Differential Inhibition of Vesicular Stomatitis Virus Polypeptide Synthesis by Hypertonic Initiation Block

Synthesis of the vesicular stomatitis virus membrane matrix protein and the glycoprotein is inhibited to a greater extent than the synthesis of the nucleocapsid protein, the nonstructural protein, and the large protein when the rate of peptide chain initiation is reduced by exposure of vesicular stomatitis virus-infected cells to hypertonic medium. It is concluded that the relative sensitivity of individual viral polypeptide synthesis to hypertonic initiation block is independent of the site of synthesis, i.e., whether on membrane-associated or free polyribosomes.     

Inactivation of Vesicular Stomatitis Virus by Disinfectants

Twenty-four chemical disinfectants considered to be viricidal were tested. Ten disinfectants were not viricidal for vesicular stomatitis virus within 10 min at 20 C when an LD(50) titer of 10(8.5) virus units per 0.1 ml were to be inactivated. Quantitative inactivation experiments were done with acid, alkaline, and a substituted phenolic disinfectant to determine the kinetics of the virus inactivation. Substituted phenolic disinfectants, halogens, and cresylic and hydrochloric acids were viricidal. Basic compounds such as lye and sodium metasilicate were not viricidal.     

Proteins of Vesicular Stomatitis Virus and of Phenotypically Mixed Vesicular Stomatitis Virus-Simian Virus 5 Virions

The identity of the glycoprotein of vesicular stomatitis virus (VSV) as the spike protein has been confirmed by the removal of the spikes with a protease from Streptomyces griseus, leaving bullet-shaped particles bounded by a smooth membrane. This treatment removes the glycoprotein but does not affect the other virion proteins, apparently because they are protected from the enzyme by the lipids in the viral membrane. The proteins of phenotypically mixed, bullet-shaped virions produced by cells mixedly infected with VSV and the parainfluenza virus simian virus 5 (SV5) have been analyzed by polyacrylamide gel electrophoresis. These virions contain all the VSV proteins plus the two SV5 spike proteins, both of which are glycoproteins. The finding of the SV5 spike glycoproteins on virions with the typical morphology of VSV indicates that there is not a stringent requirement that only the VSV glycoprotein can be used to form the bullet-shaped virion. On the other hand, the SV5 nucleocapsid protein and the major non-spike protein of the SV5 envelope were not detected in the phenotypically mixed virions, and this suggests that a specific interaction between the VSV nucleocapsid and regions of the cell membrane which contain the nonglycosylated VSV envelope protein is necessary for assembly of the bullet-shaped virion.     

Model for Vesicular Stomatitis Virus

Vesicular stomatitis virus contains single-stranded ribonucleic acid of molecular weight 3.6 x 10(6) and three major proteins with molecular weights of 75 x 10(3), 57 x 10(3), and 32.5 x 10(3). The proteins have been shown to be subunits of the surface projections, ribonucleoprotein, and matrix protein, respectively. From these values and from estimates of the proportions of the individual proteins, it has been calculated that the virus has approximately 500 surface projections, 1,100 protein units on the ribonucleoprotein strand, and 1,600 matrix protein units. Possible models of the virus are proposed in which the proteins are interrelated.     

Infective Virus Substructure from Vesicular Stomatitis Virus

Treatment of suspensions of vesicular stomatitis virus with Tween-ether results in a rapid and considerable loss of infectivity (ca. 4 logs in 2 min), but the residual infectivity is comparatively stable to further treatment with ether. The infectivity remaining after the short exposure to Tween-ether is not due to virus for the following reasons. (i) It is much less infective for tissue cultures than for mice, whereas the intact virion is equally infective for both hosts. (ii) The residual infectivity is much less stable than virus infectivity in both sucrose and tartrate gradients. (iii) Virus immune serum does not neutralize its activity. (iv) The infectivity is associated with material which sediments further in sucrose gradients and has a greater buoyant density in tartrate gradients than the virion. Experiments with (32)P-labeled virion showed that the infective substructure contains ribonucleic acid with the same sedimentation characteristics as that extracted from the virion. Electron microscopy shows that the infective component has the same overall bullet-like structure as the virion but lacks the outer envelope and fringe structure.     

Carbohydrate Composition of Vesicular Stomatitis Virus

Analysis by gas-liquid chromatography of the trimethylsilylated sugar residues of purified vesicular stomatitis virus grown in L cells or chick embryo cells revealed the presence in the whole virion of four hexoses (glucose, galactose, mannose, and fucose), two hexosamines (glucosamine and galactosamine), and 34 to 40% neuraminic acid. The isolated viral glycoprotein was devoid of galactosamine and fucose, both of which sugars were present in whole virions presumably as part of the membrane glycolipids.     

Inhibition of Protein Synthesis in L Cells Infected with Vesicular Stomatitis Virus

The inhibition of protein synthesis in L cells by vesicular stomatitis virus (VSV) requires the synthesis of new protein subsequent to virus infection. However, two mechanisms may be involved in the inhibition of cell protein synthesis by VSV: an initial, multiplicity-dependent, ultraviolet-insensitive inhibition and a progressive, ultraviolet-sensitive inhibition.     

Morphogenesis of the Nucleoprotein of Vesicular Stomatitis Virus

Accumulation of the nucleoprotein of vesicular stomatitis virus (VSV) in the cytoplasm of BHK-21 cells and in two of four human cell lines was demonstrated. Appearance and progression of the nucleoprotein inclusions paralleled development of virus-specific immunofluorescence and production of virus progeny. The inclusions appeared early as discrete foci of filamentous material which eventually increased in size to form large masses which replaced normal cytoplasmic constituents. The filamentous strands were found in close proximity to budding virions. The inclusion material was extracted from infected cells and purified in cesium chloride gradients. The isolated filaments resembled the ribonucleoprotein isolated from purified virions. They incorporated (3)H-uridine, exhibited virus-specific complement-fixing activity, had a buoyant density of 1.32 g/cm(3), and appeared as single wavy strands the width of which varied from 2.5 to 8.5 nm, depending on the angle of viewing.     

Protein Kinase and Phosphoproteins of Vesicular Stomatitis Virus

Protein kinases of similar but not identical activity were found associated with vesicular stomatitis (VS) virions grown in mouse L cells, primary chicken embryo (CE) cells, and BHK-21 cells, as well as being present in VS virions grown in HeLa and Aedes albopictus cells. The virion kinase preferentially phosphorylated the nucleocapsid NS protein in vitro and to a lesser extent the envelope M protein. Other virion proteins were phosphorylated in vitro only after drastic detergent treatment. Partial evidence that the virion kinase is of cellular origin was obtained by finding reduced enzyme activity in virions released from cells pretreated with actinomycin D and cycloheximide. Selective detergent and detergent-salt fractionation of VS virions revealed that the kinase activity was present in the envelope but not the spikes. The virion kinase activity in a Triton-salt-solubilized envelope fraction could be separated from M and G proteins and partially purified by phosphocellulose column chromatography. Virions released from L, CE, and BHK-21 cells infected in the presence of [(32)P]orthophosphate were labeled almost exclusively in the NS protein. Both soluble and nucleocapsid-associated NS phosphoprotein were present in cytoplasmic extracts of VS viral-infected L cells. The origin and function of the NS phosphoprotein remain to be elucidated.     

Interferon Production and Inhibition of Host Synthesis in Cells Infected with Vesicular Stomatitis Virus

Infection of L cells with wild-type (L(1)) vesicular stomatitis virus at high or low multiplicities does not result in the production of interferon; however, infection of L cells with low multiplicities of a small-plaque mutant (S(2)) results in the synthesis of large amounts of interferon. In chick embryo (CE) cells, both viruses induce synthesis of interferon; there is no significant multiplicity effect in CE cells. The rate and efficiency of shutoff of macromolecular synthesis in the different host cells is a critical factor in determining the ability of the viruses to induce interferon synthesis. If host ribonucleic acid or protein synthesis is shut off by the virus before the required new ribonucleic acid is transcribed or translated, interferon production does not occur. The relative yield of the two viruses in CE and L cells is not related to the effects of interferon produced during the course of infection.     

Comparison of Vesicular Stomatitis Virus Intracellular and Virion Ribonucleoproteins

Vesicular stomatitis virus ribonucleoproteins (RNP) obtained by a detergent treatment of purified virus (vRNP) or from infected HeLa cell cytoplasm (icRNP) were examined by sedimentation in sucrose or Renografin gradients in the presence or absence of EDTA. It was shown that vRNP and icRNP sediment at the same rate in sucrose and Renografin in the absence of EDTA; however, icRNP sedimented more slowly in the presence of EDTA than did vRNP. Polyacrylamide gel electrophoresis of the proteins of vRNA and icRNP recovered from EDTA-containing gradients demonstrated that both RNP structures contained L, N, and NS proteins in the same proportion. Electron microscopy of both RNP structures, in the absence of EDTA, demonstrated that both exist as helical structures ~20 by 700 nm. However, in the presence of EDTA the icRNP was completely uncoiled with a mean length of 4,095 nm, whereas vRNP was hardly affected. The addition of excess Mg²⁺ or Mn²⁺ to uncoiled icRNP preparations partially restored the coiled configuration. These observations suggest that the change in sedimentation of icRNP in the presence of EDTA is due to a change from a coiled to an uncoiled conformation, that icRNP and vRNP are not structurally identical, and that icRNP must undergo a conformational change during maturation of VSV from the 20-by-700-nm intracellular form to the 50-by-175-nm form found in intact virus. The icRNP containing L, N, and NS proteins (icRNP^L,N,NS) and icRNP containing only N protein (icRNP^N), prepared by centrifugation of icRNP^L,N,NS in CsCl to remove L and NS, were compared by cosedimentation in sucrose gradients. There was a decrease in sedimentation rate of icRNP^N due to loss of L and NS. This sedimentation difference was also apparent in the presence of EDTA; however, both icRNP^L,N,NS and icRNP^N sedimented at a much slower rate in the presence of EDTA, and by electron microscopy both were completely uncoiled. These observations suggest that N protein alone is responsible for the 20-by-700-nm coiled structure and that the divalent cation interactions disrupted by EDTA are N-N or N-RNA interactions. These results are discussed with regard to vesicular stomatitis virus maturation.     

Entry of Vesicular Stomatitis Virus into L Cells

Early stages of the entry of vesicular stomatitis (VS) virus into L cells were followed by electron microscopy with the aid of ferritin antibody labeling. Cells which were infected at 0 C and incubated for 10 min at 37 C were reacted first with antiviral-antiferritin hybrid antibody and then with ferritin or fluorescein-labeled apoferritin. Extensive ferritin labeling of the cell surface was detected by both electron and fluorescence microscopy. The labeled regions of the cell surface were continuous with and indistinguishable from the rest of the host cell membrane, suggesting incorporation of viral antigens into the cell surface during viral penetration. Fusion of parental viral membrane with host cell membrane was further demonstrated by examining the localization of (3)H-labeled viral structural proteins in cells infected at 0 C and incubated for short periods at 37 C. Viral nucleoprotein was found in a soluble fraction of the cells which was derived primarily from the cytoplasm, whereas a particulate fraction from the cells was enriched in viral envelope proteins. Cytoplasmic membrane was isolated from these cells, and this membrane contained viral envelope proteins. These results suggest that penetration by VS virus occurs by fusion of the viral and cellular membranes followed by release of nucleo-protein into the cytoplasm.     

Virus Replication in Enucleate Cells: Vesicular Stomatitis Virus and Influenza Virus

The requirement of the presence of a nucleus for the replication of vesicular stomatitis virus and influenza virus has been examined by following the growth and development of these viruses in enucleate BS-C-1 cells. Vesicular stomatitis virus replicates normally in enucleate cells with the rate of production of infectious virus, the amount of virus-specific protein synthesis, and the type of proteins produced being essentially the same in nucleate and enucleate cells. Influenza virus does not replicate in enucleate cells, no virus gene products can be detected, and there is no inhibition of cellular protein synthesis.