RNA synthesis in temperature-sensitive mutants of vesicular stomatitis virus

Leader RNA binding ability of Chandipura virus P protein is regulated by its phosphorylation status: a possible role in genome transcription-replication switch

The molecular events associated with the transcriptive and replicative cycle of negative-stranded RNA viruses are still an enigma. We took Chandipura virus, a member of the Rhabdoviridae family, as our model system to demonstrate that Phosphoprotein P, besides Nucleocapsid protein N, also acts as a leader RNA-binding protein in its unphosphorylated form, whereas CKII-mediated phosphorylation totally abrogates its RNA-binding ability. However, interaction between P protein and leader RNA can be distinguished from N-mediated encapsidation of viral sequences. Furthermore, P protein bound to leader chain can successively recruit N protein on RNA while itself being replaced. We also observed that the accumulation of phosphorylation null mutant of P protein in cells results in enhanced genome RNA replication with concurrent increase in the viral yield. All these results led us to propose a model explaining viral transcription-replication switch where Phosphoprotein P acts as a modulator of genome transcription and replication by its ability to bind to the nascent leader RNA in its unphosphorylated form, promoting read-through of the transcription termination signals and initiating nucleocapsid assembly on the nascent RNA chain.

Phosphorylation within the amino-terminal acidic domain I of the phosphoprotein of vesicular stomatitis virus is required for transcription but not for replication

Phosphorylation by casein kinase II at three specific residues (S-60, T-62, and S-64) within the acidic domain I of the P protein of Indiana serotype vesicular stomatitis virus has been shown to be critical for in vitro transcription activity of the viral RNA polymerase (P-L) complex. To examine the role of phosphorylation of P protein in transcription as well as replication in vivo, we used a panel of mutant P proteins in which the phosphate acceptor sites in domain I were substituted with alanines or other amino acids. Analyses of the alanine-substituted mutant P proteins for the ability to support defective interfering RNA replication in vivo suggest that phosphorylation of these residues does not play a significant role in the replicative function of the P protein since these mutant P proteins supported replication at levels > or = 70% of the wild-type P-protein level. However, the transcription function of most of the mutant proteins in vivo was severely impaired (2 to 10% of the wild-type P-protein level). The level of transcription supported by the mutant P protein (P(60/62/64)) in which all phosphate acceptor sites have been mutated to alanines was at best 2 to 3% of that of the wild-type P protein. Increasing the amount of P(60/62/64) expression in transfected cells did not rescue significant levels of transcription. Substitution with other amino acids at these sites had various effects on replication and transcription. While substitution with threonine residues (P(TTT)) had no apparent effect on transcription (113% of the wild-type level) or replication (81% of the wild-type level), substitution with phenylalanine (P(FFF)) rendered the protein much less active in transcription (< 5%). Substitution with arginine residues led to significantly reduced activity in replication (6%), whereas glutamic acid substituted P protein (P(EEE)) supported replication (42%) and transcription (86%) well. In addition, the mutant P proteins that were defective in replication (P(RRR)) or transcription (P(60/62/64)) did not behave as transdominant repressors of replication or transcription when coexpressed with wild-type P protein. From these results, we conclude that phosphorylation of domain I residues plays a major role in in vivo transcription activity of the P protein, whereas in vivo replicative function of the protein does not require phosphorylation. These findings support the contention that different phosphorylated states of the P protein regulate the transcriptase and replicase functions of the polymerase protein, L.

Inhibition of vesicular stomatitis virus RNA synthesis by protein hyperphosphorylation

Vesicular stomatitis virus (VSV) RNA synthesis requires the template nucleocapsid, the polymerase (L) protein, and the cofactor phosphorylated (P/NS) protein. To determine whether the degree of phosphorylation regulated VSV RNA synthesis, infected Chinese hamster ovary cells were treated with okadaic acid (OKA), a serine/threonine phosphatase inhibitor. OKA reduced viral penetration and uncoating but had little or no effect on primary transcription or viral protein synthesis. However, approximately 80% of total viral RNA synthesis was inhibited when 2 microM or more OKA was added to infected cells after viral uncoating had taken place. Analysis of proteins and RNA species in infected cells labeled with 32P showed that OKA led to hyperphosphorylation of two viral phosphoproteins, the P/NS protein and matrix protein (M), resulting in inhibition of full-length RNA synthesis and subsequent secondary transcription. Pulse-chase experiments demonstrated that the hyperphosphorylated P/NS species was converted rapidly from the less phosphorylated form. Hyperphosphorylated P/NS as well as the less phosphorylated form, but not M, were found to be associated with nucleocapsids isolated from cytoplasmic extracts. These results suggest that phosphorylation played an important role in the regulation between viral transcription and viral RNA replication as well as the turning off of RNA replication. Thus, phosphatase inhibitors promise to be a valuable tool for dissecting the regulatory mechanisms involving phosphorylated viral proteins.

Temperature-sensitivity of the replication of rabies virus (HEP-flury strain) in BHK-21 cells. I. Alteration of viral RNA synthesis at the elevated temperature

We investigated the nature of temperature sensitivity of the HEP strain of rabies virus. After initial incubation for appropriate period (more than 12 hr) at the permissive temperature (36-37 degrees), incubation temperature of the rabies virus infected cultures was shifted to a nonpermissive temperature (39.5-40.5 degrees). Upon the upshift, virion production was ceased, but the rate of viral RNA synthesis was greatly increased and reached almost 10 times that of 36 degrees-infection within 8-10 hr, and then the activity quickly decreased together with the onset of accelerated CPE. Little or no 42S genome-sized RNA was produced at the elevated temperature, and almost all RNAs produced in large amounts seemed to be viral mRNAs and were shown to be functional in t he cell-free translation system. Consistent with these observations, the viral ribonucleoprotein complex isolated from the temperature-upshifted culture was associated with relatively large amounts of small sized RNAs, which might reflect their increased transcriptive activity. These observations suggest that the viral RNA polymerase itself is not temperature-sensitive and the temperature-induced defect may reside in the regulatory factor which plays a role in turning on the synthesis of viral genome-sized RNA.

L929 cells infected with temperature sensitive mutants of vesicular stomatitis virus: virus replication is necessary for induction of changes in membrane permeability

Infection of L929 murine cells with vesicular stomatitis virus (VSV) results in inhibition of host protein synthesis and appearance of membrane alterations at a time when cells are still actively engaged in viral protein synthesis. VSV temperature-sensitive (ts) mutants have been used to explore the role(s) played by the virus-coded proteins in the genesis of these effects. Cells were infected with each of five ts mutants representing the known complementation groups of VSV Indiana serotype, and incubated at permissive (32 degrees C) and non-permissive temperatures (39 degrees C). Protein synthesis in the presence and absence of Hygromycin B (Hyg. B) was analyzed during virus infection via incorporation of 35S-methionine in acid-precipitable material and SDS-polyacrylamide gel electrophoresis. Data indicate that mutants belonging to groups I (L protein), II (NS protein) and IV (N protein) do not inhibit host protein synthesis and do not induce any membrane changes when grown at the non-permissive temperature. Mutants of group III (M protein) and V (G protein), instead, do inhibit cell protein synthesis and induce membrane changes also when grown at the non-permissive temperature; this suggests that these effects do not correlate with the biological activity of these proteins and their interaction with the cellular membrane. On the other hand, mutants exhibiting defective steps of nucleocapsid replication are apparently unable to induce these effects once more suggesting that virus replication per se is essential, as also indirectly shown by experiments employing cycloheximide to mimic shut-off.

Inhibition of vesicular stomatitis viral mRNA synthesis by interferons

Interferon (IFN) treatment inhibited the replication of vesicular stomatitis virus (VSV) in human GM2767 and mouse JLSV-11 cells. The replication of this virus in either human RD-114 or mouse A402 cells was insensitive to IFN treatment. We analyzed various steps in the VSV life cycle as they occurred under different conditions of IFN treatment to identify the point(s) at which IFN was exerting its inhibitory effect. IFN treatment led to strong inhibition of viral protein synthesis and accumulation of viral RNA in both lines of IFN-sensitive cells. No such effect was observed in the IFN-resistant cells. Using a temperature-sensitive mutant (tsG41) and wild-type VSV that were not undergoing protein synthesis, we determined that the major site of action of IFN against VSV replication in JLSV-11 and GM2767 cells was at the level of primary viral transcription. The accumulation of primary viral transcripts was strongly inhibited in these cells by IFN treatment. This effect was not a consequence of any effect of IFN on virus entry and uncoating. Thus, it appears that IFN exerts a direct effect on the VSV transcriptional process in GM2767 and JLSV-11 cells.

Assignment of the temperature-sensitive lesion in the replication mutant A1 of vesicular stomatitis virus to the N gene

The replication defect in the temperature-sensitive mutant A1 of the New Jersey serotype (Hazelhurst subtype) of vesicular stomatitis virus was confirmed by the absence of intracellular nucleocapsids in infected cells incubated at the restrictive temperature. After preamplification, the relative yield of the A1 N protein accumulated intracellularly after 1 h of incubation at the restrictive temperature was decreased by 50% that of the wild-type or revertant A1 N protein. This difference was not as apparent in pulse-chase experiments. The functional lesion in A1 was correlated with a structural alteration in the N protein on the basis of the thermolability of the template activity of the A1 N protein-RNA complex in in vitro transcription reactions and the covariance of this phenotype with the temperature-sensitive phenotype in a spontaneous A1 revertant. This correlation was consistent with a direct role of the N protein in replication and allowed the assignment of the N gene to complementation group A.

Mechanism of interferon action. Inhibition of vesicular stomatitis virus in human amnion U cells by cloned human leukocyte interferon

The effects of a subsaturating, long treatment (24 h) dose of a highly purified cloned subspecies of human leukocyte interferon (IFN-alpha A) on vesicular stomatitis virus (VSV) primary macromolecular synthesis in tsG41-infected human amnion U cells were examined. IFN-alpha A, under these conditions, was found to inhibit primary VSV protein synthesis ten-fold while producing no detectable effect on the amount or integrity of primary viral message transcripts. There was no selective reduction by IFN-alpha A of the VSV G or M proteins.

Structural and functional characterization of the RNA-positive complementation groups, C and D, of the New Jersey serotype of vesicular stomatitis virus: assignment of the M gene to the C complementation group

The structural and functional lesions in the RNA-positive complementation groups, C and D, of the New Jersey serotype (Hazelhurst subtype) of vesicular stomatitis virus have been characterized. The M protein of the temperature-sensitive mutant C1, the prototype of the C complementation group, was degraded at the restrictive temperature in vivo, and was resolved from the wild-type M protein by SDS-polyacrylamide gel electrophoresis and nonequilibrium pH gradient electrophoresis. Coreversion of these properties and the temperature-sensitive phenotype was observed in a spontaneous revertant. On the basis of these results, the M gene was assigned to the C complementation group. Intracellular nucleocapsids could not be isolated from New Jersey serotype infections by procedures developed for Indiana serotype infections. Therefore, in order to assess the ability of New Jersey ts mutants to accumulate nucleocapsids at the restrictive temperature, a procedure for their isolation was developed. Hypertranscription was observed in C1-infected cells incubated at the restrictive temperature, but was not accompanied by proportionate increases in intracellular viral nucleocapsids or protein synthesis. The G and N proteins of the temperature-sensitive mutant D1, the sole representative of the D complementation group, were electrophoretic variants. The relative yield of intracellular D1 N protein was lower at the restrictive than at the permissive temperature, and the D1 L protein was thermolabile. No intracellular viral nucleocapsids were detected in D1 infected cells incubated at the restrictive temperature; however, more 40 S and less message-sized RNA were synthesized at the restrictive than at the permissive temperature. These results suggested functional defects in both the N protein and polymerase of D1.

Effect of intracellular vesicular stomatitis virus mRNA concentration on the inhibition of host cell protein synthesis

Inhibition of host cellular protein synthesis by vesicular stomatitis virus (VSV) has been suggested to be primarily the result of competition for ribosomes between cellular and viral mRNAs (H. F. Lodish and M. Porter, J. Virol., 36:719-733, 1980; Lodish and Porter, J. Virol. 38:504-517, 1981). This hypothesis was investigated by regulating the extent of VSV mRNA synthesis through the use of defective interfering particles. Although intracellular VSV mRNA concentrations decreased by as much as a factor of 14 at high multiplicities of infection of defective interfering particles, the inhibition of host cell protein synthesis by VSV decreased by a maximum of only 10%. The data also indicated that under these conditions the protein-synthesizing capacity of the cells was not exhausted. We concluded that competition for cellular ribosomes could not have been the major factor in the inhibition of host cell protein synthesis by VSV. This conclusion was further supported by inhibition data obtained with VSV mutants. The ts G22 mutant, defective in replication but not in primary transcription, inhibited host protein synthesis at the nonpermissive temperature (39 degrees C) to the same extent as did wild-type virus, even though it generated only 30 to 50% of the amount of viral mRNA as did wild-type virus. Conversely, in infections with the R1 mutant, which did not inhibit host cell protein synthesis, the amount of total and polysome-bound viral mRNA was indistinguishable from that obtained in infections by wild-type virus.

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.

Passage of an integral membrane protein, the vesicular stomatitis virus glycoprotein, through the Golgi apparatus en route to the plasma membrane

The intracellular pathway of biogenesis of the vesicular stomatitis virus transmembrane glycoprotein was investigated in situ by using indirect immunofluorescence of whole infected Chinese hamster ovary cells and immunoelectron microscopy of ultrathin frozen sections of infected cells. Transport of the glycoprotein was synchronized by using the temperature-sensitive virus mutant Orsay-45 and a temperature shift-down protocol. Sequential appearance of the glycoprotein in the rough endoplasmic reticulum, Golgi apparatus, and plasmalemma was demonstrated. The potential of this system for further studies is discussed.

Characterization of vesicular stomatitis virus mutants by partial proteolysis

Structural proteins of temperature-sensitive (ts) mutants of vesicular stomatitis virus, Indiana serotype, were compared with those of wild-type and revertant virions by electrophoresis on polyacrylamide gels of partial digests with Staphylococcus aureus V8 protease. Mutants of complementation groups III (tsG31 and tsG33), II (tsG22), and IV (tsG41) differed from the wild-type virion in peptide profiles of their M, NS, and N proteins, respectively. The differences were only detectable over a narrow range of enzyme-substrate ratios and were due to peptides transiently generated during incomplete digestion. Proteins of revertants to tsG31, tsG22, and tsG41 exhibited the wild-type virion peptide pattern, indicating that reversion had restored their original conformation. However, in the case of tsG22, the NS peptide profile reverted to the wild-type phenotype only partially, suggesting that a silent mutation might have taken place during either the original chemical mutagenesis or the following repeated laboratory passages. The apparent alteration in protein conformation and its restoration upon reversion of the mutants indicated that the lesions of groups III and IV were located in the M and N proteins, respectively. Moreover, for the first time, the site of mutation of group II could be positively identified as the NS protein cistron.

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.

UV inactivation of the biological activity of defective interfering particles generated by vesicular stomatitis virus

UV inactivation of vesicular stomatitis virus and its defective interfering (DI) particles was measured in order to obtain the target size for interference. In the case of DI particles whose genomes mapped at the 5' end of the virion RNA, this target size corresponded to the entire DI particle RNA molecule regardless of whether it amounted to 10, 30, or 50% of the viral genome. These data were interpreted as demonstrating that both termini of the DI particle RNAs were required for their replication and for interference with virion RNA replication. The unique heat-resistant DI particle, with an RNA molecule corresponding to the 3' half of the viral genome, exhibited an inactivation target size of approximately 42% of its RNA molecule with respect to both homotypic and heterotypic interference. Unlike other DI particles, this particle interfered with virion primary transcription. The unusual inactivation target size of the heat-resistant DI particle was interpreted as being a compromise between the requirements for replication of its genome and those for interference with virion primary transcription.

Selective isolation of mutants of vesicular stomatitis virus defective in production of the viral glycoprotein

We describe a procedure that enriches for temperature-sensitive (ts) mutants of vesicular stomatitis virus (VSV), Indiana serotype, which are conditionally defective in the biosynthesis of the viral glycoprotein. The selection procedure depends on the rescue of pseudotypes of known ts VSV mutants in complementation group V (corresponding to the viral G protein) by growth at 39.5 degrees C in cells preinfected with the avian retrovirus Rous-associated virus 1 (RAV-1). Seventeen nonleaky ts mutants were isolated from mutagenized stocks of VSV. Eight induced no synthesis of VSV proteins at the nonpermissive temperature and hence were not studied further. Four mutants belonged to complementation group V and resembled other ts (V) mutations in their thermolability, production at 39.5 degrees C of noninfectious particles specifically deficient in VSV G protein, synthesis at 39.5 degrees C of normal levels of viral RNA and protein, and ability to be rescued at 39.5 degrees C by preinfection of cells by avian retroviruses. Five new ts mutants were, unexpectedly, in complementation group IV, the putative structural gene for the viral nucleocapsid (N) protein. At 39.5 degrees C these mutants also induced formation of noninfectious particles relatively deficient in G protein, and production of infectious virus at 39.5 degrees C was also enhanced by preinfection with RAV-1, although not to the same extent as in the case of the group V mutants. We believe that the primary effect of the ts mutation is a reduced synthesis of the nucleocapsid and thus an inhibition of synthesis of all viral proteins; apparently, the accumulation of G protein at the surface is not sufficient to envelope all the viral nucleocapsids, or the mutation in the nucleocapsid prevents proper assembly of G into virions. The selection procedure, based on pseudotype formation with glycoproteins encoded by an unrelated virus, has potential use for the isolation of new glycoprotein mutants of diverse groups of enveloped viruses.

Transcription of vesicular stomatitis virus is required to shut off cellular RNA synthesis

RNA synthesis by mouse myeloma (MPC-11) cells was rapidly and progressively shut off by infection with vesicular stomatitis virus temperature-sensitive (ts) mutants permissive for transcription. In sharp contrast, mutants or defective vesicular stomatitis virions restricted in transcription were incapable of causing progressive inhibition of cellular RNA synthesis even at massive multiplicities of infection. A viral product synthesized 30 to 60 min after permissive infection with tsG114(I) appeared to be essential for prolonged inhibition of RNA synthesis in cells switched up to restrictive temperature.

Envelope proteins and replication of vesicular stomatitis virus: in vivo effects of RNA+ temperature-sensitive mutations on viral RNA synthesis

Temperature-sensitive (ts) mutants of vesicular stomatitis virus belonging to complementation groups III and V were investigated for their in vivo RNA synthesis. The sucrose gradient patterns of the RNA species which they produced at nonpermissive temperature (39.2 degrees C) were systematically compared under different experimental conditions: variation of input multiplicity and of time of infection, superinfection with T particles, and temperature shifts. Finally, a more precise analysis of the various RNA species synthesized was carried out. It appeared that the characteristics of RNA synthesis specified at 39.2 degrees C by tsIII or tsV mutants differed from the normal RNA synthesis of vesicular stomatitis virus wild type. Their common depression at 39.2 degrees C in virion-like RNA (38S) production--i.e., so-called genome replication--was tentatively paralleled with the concomitant ts events which have been previously shown to affect the two viral envelope proteins. An overproduction of the RNA transcripts was described for mutants in group III and posed the question of a regulation process to determine the amount of RNA to be transcribed.

Role of the membrane (M) protein in endogenous inhibition of in vitro transcription by vesicular stomatitis virus

An endogenous transcriptase inhibitor active at high concentrations of vesicular stomatitis (VS) virus was present in trypsinized whole virions but was absent from ribonucleoprotein cores containing only the L, N, and NS proteins. Poly(L-glutamic acid) effectively reversed the transcriptase inhibition. Transcription under noninhibited, inhibited, and poly(L-glutamic acid)-reversed conditions did not appear to greatly affect the nature of the RNA transcription product. The VS virion matrix (M) protein was purified to greater than 98% homogeneity and was found to have an isoelectric point of approximately 9.0. Purified M protein inhibited transcription by ribonucleoprotein cores, an effect that was partially reversed by poly(L-glutamic acid). Two group III temperature-sensitive (ts) mutants of VS virus (tsO23 and ts G31) with lesions in the M protein exhibited little or no endogenous inhibitor activity compared with two wild-type strains and a group V mutant (tsO45) with a lesion in the G protein. The data presented strongly suggest that the virion M protein is responsible for the endogenous inhibition of in vitro RNA synthesis seen at high concentrations of VS virus.

Shedding of the glycoprotein from vesicular stomatitis virus-infected cells

In a culture of Chinese hamster ovary cells infected with vesicular stomatitis virus, there is specific shedding of viral antigens into the medium. This shedding appears to be unrelated to progeny formation or to cell lysis. Although all five of the virus-specific proteins are detected in the extracellular soluble fraction, the major antigen is the Gs protein. This protein has a molecular weight of 54,000. Indirect analysis of the content of sialic acid as well as peptide analysis of the Gs and G proteins of vesicular stomatitis virus suggest that the Gs protein is derived from the G protein by proteolysis. Both proteins are hydrophobic when analyzed by charge-shift electrophoresis. The presence of phenylmethylsulfonyl fluoride in the culture medium or the removal of serum from the culture medium partially reduces the shedding of Gs protein. Increased shedding of the Gs protein is seen when there is an unstable M or matrix protein synthesized by a temperature-sensitive mutant, tsG31. These results indicate that the G protein is cleaved at the cell surface, thus releasing Gs protein into the medium. Furthermore, the stability of G protein at the cell surface appears to be dependent on its association with the M protein.

Temperature-sensitive defect of vesicular stomatitis virus in complementation group II

The prototype member of the complementation group II temperature-sensitive (ts) mutants of vesicular stomatitis virus, ts II 052, has been investigated. In ts II 052-infected HeLa cells at the restrictive temperature (39.5 degrees C), reduced viral RNA synthesis was observed by comparison with infections conducted at the permissive temperature (30 degrees C). It was found that for an infection conducted at 39.5 degrees C, no 38S RNA or intracytoplasmic nucleocapsids were present. For nucleocapsids isolated from ts II 052 purified virions or from ts II 052-infected cells at 30 degrees C, the RNA was sensitive to pancreatic RNase after an exposure at 39.5 degrees C in contrast to the resistance observed for wild-type virus. The nucleocapsid stability of wild-type virus when heated to 63 degrees C or submitted to varying pH was not found in nucleocapsids extracted from ts II 052 purified virions. The data suggest that for ts II 052 there is an altered relationship between the viral 38S RNA and the nucleocapsid protein(s) by comparison with wild-type virus. Such results argue for the complementation group II gene product being N protein, so that the ts defect in ts II 052 represents an altered N protein.

Maturation of viral proteins in cells infected with temperature-sensitive mutants of vesicular stomatitis virus

Maturation of viral proteins in cells infected with mutants of vesicular stomatitis virus was studied by surface iodination and cell fractionation. The movement of G, M, and N proteins to the virion bud appeared to be interdependent. Mutations thought to be in G protein prevented its migration to the cell surface, allowed neither M nor N protein to become membrane bound, and blocked formation of viral particles. Mutant G protein appeared not to leave the endoplasmic reticulum at the nonpermissive temperature, but this defect was partially reversible. In cells infected with mutants that caused N protein to be degraded rapidly or prevented its assembly into nucleocapsids, M protein did not bind to membranes and G protein matured to the cell surface, but never entered structures with the density of virions. Mutations causing M protein to be degraded prevented virion formation, and G protein behaved as in cells infected by mutants in N protein. These results are consistent with a model of virion formation involving coalescence of soluble nucleocapsid and soluble M protein with G protein already in the plasma membrane.

Analysis of the defects of temperature-sensitive mutants of vesicular stomatitis virus: intracellular degradation of specific viral proteins

The metabolism of viral RNA and proteins has been studied in cells infected with temperature-sensitive mutant strains of vesicular stomatitis virus. Certain viral proteins encoded by the mutant strains, usually the putative mutant protein for the assigned complementation group, were shown to be degraded more rapidly at the nonpermissive temperature than were the wild-type proteins. Group III mutants (tsG33, tsM301) encode M proteins which are degraded three- to fourfold faster than the wild-type protein. This defect cannot be fully rescued by coinfection with wild-type virus, and thus the defect appears to be in the M protein itself. Mutants tsM601 (VI) and tsG41(IV) encode N proteins which are degraded much faster than the wild-type protein and also share the property of being defective in replication of viral RNA, suggesting a correlation between these phenotypic properties. Furthermore, the L proteins of tsG11(I) and tsG13(I) are more labile than the wild-type protein at the nonpermissive temperature. The G protein of tsM501(V) did not undergo the change in electrophoretic mobility previously shown to be the result of sialylation, suggesting that it is defective in maturation or glycosylation at the nonpermissive temperature. Three of the mutants previously isolated in this laboratory, tsM502(V), tsM601(VI), and tsM602(VI), were shown to be defective in viral RNA synthesis at the nonpermissive temperature. Mutant tsM601(VI) was defective mainly in viral RNA replication, whereas tsM502(V) appeared to be totally defective for viral RNA transcription and replication at the nonpermissive temperature.

Rifampin-susceptible mutant of vesicular stomatitis virus: protein and RNA synthesis

A rifampin-susceptible strain (VSV Rif+) was selected from the wild vesicular stomatitis virus (VSV) population unsusceptible to rifampin. The VSV Rif+ was blocked in its intracellular replication in the presence of rifampin. In cells, rifampin affected primarily VSV Rif+ transcription, but to a different extent than in a cell-free system. In addition, a decrease in the amount of VSV Rif+ protein M was detected, linked to a stimulation of protein NS. In the absence of rifampin, protein M, although synthesized, was not immediately incorporated into the cell membrane. An interpretation of these observations is proposed.

Inhibition of pseudorabies virus replication by vesicular stomatitis virus. II Activity of defective interfering particles

Purified defective interfering (DI) particles of vesicular stomatitis virus (VSV) inhibit the replication of a heterologous virus, pseudorabies virus (PSR), in hamster (BHK-21) and rabbit (RC-60) cell lines. In contrast to infectious B particles of VSV, UV irradiation of DI particles does not reduce their ability to inhibit PSR replication. However, UV irradiation progressively reduces the ability of DI particles to cause homologous interference with B particle replication. Pretreatment with interferon does not affect the ability of DI particles to inhibit PSR replication in a rabbit cell line (RC-60) in which RNA, but not DNA, viruses are sensitive to the action of interferon. Under similar conditions of interferon pretreatment, the inhibition of PSR by B particles is blocked. These data suggest that de novo VSV RNA or protein synthesis is not required for the inhibition of PSR replication by DI particles. DI particles that inhibit PSR replication also inhibit host RNA and protein synthesis in BHK-21 and RC-60 cells. Based on the results described and data in the literature, it is proposed that the same component of VSV B and DI particles is responsible for most, if not all, of the inhibitory activities of VSV, except homologous interference.

Differential inhibition of host protein synthesis in L cells infected with RNA - temperature-sensitive mutants of vesicular stomatitis virus

The response of mouse L cells to infection with wild-type (wt) and temperature-sensitive (ts) mutants of vesicular stomatitis virus was monitored by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to delineate the synthesis of host cell and viral proteins. Experiments utilized transcriptase mutants of complementation group I (ts114 and ts13), a group IV mutant (ts44) that is restricted in total RNA synthesis (RNA-1) but not in primary transcription, and a group II mutant (ts52) variably restricted in RNA synthesis (RNA +/-). L cells infected with ts mutants at permissive temperature exhibited the wt response of progressive inhibition of host cell protein synthesis accompanied by accumulation of all five viral proteins. Mutant ts44 (IV) also switched off cell protein synthesis at restrictive temperature and accumulated all five viral proteins, but with disproportionate ratios of N and G proteins. At restrictive temperature, cells infected with group I ts mutants failed to accumulate any viral protein and did not exhibit significant reduction in host cell protein synthesis. These data suggest that vesicular stomatitis virus inhibits cell protein synthesis at a stage of viral infection after transcription and possibly translation but preceding replication of progeny viral RNA.

Physical properties of New Jersey serotype of vesicular stomatitis virus and its defective particles

The wild-type New Jersey serotype of vesicular stomatitis virus generated two types of defective interfering T-particles. The physical properties of these particles and the wild-type virion were determined by laser light scattering spectroscopy, sedimentation measurements, and electron microscopy.

Temperature-sensitive mutants of vesicular stomatitis virus: comparison of the in vitro RNA polymerase defects of group I and group IV mutants

When tested in vitro, certain temperature-sensitive (ts) mutants of vesicular stomatitis virus (VSV) belonging to complementation groups I and IV appear to have defects in the virion-bound polymerase. To obtain further information concerning the nature of these defects, representative mutants were dissociated by the method of S. Emerson and R. Wagner (1972), and their supernatant (S) and pellet (P) fractions were tested for transcriptase activity when combined with the P and S fractions, respectively, of VSV-HR virions. It was found that the S fractions from group I mutants tsW4, 11, 14, 15, and 28 were defective in transcriptase activity, whereas their P fractions were as active as those of VSV-HR. On the other hand, the P fraction derived from virions of the group IV mutant tsW16B showed reduced activity at 25 C and very little activity at 38 C. These results suggest that our group I mutants, like those examined by D. Hunt and R. Wagner (1974), have a defect in the soluble transcriptase enzyme, whereas mutant tsW16B (group IV) has a defect in a sedimentable component required for transcriptase activity, possibly in the ribonucleoprotein template.

Transcription and replication of vesicular stomatitis virus: effects of temperature-sensitive mutations in complementation group IV

Temperature-sensitive (ts) mutants of vesicular stomatitis virus belonging to the RNA(-) complementation group IV were investigated under various conditions to study both their RNA and protein syntheses. In infected cells maintained at 39.2 C, viral RNA species were recovered only in the 13 to 15S region of the gradient in an amount depending on the ts mutant used. In the presence of cycloheximide at 39.2 C, the primary transcription was deficient, especially for 28S mRNA production. When mutant-infected cells were shifted to nonpermissive temperature, a shutoff of 28S mRNA synthesis occurred as a general feature. On the contrary under this condition, the two mutants chosen, ts IV100 and ts IV111, behaved very differently in their 13 to 15S and 38S RNA production. However, treatment with cycloheximide at the time of the transfer to 39.2 C resulted in a similar recovery of 13 to 15S RNA in both mutants, whereas the 28S remained very depressed. The viral proteins synthesized by cells infected with the same two mutants also showed a distinct pattern, especially regarding the N protein; a correlation between 38S RNA and protein N syntheses was tentatively drawn. The whole set of data suggested that the lesion in group IV mutants concerned a viral structural protein required for the process of in vivo transcription and which probably intervened in the replication mechanism.