha (TNF alpha), interleukin 1 beta (IL-1 beta), interleukin 6 (IL-6), or tissue factor genes. In detailed studies on TNF alpha, HIV infection did not affect the regulation of TNF alpha in response to bacterial lipopolysaccharide. In an effort to examine the interferon responsiveness of HIV-infected macrophages, the cells were challenged with vesicular stomatitis virus (VSV) with or without interferon pretreatment. Surprisingly, HIV-infected macrophages were completely resistant to VSV-induced lysis even in the absence of interferon; however, no interferon was detected in the supernatants of these infected cells. The resistance of HIV-infected macrophages to superinfection with VSV indicates a previously undescribed effect of HIV upon macrophage cellular metabolism.

Membrane anchors of vesicular stomatitis virus: characterization and incorporation into virions

Wild-type vesicular stomatitis virus-infected cells contained multiple carboxy-terminal fragments of the envelope glycoprotein G. They migrated in 16% polyacrylamide gels with two dominant apparent molecular weights, 14,000 and 9,000. Both fragments were immunoprecipitated by two antibodies, anti-G(COOH) and anti-G(stem), made against the last 15 amino acids at the carboxy terminus and against the first 22 amino acids of the ectodomain adjacent to the transmembrane region of G, respectively. Pulse-chase experiments in the presence and absence of tunicamycin indicated that the higher-molecular-weight fragment, Gal, was generated first, presumably in the rough endoplasmic reticulum, and then apparently chased into the faster-migrating, stable fragment, Ga2. Exposure of infected cells to radioactive palmitic acid labeled Ga2. Ga2 was detected in purified virions. These results show that a polypeptide approximately 71 amino acids long is transported and incorporated into budding virions. What signals are operative and whether this C-terminal fragment of G protein is transported as a complex with other viral or host cell proteins are presently unknown.

Formation, characterization and interfering capacity of a small plaque mutant and of incomplete virus particles of infectious bursal disease virus

Serial undiluted passages of infectious bursal disease virus in chick embryo cells were accompanied by a von Magnus type fluctuation of infectivity in viral harvests and a gradual decrease of plaque size. From the 9th undiluted passage on, the whole virus population consisted of small plaque-forming virus. The small plaque size remained constant when subsequent infections were carried out at low multiplicities. Small plaque virus interfered with the replication of large plaque standard virus. The small plaque/low yield mutation favoured the generation of defective particles which could be separated from complete particles by their lower densities in CsCl-gradients, where six fractions became visible and could be analyzed separately. Most of the defective virus particles had lost the larger of their two dsRNA segments and showed an aberrant protein composition. They had a very low residual infectivity and were also able to interfere with the replication of complete virus.

Characterization of virulent isolates of vesicular stomatitis virus in relation to interference by defective particles

To investigate the role that defective interfering (DI) particles might conceivably play in the epizootiology of vesicular stomatitis, two virulent New Jersey (NJ) isolates from the 1982-1983 epizootic in the United States (US) were compared with three laboratory adapted strains of vesicular stomatitis virus (VSV): NJ Hazelhurst, NJ Ogden and Indiana San Juan. Successive undiluted passages showed that the virulent isolates did not readily exhibit 'autointerference' because they did not readily generate and amplify DI particles. Viral RNA synthesis of isolates that were exposed to homotypic or heterotypic DI particles generated from the laboratory strains showed that the isolates were totally resistant to the heterotypic DI particle and partially resistant to the homotypic DI particle. In contrast, Indiana San Juan and NJ Ogden were inhibited by hetero- or homotypic DI particles. NJ Hazelhurst more closely resembled the isolates. This demonstrates that virulence of VSV in its natural setting may be related to a number of factors, including the slower generation and amplification of endogenous DI particles, as well as the increased resistance of the virus to some pre-existing DI particles.

Antibody-induced modulation of proteins in vesicular stomatitis virus-infected fibroblasts

When vesicular stomatitis virus-infected baby hamster kidney cells were treated with rabbit anti-vesicular stomatitis virus serum, there was a loss of the viral glycoprotein G into acid-soluble products. This degradation occurred within minutes at 37 degrees C and required the presence of G protein at the cell surface. The degree of degradation depended on antiserum concentration. The antiserum, also, prevented maturation of extracellular virions and induced partial degradation of the intracellular viral proteins, without affecting host proteins. The degradation could not be prevented by the presence of lysosomotropic agents, protease inhibitors, colchicine, or cytochalasin B. Similar kinetics and specificity of degradation was obtained with cells infected with vesicular stomatitis virus mutants that were less cytopathic. These results characterize a model system for studying the parameters and consequences of antigenic modulation as well as for studying the fate of viral antigens during persistent infections.

Antibody-induced modulation of proteins in vesicular stomatitis virus-infected fibroblasts

When vesicular stomatitis virus-infected baby hamster kidney cells were treated with rabbit anti-vesicular stomatitis virus serum, there was a loss of the viral glycoprotein G into acid-soluble products. This degradation occurred within minutes at 37 degrees C and required the presence of G protein at the cell surface. The degree of degradation depended on antiserum concentration. The antiserum, also, prevented maturation of extracellular virions and induced partial degradation of the intracellular viral proteins, without affecting host proteins. The degradation could not be prevented by the presence of lysosomotropic agents, protease inhibitors, colchicine, or cytochalasin B. Similar kinetics and specificity of degradation was obtained with cells infected with vesicular stomatitis virus mutants that were less cytopathic. These results characterize a model system for studying the parameters and consequences of antigenic modulation as well as for studying the fate of viral antigens during persistent infections.

Immunoprecipitating human antigens associated with vesicular stomatitis virus grown in HeLa cells

Vesicular stomatitis virus (VSV) preparations made in HeLa cells, VSV(HeLa), appeared to contain non-viral structural proteins. This was suggested by neutralization of the virus with homologous and heterologous antisera made against VSV prepared in different cells. Antisera against uninfected HeLa cells failed to neutralize VSV(HeLa) but did immunoprecipitate the virus in the presence of Staphylococcus aureus. These immunoprecipitated VSV(HeLa) retained their infectivity, despite the presence of antibody and bacteria. The anti-HeLa cell serum did not react with VSV grown in rodent cells nor did anti-Vero cells serum immunoprecipitate VSV(HeLa). When the anti-HeLa cell serum was absorbed with whole HeLa cells, it no longer specifically precipitated VSV(HeLa). Because over 98% of infectious VSV(HeLa) was neutralizable by anti-VSV serum and immunoprecipitable by anti-HeLa serum, these virions were called mosaics. Physical identification of HeLa cell determinants on the mosaics was accomplished by further purification and radioiodination followed by selective immunoprecipitations with antisera. Two to three major bands with molecular weights around 75,000 Da were identified as HeLa cell determinants associated with the mosaic VSV(HeLa).

Nucleotide sequence of a cDNA clone encoding the entire glycoprotein from the New Jersey serotype of vesicular stomatitis virus

The nucleotide sequence of the mRNA encoding the glycoprotein from the New Jersey serotype of vesicular stomatitis virus (VSV) was determined from a cDNA clone containing the entire coding region. The sequence of 12 5'-terminal noncoding nucleotides present in the mRNA but not in the cDNA clone was determined from a primer extended to the 5' terminus of the mRNA. The mRNA is 1,573 nucleotides long (excluding polyadenylic acid) and encodes a protein of 517 amino acids. Only six nucleotides occur between the translation termination codon and the polyadenylic acid. Short homologies between the untranslated termini of this mRNA and the mRNAs of the Indiana serotype were found. The predicted protein sequence was compared with that of the glycoprotein of the Indiana serotype of VSV and with the glycoprotein of rabies virus, using a computer program which determines optimal alignment. An amino acid identity of 50.9% was found for the two VSV serotypes. Approximately 20% identity was found between the rabies virus and VSV New Jersey glycoproteins. The positions and sizes of the transmembrane domains, the signal sequences, and the glycosylation sites are identical in both VSV serotypes. Two of five serine residues which were possible esterification sites for palmitate in the glycoprotein from the Indiana serotype are changed to glycine residues in the glycoprotein from the New Jersey serotype. Because the glycoprotein of the New Jersey serotype does not contain esterified palmitate, we suggest that one or both of these residues are the probable esterification sites in the glycoprotein from the Indiana serotype.

Interference among defective interfering particles of vesicular stomatitis virus

Three defective interfering (DI) particles of vesicular stomatitis virus (VSV), all derived from the same parental standard San Juan strain (Indiana serotype), were used in various combinations to infect cells together with the parental virus. The replication of their RNA genomes in the presence of other competing genomes was described by the hierarchical sequence: DI 0.52 particles greater than DI 0.45 particles less than or equal to DI-T particles greater than standard VSV. The advantage of one DI particle over another was not due simply to multiplicity effects nor to the irreversible occupation of limited cellular sites. Interference, however, did correlate with a change in the ratio of plus and minus RNA templates that accumulated intracellularly and with the presence of new sequences at the 3' end of the DI genomes. DI 0.52 particles contained significantly more nucleotides at the 3' end that were complementary to those at the 5' end of its RNA than did DI-T or DI 0.45 particles. The first 45 nucleotides at the 3' ends of all of the DI RNAs were identical. VSV and its DI particles can be separated into three classes, depending on their terminal RNA sequences. These sequences suggest two mechanisms, one based on the affinity of polymerase binding and the other on the affinity of N-protein binding, that may account for interference by DI particles against standard VSV and among DI particles themselves.

Comparison of ribonucleotide sequences from the genome of vesicular stomatitis virus and two of its defective interfering particles

RNA genomes from standard vesicular stomatitis virus and two defective interfering (DI) particles dI 0.33 (DI-T) and DI 0.52, were purified and digested with RNase T1. The resulting oligonucleotides were labeled at the 5' end with [32P]ATP and separated by two-dimensional electrophoresis in polyacrylamide gels. All of the major oligonucleotides containing 20 or more nucleotides were sequenced. Those oligonucleotides that were thought to be in common by their migration on polyacrylamide gels actually did have identical sequences. Those oligonucleotides thought to be unique to the DI RNAs either differed by only one nucleotide from oligonucleotides of the standard RNA or contained new sequences which were complementary to known sequences at the 5' end. These data indicate that RNAs from DI particles are not simple deletions but contain point mutations and additional complementary sequences.

RNA synthesis of vesicular stomatitis virus. X. Transcription and replication by defective interfering particles

In cells coinfected by standard vesicular stomatitis virus (VSV) and defective interfering (DI) T particles, small RNA consisting of 46 nucleotides was synthesized in molar excess over other VSV-specific RNAs. Although its rate of synthesis increased over time, small RNA accumulated linearly, suggesting that the molecule is unstable. In contrast, replication of the genome RNA of DI T particles was relatively constant after 3 h of infection, resulting in the intracellular accumulation of stable genomic and antigenomic RNA of DI T particles. Coinfection of cells with DI T particles and selected temperature-sensitive mutants from all five complementation groups of VSV indicated that the replication of DI genomes was controlled separately from the synthesis of small RNA. Also, when viral RNA replication was inhibited by cycloheximide, small RNA continued to be synthesized as long as there were enough templates present. These results indicate that small RNA is synthesized by the enzyme(s) involved in VSV transcription and that its dependence on RNA replication is due to the requirement for template amplification.

Concanavalin A agglutinability of some enveloped RNA viruses modified by host cell transformation

The dependence on concanavalin A (Con A) concentration of agglutinability of some enveloped RNA viruses grown in transformed cells was compared with that of those grown in nontransformed cells. The avian oncoviruses were purified by centrifuging to equilibrium in a combination equilibrium: viscosity gradient of potassium tartrate and glycerol after conventional isopycnic sucrose density gradient centrifugation. Avian oncoviruses were more agglutinable with Con A when grown in transformed cells than when grown in nontransformed cells. Vesicular stomatitis virus grown in transformed cells was also more agglutinable than the virus grown in nontransformed cells. These results agree with the concept that the envelopes are modified by host cell transformation and that, therefore, viruses grown in transformed cells are expected to be more agglutinable with Con A than those grown in nontransformed cell.

RNA synthesis of vesicular stomatitis virus. VIII. Oligonucleotides of the structural genes and mRNA

The single-stranded RNA genome of vesicular stomatitis virus (VSV, Indiana serotype, San Juan strain) yields approx. 75 RNase T1-resistant oligonucleotides ranging in size from 10 to 50 bases. Each of the five structural genes, isolated as duplex RNA molecules hybridized to complementary mRNA, contains two or more of these large oligonucleotides. One of the oligonucleotides is identified as part of the non-coding region near the 3' end of the genome. Comparison of these results with others indicate that the RNA sequence of VSV is apparently stable in the laboratory but not in the wild. RNase T1-resistant oligonucleotides are also shown for all five VSV mRN species. Whether the mRNA for these digestions are are isolated from duplex RNA molecules or as single-stranded RNA species, the oligonucleotide patterns for each mRNA are virtually identical, indicating that each mRNA is transcribed from contiguous sequences on the genome. Comparison with published oligonucleotide patterns obtained from other isolates of VSV or from VSV deletion mutants indicate that identity and changes in their genome structure can be correlated with specific structural genes.

The matrix (M) protein of vesicular stomatitis virus regulates transcription

Temperature-sensitive mutants of vesicular stomatitis virus (VSV) belonging to complementation group III contain a lesion in the matrix (M) protein. This results in a 2--5 fold increase in transcription at the nonpermissive temperature. Co-infection of cells with one of these mutants and wild-type virus reverses this mutant phenotype. Separation of the transcriptional and translational products from mutant-infected cells reveals an overall increase in each of the viral mRNA species concomitant with degradation of the M protein at the nonpermissive temperature. The increase in mRNA, however, does not lead to increased synthesis of viral proteins. Quantitation of individual mRNA species indicates that M protein acts as a direct inhibitor of transcription as well as an attenuator of sequential transcription.

Defective Friend spleen focus-forming virus: interfering properties and isolation free from standard leukemia-inducing helper virus

Defective Friend spleen focus-forming virus (SFFV) is able to interfere with the ability of its naturally occurring leukemia-inducing helper virus (LLV-F) to induce XC plaque formation in several different strains of mouse embryo cells. This interference has been observed by using two different SFFV preparations, one contained in an NB-tropic stock of Friend virus (FV) complex, and the second present in a C57BL-adapted strain of FV complex containing an associated B-tropic LLV-F helper. The LLV-F in NB-tropic FV complex effectively induced XC plaques in C57BL/6 (Fv-1(bb); Fv-2(rr)) mouse embryo fibroblasts (MEF) only in the absence of coinfecting SFFV, indicating that Fv-2-associated resistance to SFFV-induced focus formation in vivo does not necessarily extend to the restriction of SFFV function(s) in vitro (i.e., in Fv-2(rr) C57BL MEF). SFFV interference appears to be an intracellular event since LLV-F can adsorb onto, penetrate, and rescue defective murine sarcoma virus (MSV) from transformed 3T3FL S(+)L(-) cells with equal efficiency in the presence and absence of SFFV. However, significantly fewer LLV-infected S(+)L(-) cells released LLV-F progeny if SFFV was present. These observations suggest that Friend SFFV may be classified as a defective, interfering (DI) particle. Further support for this conclusion has come from studies designed to investigate two physical properties of defective SFFV particles. SFFV layered onto a 0 to 20% sucrose sedimentation gradient was recovered as a symmetrical band of virus that sedimented more slowly than standard LLV-F particles. Pooled SFFV-containing gradient samples contained visualizable type C virus particles and occasionally small amounts of detectable LLV-F. In an attempt to determine the buoyant density of sedimentation gradient-purified SFFV, pooled SFFV samples were layered onto a 25 to 50% sucrose equilibrium density gradient and were centrifuged to equilibrium. Greater than 50% of the infectious SFFV originally layered onto this gradient was recovered and seen as a narrow symmetrical band with peak SFFV infectivity at a sucrose density of 1.14 g/ml. The observed difference between SFFV and LLV-F buoyant densities appears to be related to an inherent physical property of each virus. Mixtures of these two viruses express the buoyant density of that virus population which is in excess in fabricated FV complexes probably due to the formation of SFFV-LLV aggregates. Finally, gradient-purified SFFV failed to induce XC plaques in MEF and did not function to rescue MSV as expected since SFFV itself is replication defective.

The structure of vesicular stomatitis virus membrane. A phosphorus nuclear magnetic resonance approach

The proton decoupled 40.48 M Hz 31P NMR spectrum of intact and unperturbed membrane-enclosed vesicular stomatitis virus (sterotype Indiana) exhibited two distinct maxima. These can be resolved into a narrow, symmetric line and a broad asymmetric line. The 31P NMR spectrum of a multilamellar (unsonicated) preparation of the extracted viral lipids exhibited a line shape similar to that of the intact virus. A sonicated vesicle preparation of the extracted viral lipids exhibited a narrow symmetric line. The narrow component in the intact virus spectrum may be attributed to small membrane fragments. Phospholipase C digestion of the intact virus resulted in substantial reduction in intensity of both components which suggests that much of the contribution to both peaks is due to phosphate in the phospholipid polar head groups. The phospholipid phosphates in both sonicated and unsonicated preparations of the extracted viral lipids exhibited substantially longer relaxation times than did those in the intact virus. The short relaxation time emanating from the intact virus preparation is caused by immobilization of the phospholipid head groups which could be due to lipid-protein interactions. Trypsin treatment of vesicular stomatitis virions, which results in complete removal of the exterior hydrophilic segment of the membrane glycoprotein, increased the 31P relaxation time to a value similar to that observed in the protein-free total lipid extracts; this finding provides supporting evidence for the role of virus glycoprotein in shortened relaxation times. A reversible temperature-dependent change in apparent line width and absence of an effect of cholesterol on the 31P phospholipid spectrum were also demonstrated.