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

Model-based design of growth-attenuated viruses

Live-virus vaccines activate both humoral and cell-mediated immunity, require only a single boosting, and generally provide longer immune protection than killed or subunit vaccines. However, growth of live-virus vaccines must be attenuated to minimize their potential pathogenic effects, and mechanisms of attenuation by conventional serial-transfer viral adaptation are not well-understood. New methods of attenuation based on rational engineering of viral genomes may offer a potentially greater control if one can link defined genetic modifications to changes in virus growth. To begin to establish such links between genotype and growth phenotype, we developed a computer model for the intracellular growth of vesicular stomatitis virus (VSV), a well-studied, nonsegmented, negative-stranded RNA virus. Our model incorporated established regulatory mechanisms of VSV while integrating key wild-type infection steps: hijacking of host resources, transcription, translation, and replication, followed by assembly and release of progeny VSV particles. Generalization of the wild-type model to allow for genome rearrangements matched the experimentally observed attenuation ranking for recombinant VSV strains that altered the genome position of their nucleocapsid gene. Finally, our simulations captured previously reported experimental results showing how altering the positions of other VSV genes has the potential to attenuate the VSV growth while overexpressing the immunogenic VSV surface glycoprotein. Such models will facilitate the engineering of new live-virus vaccines by linking genomic manipulations to controlled changes in virus gene-expression and growth.

Different host-cell shutoff strategies related to the matrix protein lead to persistence of vesicular stomatitis virus mutants on fibroblast cells

Acute infection of fibroblastic cell lines by the Indiana strain of vesicular stomatitis virus (VSV) usually induces dramatic cytopathic effects and shutoff of cellular gene expression. We have compared a series of independent mutants with differences in shutoff induction and found that M was mutated either in the N-terminus (M(51)R) or C-terminus (V(221)F and S(226)R). Furthermore, only double mutants (M mutation and a ts mutation related or not to M) were able to persist on fibroblast cell lines at 39 degrees C. A more detailed investigation of the infection was performed for the mutants T1026, TP3 and G31, differing in their host shutoff effects related to M protein. Viral activity in persistently infected mouse L-929 and monkey Vero cell lines was followed by viral proteins detection, RNA synthesis throughout infection and finally detection of infectious particles. All three mutants cause extensive CPE followed by emergence of persistently infected cells on Vero cells. The same thing is seen on L-929 cells except for T1026 which causes little CPE. Taken together, the results form a basis of further studies to clarify how various viral and cellular factors interact in the establishment of a persistent infection by VSV mutants.

Role of M protein aggregation in defective assembly of temperature-sensitive M protein mutants of vesicular stomatitis virus

The goal of these experiments was to determine the steps in virus assembly that are defective at the nonpermissive temperature in temperature-sensitive (ts) matrix (M) protein mutants of vesicular stomatitis virus. It has been proposed that mutations in M protein either reduce the binding affinity for nucleocapsids or lead to aggregation, reducing the amount of M protein available for virus assembly. Cytosolic or membrane-derived M proteins from wild-type VSV and two ts M protein mutant viruses, tsM301 and tsO23, as well as a revertant of tsO23 virus, O23R1, were analyzed for binding to nucleocapsid-M protein (NCM) complexes and for M protein aggregation. The experiments presented here showed that ts M proteins synthesized at the nonpermissive temperature were capable of binding to nucleocapsids and that aggregation of ts M proteins did not reduce the amount of soluble M protein below the amount required for assembly of the O23R1 virus. Instead, the most pronounced defect in ts M proteins was in the ability of membrane-derived M proteins to be solubilized in the presence of the detergent Triton X-100. It is proposed that this detergent-insoluble form of M protein interferes with a step necessary to initiate assembly of NCM complexes. A similar detergent, Triton X-114, caused aggregation of membrane-derived wild-type M protein, disproving an earlier proposal that membrane-derived M protein behaves like an integral membrane protein in the presence of Triton X-114. Aggregation of wild-type M protein in the presence of Triton X-100 could be induced by incubation at 37 degrees C with a high-molecular-weight fraction isolated from uninfected cells by sucrose gradient centrifugation. These results implicate host components in inducing M protein aggregation.

Sites of in vivo phosphorylation of vesicular stomatitis virus matrix protein

We mapped the in vivo phosphorylation sites for the matrix (M) protein of the Orsay and San Juan strains of vesicular stomatitis virus, Indiana serotype, using limited proteolysis and phosphoamino acid analysis. M protein was solubilized from 32P-labeled virions by using detergent and high-salt conditions, then treated with either trypsin or Staphylococcus aureus V8 protease, and analyzed by polyacrylamide gel electrophoresis and autoradiography to determine which fragments contained phosphate residues. The M protein fragment extending from amino acid 20 to the carboxy terminus contained approximately 70% of the control 32P label, while the fragment extending from amino acid 35 to the carboxy terminus had only trace amounts of label. These data indicate that the major phosphorylation site was between amino acids 20 and 34 in the Orsay strain M protein. Phosphoamino acid analysis of M protein by thin-layer electrophoresis showed the presence of phosphothreonine and phosphoserine and that phosphothreonine continued to be released after prolonged vapor-phase acid hydrolysis. These data identify Thr-31 as the primary in vivo phosphate acceptor for M protein of the Orsay strain of vesicular stomatitis virus. The San Juan strain M protein has serine at position 32, which may also be an important phosphate acceptor. In addition, phosphorylation at Ser-2, -3, or -17 occurs to a greater extent in the San Juan strain M protein than in the Orsay strain M protein. The subcellular distribution of phosphorylated M protein was investigated to determine a probable intracellular site(s) of phosphorylation. Phosphorylated M protein was associated primarily with cellular membranes, suggesting phosphorylation by a membrane-associated kinase. Virion M protein was phosphorylated to a greater extent than membrane-bound M protein, indicating that M protein phosphorylation occurs at a late stage in virus assembly. Phosphorylation of wild-type and temperature-sensitive mutant M protein was studied in vivo at the nonpermissive temperature. The data show that phosphorylated M protein was detected only in wild-type virus-infected cells and virions, suggesting that association with nucleocapsids may be required for M protein phosphorylation or that misfolding of mutant M protein at the nonpermissive temperature prevents phosphorylation.

Antiviral activity of the prostanoid clavulone II against vesicular stomatitis virus

Prostaglandins of the A series exhibit the most pronounced antiviral activity in cells infected with RNA or DNA viruses as compared to other prostaglandins. Clavulone is a prostaglandin A analog found in the soft coral Clavularia viridis. Using vesicular stomatitis virus in mouse L929 fibroblasts as a model system, 50% inhibition of viral yield was seen at a concentration of 1-1.5 microM, whereas 50% cytotoxicity required 50-70 times higher inhibitor concentrations. For a further elucidation of the antiviral mechanism a temperature-sensitive mutant, tsG 41, was used, which is replication-negative at the restrictive temperature. Results obtained with this mutant suggest that inhibition of VSV replication occurs at the level of transcription.

Intracellular degradation of unassembled asialoglycoprotein receptor subunits: a pre-Golgi, nonlysosomal endoproteolytic cleavage

The human asialoglycoprotein receptor is a heterooligomer of the two homologous subunits H1 and H2. As occurs for other oligomeric receptors, not all of the newly made subunits are assembled in the RER into oligomers and some of each chain is degraded. We studied the degradation of the unassembled H2 subunit in fibroblasts that only express H2 (45,000 mol wt) and degrade all of it. After a 30 min lag, H2 is degraded with a half-life of 30 min. We identified a 35-kD intermediate in H2 degradation; it is the COOH-terminal, exoplasmic domain of H2. After a 90-min chase, all remaining intact H2 and the 35-kD fragment were endoglycosidase H sensitive, suggesting that the cleavage generating the 35-kD intermediate occurs without translocation to the medial Golgi compartment. Treatment of cells with leupeptin, chloroquine, or NH4Cl did not affect H2 degradation. Monensin slowed but did not block degradation. Incubation at 18-20 degrees C slowed the degradation dramatically and caused an increase in intracellular H2, suggesting that a membrane trafficking event occurs before H2 is degraded. Immunofluorescence microscopy of cells with or without an 18 degrees C preincubation showed a colocalization of H2 with the ER and not with the Golgi complex. We conclude that H2 is not degraded in lysosomes and never reaches the medial Golgi compartment in an intact form, but rather degradation is initiated in a pre-Golgi compartment, possibly part of the ER. The 35-kD fragment of H2 may define an initial proteolytic cleavage in the ER.

Temperature-sensitive mutants of Newcastle disease virus altered in HN glycoprotein size, stability, or antigenic maturity

It has been suggested that the 11 group B, C, and BC temperature-sensitive (ts) mutants of Newcastle disease virus (NDV), strain Australia-Victoria (AV-WT), have lesions in the gene for the hemagglutinin/neuraminidase glycoprotein (HN), and that complementation between groups B and C is intracistronic. Virions produced by these mutants even at permissive temperature contain greatly reduced amounts of HN, and the accompanying hemagglutinating and neuraminidase functions. To explore the basis for decreased HN incorporation into virions and the temperature sensitivity of these mutants, infected chick embryo cells were examined for changes in HN characteristics. The HN of two of the mutants was clearly altered in electrophoretic migration rates in both virions and infected cells. The migrational differences were not due to differences in glycosylation because altered migration rates were also observed in the presence of tunicamycin. In all cases, cells infected by these mutants produced as much HN as did AV-WT-infected cells, but the HN of six of these mutants was metabolically unstable. All of the mutants, including those with metabolically stable HN, exhibited greatly restricted ability to convert HN to an antigenically reactive form, indicating an early block in processing. For most of these mutants, the neuraminidase activities of infected cells were somewhat temperature sensitive, but the production of hemadsorbing activities on cell surfaces was not temperature sensitive. In contrast, the hemadsorbing and neuraminidase activities of cells infected by one mutant, BC2, were temperature sensitive, probably a reflection of the previously described extreme thermolability of the HN of this mutant. The relationship between these mutant characteristics, their temperature sensitivity and the virion phenotypes, is discussed. The data presented here confirm the assignment of these 11 group B, C, and BC mutants to defects in HN and begin to separate them into groups with different characteristics.

Expression of the M gene of vesicular stomatitis virus cloned in various vaccinia virus vectors

Initial attempts to clone the matrix (M) gene of vesicular stomatitis virus (VSV) in a vaccinia virus expression vector failed, apparently because the expressed M protein, and particularly a carboxy-terminus-distal two-thirds fragment, was lethal for the virus recombinant. Therefore, a transient eucaryotic expression system was used in which a cDNA clone of the VSV M protein mRNA was inserted into a region of plasmid pTF7 flanked by the promoter and terminator sequences for the T7 bacteriophage RNA polymerase. When CV-1 cells infected with recombinant vaccinia virus vTF1-6,2 expressing the T7 RNA polymerase were transfected with pTF7-M3, the cells produced considerable amounts of M protein reactive by Western blot (immunoblot) analysis with monoclonal antibodies directed to VSV M protein. Evidence for biological activity of the plasmid-expressed wild-type M protein was provided by marker rescue of the M gene temperature-sensitive mutant tsO23(III) at the restrictive temperature. Somewhat higher levels of M protein expression were obtained in CV-1 cells coinfected with a vaccinia virus-M gene recombinant under control of the T7 polymerase promoter along with T7 polymerase-expressing vaccinia virus vTF1-6,2.

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.

A mutated membrane protein of vesicular stomatitis virus has an abnormal distribution within the infected cell and causes defective budding

Two temperature-sensitive (ts) mutants of the M protein of vesicular stomatitis virus (tsG31 and tsG33) are defective in viral assembly, but the exact nature of this defect is not known. When infected cells are switched from nonpermissive (40 degrees C) to permissive (32 degrees C) temperatures in the presence of cycloheximide, tsG33 virus release increased by 100-fold, whereas tsG31 release increased only by 10-fold. Thus, the tsG33 defect is more reversible than that of tsG31. Therefore, we investigated how the altered synthesis and cellular distribution of tsG33 M protein correlates with the viral assembly defect. At 32 degrees C tsG33 M protein is stained diffusely in the cell cytoplasm and later at the budding sites. In contrast, at 40 degrees C the mutant M protein formed unusual aggregates mostly located in the perinuclear regions of virus-infected cells and partially colocalized with G protein in this region. In temperature shift-down experiments, M can be disaggregated and used to some extent for nucleocapsid coiling and budding, which correlates with the virus titer increase. M aggregates also formed after shift-up from 32 to 40 degrees C, indicating a complete dependence of M aggregation on the temperature. Biochemical analysis with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting revealed that at 40 degrees C M protein is detected exclusively in pellet fractions (nuclear and cytoskeleton components), whereas at 32 degrees C M protein is mainly in the cytoplasmic soluble fractions. Furthermore, when the temperature is raised from 32 to 40 degrees C, the distribution of M protein tends to shift from the soluble to the pellet and cytoskeletal fractions. Electron micrographs of immunoperoxidase-labeled M protein showed that at 40 degrees C M aggregates are often associated with the outer nuclear membranes as well as with vesicular structures. No nucleocapsid coiling was observed in these cells, whereas coiling and budding were seen at 32 degrees C in cells where M protein was partly associated with the plasma membrane. We suggest that the tsG33 M protein mutation may produce a reversible conformational alteration which causes M protein to aggregate at 40 degrees C, therefore inhibiting the proper association of M protein with nucleocapsids and budding membranes.

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.

Reconstitution of transport of vesicular stomatitis virus G protein from the endoplasmic reticulum to the Golgi complex using a cell-free system

Transport of the vesicular stomatitis virus-encoded glycoprotein (G protein) between the endoplasmic reticulum (ER) and the cis Golgi compartment has been reconstituted in a cell-free system. Transfer is measured by the processing of the high mannose (man GlcNAc2) ER form of G protein to the man5GlcNAc5 form by the cis Golgi enzyme alpha-mannosidase I. G protein is rapidly and efficiently transported to the Golgi complex by a process resembling that observed in vivo. G protein is trimmed from the high mannose form to the man5GlcNAc2 form without the appearance of the intermediate man GlcNAc2 oligosaccharide species, as is observed in vivo. G protein is found in a sealed membrane-bound compartment before and after incubation. Processing in vitro is sensitive to detergent, and the Golgi alpha-mannosidase I inhibitor 1-deoxymannorjirimycin. Transport between the ER and Golgi complex in vitro requires the addition of a high speed supernatant (cytosol) of cell homogenates, and requires energy in the form of ATP. Efficient reconstitution of export of protein from the ER requires the preparation of homogenates from mitotic cell populations in which the nuclear envelope, ER, and Golgi compartments have been physiologically disassembled before cell homogenization. These results suggest that the high efficiency of transport observed here may require reassembly of functional organelles in vitro.

Phenotypic revertants of temperature-sensitive M protein mutants of vesicular stomatitis virus: sequence analysis and functional characterization

Twenty-five spontaneous temperature-stable revertants of four different temperature-sensitive (ts) M protein mutants (complementation group III: tsG31, tsG33, tsO23, and tsO89) were sequenced and tested for their ability to inhibit vesicular stomatitis virus RNA polymerase activity in vitro. Consensus sequences of the coding region of each M protein gene were determined, using total viral RNA as template. Fifteen different sequences were found among the 25 revertants; 14 differed from their ts parent by a single amino acid (one nucleotide), and 1 differed by two amino acids (two nucleotides). Amino acids were altered in various positions between residues 64 and 215, representing over 60% of the polypeptide chain. Resequencing of the Glasgow and Orsay wild types and the four ts mutants confirmed previously published differences (Y. Gopalakrishana and J. Lenard, J. Virol., 56:655-659, 1985), and one or two additional differences were found in each. The relative charges of the revertant M proteins, as determined by nonequilibrium pH gradient electrophoresis, were consistent with the deduced sequences in every case. The ability of each revertant M protein to inhibit the RNA polymerase activity of nucleocapsids prepared from its parent ts mutant was also tested. Only 13 of the 25 revertants had M protein with high (wild type-like) polymerase-inhibiting activity, while 5 had low (ts-like) activity, and 7 had intermediate activity, demonstrating that this property is not an essential concomitant of the temperature-stable phenotype. It is concluded that the high reversion frequency observed for these mutants arises from a very high incidence of pseudoreversion, i.e., many different molecular changes can repair the ts phenotype.

Further characterization of the vesicular stomatitis virus temperature-sensitive O45 mutant: intracellular conversion of the glycoprotein to a soluble form

Reexamination of the viral products of tsO45, a glycoprotein mutant of vesicular stomatitis virus, showed that at 39 degrees C there was a conversion of the glycoprotein (G) to a truncated, soluble form, Gs, which subsequently appeared in the extracellular medium. The half-life for this intracellular conversion and extracellular appearance was about 2 h at 39 degrees C. Gs was precipitated by a monoclonal antibody to the ektodomain but not by an antipeptide serum made against the first 15 amino acids at the carboxy terminus of G. Gs was also resistant to endoglycosidase H digestion. On the basis of pulse-chase experiments, the generation of Gs most probably occurred in the rough endoplasmic reticulum. This additional phenotype of the tsO45 mutant provides another approach for studying the generation and subsequent transport of a secreted protein in fibroblast cells.

Stereo images of vesicular stomatitis virus assembly

Viral assembly was studied by viewing platinum replicas of cytoplasmic and outer plasma membrane surfaces of baby hamster kidney cells infected with vesicular stomatitis virus. Replicas of the cytoplasmic surface of the basilar plasma membrane revealed nucleocapsids forming bullet-shaped tight helical coils. The apex of each viral nose cone was anchored to the membrane and was free of uncoiled nucleocapsid, whereas tortuous nucleocapsid was attached to the base of tightly coiled structures. Using immunoelectron microscopy, we identified the nucleocapsid (N) viral protein as a component of both the tight-coil and tortuous nucleocapsids, whereas the matrix (M) protein was found only on tortuous nucleocapsids. The M protein was not found on the membrane. Using immunoreagents specific for the viral glycoprotein (G protein), we found that the amount of G protein per virion varied. The G protein was consistently localized at the apex of viral buds, whereas the density of G protein on the shaft was equivalent to that in the surrounding membrane. These observations suggest that G-protein interaction with the nucleocapsid via its cytoplasmic domain may be necessary for the initiation of viral assembly. Once contact is established, nucleocapsid coiling proceeds with nose cone formation followed by formation of the helical cylinder. M protein may function to induce a nucleocapsid conformation favorable for coiling or may cross-link adjacent turns in the tight coil or both.

Sequence alterations in temperature-sensitive M-protein mutants (complementation group III) of vesicular stomatitis virus

Sequences were determined of the coding regions of the M-protein genes of the Glasgow and Orsay strains of vesicular stomatitis virus (Indiana serotype) and of two group III (M-protein) mutants derived from each wild type. Synthetic primers were annealed with viral genomic RNA and extended with reverse transcriptase. The resulting high-molecular-weight cDNA was sequenced directly. Both Glasgow and Orsay wild types differed in 13 bases from a clone of the San Juan strain sequenced by J. K. Rose and C. J. Gallione (J. Virol. 39:519-528, 1981). Six of these base changes caused amino acid changes in each wild type, whereas seven were degenerate. The Orsay and Glasgow sequences resembled each other more closely than either resembled that of Rose and Gallione, differing in eight nucleotides and four amino acids. Each of the four mutants, however, differed from its parent wild type in only one or two point mutations. Every mutation caused a change either from or to a charged amino acid; the change for tsG31 was Lys (position 215) to Glu, the change for tsO23 was Gly (position 21) to Glu, the change for tsO89 was Ala (position 133) to Asp, the changes for tsG33 were Lys (position 204) to Thr and Glu (position 214) to Lys. The charge differences predicted from these amino acid changes was confirmed by nonequilibrium pH gradient electrophoresis for tsG31, tsG33, tsO23, and the two wild types. These mutations affect residues spanning nearly 85% of the linear sequence, although the mutants possess nearly identical phenotypic properties.

Exit of newly synthesized membrane proteins from the trans cisterna of the Golgi complex to the plasma membrane

The intracellular location at which the G protein of vesicular stomatitis virus accumulated when transport was blocked at 20 degrees C has been studied by biochemical, cytochemical, and immunocytochemical methods. Our results indicated that the viral G protein was blocked in that cisterna of the Golgi stack which stained for acid phosphatase. At 20 degrees C this trans cisterna became structurally altered by the accumulation of G protein. This alteration was characterized by extensive areas of membrane buds which were covered by a cytoplasmic coat. These coated structures were of two kinds--those that labeled with anti-clathrin antibodies and those that did not. The clathrin-coated pits consistently did not label with anti-G antibodies. Upon warming infected cells to 32 degrees C, G protein appeared on the surface within minutes. Concomitantly, the trans cisterna lost its characteristic structural organization. Double-labeling experiments were performed in which G protein localization was combined with staining for horseradish peroxidase, which had been taken up from the extracellular medium by endocytosis. The results suggest that the trans cisterna was distinct from the endosome compartment and that the latter was not an obligatory station in the route taken by G protein to the cell surface.

Vesicular stomatitis virus-infected cells fuse when the intracellular pool of functional M protein is reduced in the presence of G protein

Five highly cytolytic strains of both Indiana and New Jersey serotypes of vesicular stomatitis virus were shown to induce cell fusion in BHK-21 and R(B77) cells. Inhibition of protein synthesis after the eclipse period of viral replication is a prerequisite for vesicular stomatitis virus-induced cell fusion. Pulse-chase experiments showed that inhibition of protein synthesis would lead to a drastic reduction in the intracellular pool of M protein as compared with other proteins. A temperature-sensitive mutant defective in M protein function (G31) was the only mutant of the five complementation groups to spontaneously induce polykaryocytes at the nonpermissive temperature. Previously, G protein has been shown to play a role in vesicular stomatitis virus-induced cell fusion. These results suggest that the combination of the presence of G protein on the virus-infected cell surface and the absence of functional M protein or a reduced level of intracellular M protein promotes cell fusion. On the basis of this study, we propose that vesicular stomatitis virus infection can induce cell fusion when the functional M protein pool declines to a critical level while G protein remains on the cell surface.

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.

Direct visualization of protein transport and processing in the living cell by microinjection of specific antibodies

We have prepared polyclonal antibodies to the cytoplasmic portion of the envelope glycoprotein G of vesicular stomatitis virus (VSV) by using synthetic peptides corresponding to either the 22 or 11 ultimate carboxy-terminal residues of the G as immunogens. When antibodies to the 22 residue peptide are microinjected into monolayer baby hamster kidney cells before or shortly after infection with wild-type VSV, G protein accumulates in large intracellular patches and little G is observed in the Golgi complex or at the cell surface. In contrast, when antibodies to the 11 residue peptide are injected, no such patches are observed and G protein is seen colocalized with the injected antibody at the endoplasmic reticulum, in the Golgi complex, in transport vesicles, and at the plasma membrane. Microinjection of these antibodies does not disturb the pathway or kinetics of G-protein transport. In cells infected with a temperature-sensitive mutant of VSV, 045, the glycoprotein accumulates in the endoplasmic reticulum at 39.8 degrees C, but rapidly moves through the Golgi apparatus and then to the cell surface after a temperature shift-down to 32 degrees C. Using rhodamine-coupled antibodies to the 11 residue peptide, a microscope stage equipped for precise temperature control, and a silicon intensifier target video camera, we can visualize by video light microscopy the synchronized exocytotic transport of the G protein directly in the living cell.

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.

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.

Identification of a new protein present in vesicular stomatitis virus-infected Chinese hamster ovary cells as a degradation product of viral M protein

In addition to the five previously described vesicular stomatitis virus (VSV) proteins (L, G, N, NS, and M), a protein (Mr 17,500) accumulated late in infection of Chinese hamster ovary cells. The protein, designated M', was a cleavage product of the viral M protein (Mr 26,000) both in vivo and in vitro. (a) M' was precipitated by anti VSV serum, indicating that it is of viral origin. (b) M' peptides generated using Staphylococcus V8 protease or chymotrypsin were shared by M, but not by the other VSV proteins. (c) The conversion of M to M' was enzymatic. The enzyme denoted M protease was heat labile, was inhibited by the serine protease inhibitor phenylmethylsulfonyl fluoride, and its accumulation, which commenced between 2 and 3 hr after infection, required protein synthesis. (d) The amounts of L, G, N, and NS increased in CHO-infected cells while the amount of M increased for only 3-4 hr and decreased thereafter. Since M has been implicated in the inhibition of VSV transcription, it is possible that regulation of the amount of M by degradation is important in the regulation of VSV transcription.

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.

Preliminary characterization of coxsackievirus B3 temperature-sensitive mutants

Prototype temperature-sensitive (ts) mutants of a coxsackievirus B3 parent virus capable of replication to similar levels at 34 or 39.5 degrees C were examined for the nature of the temperature-sensitive event restricting replication in HeLa cells at 39.5 degrees C. The ts mutant prototypes represented three different non-overlapping complementation groups. The ts1 mutant (complementation group III) synthesized less than 1% of the infectious genomic RNA synthesized by the coxsackievirus B3 parent virus at 39.5 degrees C and was designated an RNA- mutant. Agarose gel analysis of glyoxal-treated RNA from cells inoculated with ts1 virus revealed that cell RNA synthesis continued in the presence of synthesis of the small amount of viral RNA. This mutant was comparatively ineffective in inducing cell cytopathology and in directing synthesis of viral polypeptides, likely due to the paucity of nascent genomes for translation. The ts5 mutant (complementation group II) directed synthesis of appreciable quantities of both viral genomes (RNA+) and capsid polypeptides; however, assembly of these products into virions occurred at a low frequency, and virions assembled at 39.5 degrees C were highly unstable at that temperature. Shift-down experiments with ts5-inoculated cells showed that capsid precursor materials synthesized at 39.5 degrees C can, after shift to 34 degrees C, be incorporated into ts5 virions. We suggest that the temperature-sensitive defect in this prototype is in the synthesis of one of the capsid polypeptides that cannot renature into the correct configuration required for stability in the capsid at 39.5 degrees C. The ts11 mutant (complementation group I) also synthesized appreciable amounts of viral genomes (RNA+) and viral polypeptides at 39.5 degrees C. Assembly of ts11 virions at 39.5 degrees C occurred at a low frequency, and the stability of these virions at 39.5 degrees C was similar to that of the parent coxsackievirus B3 virions. The temperature-sensitive defect in the ts11 prototype is apparently in assembly. The differences in biochemical properties of the three prototype ts mutants at temperatures above 34 degrees C may ultimately offer insight into the differences in pathogenicity observed in neonatal mice for the three prototype ts mutants.

Membrane insertion at the leading edge of motile fibroblasts

We are concerned with the mechanisms involved in the directed migration of eukaryotic cells. Previously we found that, inside cells at the edge of an experimental wound, the Golgi apparatus and the microtubule-organizing center were rapidly repositioned forward of the nucleus in the direction of subsequent cell migration into the wound. This repositioning was proposed to serve the purpose of introducing new membrane mass at the leading edge of the cell, by directing Golgi apparatus-derived vesicles bound for the plasma membrane to that edge. We now provide evidence to support this proposal. Cultured fibroblastic cells at the edge of a wound were infected with a temperature-sensitive mutant (0-45) of vesicular stomatitis virus. It is known that the G-protein, an integral membrane protein of the virus, is synthesized and remains in the rough endoplasmic reticulum at the nonpermissive temperature, but when the infected cells are shifted to the permissive temperature, the G-protein moves through the Golgi apparatus to the plasma membrane. By immunofluorescence microscopy, we here show that the first appearance of the G-protein at the cell surface corresponds to the leading edge of the motile cell. These observations are incorporated into a coherent scheme for the mechanisms involved in cell migration.

Characterization of two temperature-sensitive mutants of type 5 adenovirus with mutations in the 100,000-dalton protein gene

Complementation analysis assigned the mutations of strains H5ts115 and H5ts116, two hexon-minus mutants, to the 100,000-dalton (100K) protein gene. Heterotypic marker rescue (i.e., type 5 adenovirus [Ad5] temperature-sensitive mutants DNA X EcoRI restriction fragments of Ad2 DNA) confirmed the results of previous marker rescue mapping studies, and the heterotypic recombinants yielded unique hybrid (Ad5-Ad2) 100K proteins which were intermediate in size between Ad5 and Ad2 proteins and appeared to be as functionally active as the wild-type 100K protein. Phenotypic characterization of these mutants showed that both the hexon polypeptides and the 100K polypeptides were unstable at the nonpermissive temperature, whereas fiber and penton were not degraded, and that the 100K protein made at 39.5 degrees C could not be utilized after a shift to the permissive temperature (32 degrees C). The role of the 100K protein in the assembly of the hexon trimer was also examined by in vitro protein synthesis. Normally, hexon polypeptides synthesized during an in vitro reaction are assembled into immunoreactive hexons. However, this assembly was inhibited by preincubation of the cell extract with anti-100K immunoglobulin G; neither anti-fiber immunoglobulin G nor normal rabbit immunoglobulin G inhibited hexon assembly. It is postulated that an interaction between the 100K protein and hexon polypeptides is required for effective assembly of hexon trimers.

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.

Murine central nervous system infection by a viral temperature-sensitive mutant: a subacute disease leading to demyelination

Temperature-sensitive (ts) mutants of viruses may represent an important mechanism for viral persistence. Ts mutants of different complementation groups of vesicular stomatitus virus (VSV) have shown various disease patterns in infected mice which were at variance with the clinical and pathologic features of wild-type virus infection. To investigate whether neurovirulence of different ts mutants was dependent on the individual mutant or on the biochemical defect(s) common to all members of a complementation group, we infected mice with ts G32 VSV, a mutant of the same complementation group III as the previously described ts G31 VSV. Pathologic changes in infected mice were sharply different from those produced by ts G31 VSV and actually similar to those produced by ts G41 VSV, a member of Complementation Group IV, also previously described. These results suggest that the biologic behavior of ts mutants is dependent on the individual characteristics of each mutant. The most important alterations by ts G32 VSV were in the white matter of brain and spinal cord, where extensive inflammatory demyelination was observed. Lack of inflammation and demyelination in similarly infected nude mice would suggest that, in this infection, demyelination is produced by the host immune response rather than by direct viral myelinolytic activity. Such findings are similar to those we described in other viral infections and support the hypothesis of a common host-mediated pathway leading to demyelination in a variety of unrelated viral infections. These conclusions may have relevance to human demyelinating diseases.

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.

Mutational changes in the vesicular stomatitis virus glycoprotein affect the requirement of carbohydrate in morphogenesis

The role of carbohydrate in the morphogenesis of vesicular stomatitis virus was studied, using the antibiotic tunicamycin to inhibit glycosylation. It has been reported previously (Gibson et al., J. Biol. Chem. 254:3600-3607, 1979) that the San Juan strain of vesicular stomatitis virus requires carbohydrate for efficient migration of the glycoprotein (G) to the cell surface and for virion formation, whereas the prototype or Orsay strain of vesicular stomatitis virus is less stringent in its carbohydrate requirement at 30 degrees C. However, there are many differences between the two strains. We found that mutational changes within the G protein of the same strain of virus (prototype or Orsay) alters the requirement for carbohydrate at 30 degrees C. Group V or G protein mutants tsO45 and tsO44, like their prototype parent, did not require carbohydrate for efficient morphogenesis. In contrast, the G protein of another group V mutant, tsO110, was totally dependent upon carbohydrate addition for migration to the cell surface. Furthermore, no tsO110 particles were released in the absence of glycosylation. The wild-type prototype strain did require carbohydrate at 39.5 degrees C for insertion of the G protein into the plasma membrane and virion formation. However, a pseudorevertant of tsO44 (tsO44R), unlike the prototype parent, no longer exhibited this temperature-sensitive requirement for carbohydrate. At 39.5 degrees C in the presence of tunicamycin, tsO44R-infected cells released normal yields of particles and the unglycosylated G reached the cell surface very efficiently. In contrast to tsO110, which absolutely requires carbohydrate, mutational change in the tsO44R G protein has eliminated the requirement for carbohydrate. Thus, simple mutational changes, as opposed to many changes in the molecule, are sufficient to alter the carbohydrate requirement.

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.

Mutants of vesicular stomatitis virus blocked at different stages in maturation of the viral glycoprotein

Maturation of the vesicular stomatitis virus (VSV) glycoprotein (G) to the cell surface is blocked at the nonpermissive temperature in cells infected with temperature-sensitive mutants in the structural gene encoding for G. We show here that these mutants fall into two discrete classes with respect to the stage of post-translational processing at which the block occurs. In all cases the mutant glycoproteins are inserted normally into the endoplasmic reticulum membrane, receive the two-high-mannose oligosaccharides, and apparently lose the NH2-terminal signal sequence of 16 amino acids. In cells infected with one class of mutants, no further processing of the glycoprotein occurs, and we conclude that the mutant protein is blocked at a pre-Golgi stage. In cells infected with ts L511(V), however, addition of the terminal sugars galactose and sialic acid occurs normally. Thus the maturation of G proceeds through several Golgi functions but is blocked before its appearance on the cell surface. The oligosaccharide chain of ts L511(V) G, accumulated at either the permissive (where surface maturation occurs) or the nonpermissive temperature, lacks one saccharide residue, probably fucose. In addition, no fatty acid residues are added to the ts L511(V) G protein at the nonpermissive temperature, although addition does occur under permissive conditions.

Neurovirulence mutant of vesicular stomatitis virus with an altered target cell tropism in vivo

Intracerebral infection of weanling Swiss mice with a temperature-sensitive (ts) mutant of vesicular stomatitis virus (VSV), ts pi364, resulted in a unique neuropathological syndrome not previously described with other VSV mutants. Mice infected with wild-type VSV died from an acute encephalitis characterized by neuronal necrosis and efficient virus replication in both brain and spinal cord. In contrast, with VSV ts pi364, the most prominent histopathological feature was destruction of the ependyma of the lateral ventricles. Virus antigen was also limited to the leptomeninges and the lateral ventricles. Infected mice survived and developed hydrocephalus. Replication of ts pi364 in the brain was 10- to 100- fold less than that of wild-type VSV, and appearance of virus in the spinal cord was delayed. VSV ts pi364 was isolated from mouse cells persistently infected with VSV. Another VSV ts pi mutant, isolated from the same persistent infection, behaved in vivo like wild-type VSV, even though both mutants were very similar in plaque size, reversion frequency, cut-off temperature, and synthesis of virus-specific proteins at semipermissive temperature. These results strongly suggest that VSV ts pi364 has a second, non-ts mutation which results in a restricted target cell range in vivo; wild-type VSV can infect both neurons and ependymal cells, whereas ts pi364 does not replicate in neurons.

Temperature-sensitive mutants of Chandipura virus. II. Phenotypic characteristics of the six complementation groups

Fifty temperature-sensitive (ts) mutants of the rhabdovirus Chandipura virus have been classified into six complementation groups designated ChI to ChVI. Group ChI contains 44 mutants, group ChII contains 2 mutants, and the remaining groups have 1 mutant each. Mutants in groups ChI, ChIII, ChIV, and ChVI had RNA-negative phenotypes in experiments measuring amplification of RNA synthesis at restrictive temperature. The two mutants in group ChII had RNA-positive phenotypes, and the virions were thermolabile. Mutant ts Ch851 of group ChV was also RNA positive, and the M polypeptide of this mutant appeared to be unstable in cells incubated at restrictive temperature. It is likely, therefore, that complementation groups ChII and ChV represent the genes coding for the two viral proteins of the virion envelope. No precise assignment can be made in the case of the four RNA-negative groups, since all the mutants examined showed some polymerase activity in vitro at restrictive temperature. An attempt to obtain polymerase mutants by screening for sensitivity to rifampin was not successful. Six temperature-dependent host range mutants (the tdCE phenotype) of Chandipura virus failed to multiply in chicken embryo cells at restrictive temperature, but otherwise they differed in their host range properties from similar mutants of vesicular stomatitis virus.

Temperature-sensitive mutants of Chandipura virus. I. Inter- and intragroup complementation

Fifty temperature-sensitive (ts) mutants of Chandipura virus, a human rhabdovirus, have been classified into six complementation groups, designated ChI, ChII, ChII, ChIV, ChV, and ChVI and containing 44, 2, 1, 1, 1, and 1 mutants, respectively. Weak complementation was observed within group ChI, allowing the division of the group into subgroups ChIA and ChIB. Intragroup complementation was most extensive within subgroup ChIB, and one mutant in this subgroup complemented all but one (ts Ch598) of the mutants in group ChI. If ts Ch598 had been omitted from the analysis the number of complementation groups would have been increased to seven. Consequently, in circumstances where intragenic and intergenic complementation cannot be clearly distinguished, the number of complementation groups identified in rhabdoviruses could be overestimated. The identification of six complementation groups in three different rhabdoviruses need not imply the existence of an as yet unidentified sixth virus-specified polypeptide. The extensive intragroup complementation observed in Chandipura virus suggests that the functional form of one at least of the virion proteins of Chandipura virus is a multimer.

Effect of temperature-sensitive mutation on activity of the RNA transcriptase of vesicular stomatitis virus New Jersey

The virion-associated RNA transcriptase activity of vesicular stomatitis virus New Jersey temperature-sensitive (ts) mutants was assayed in vitro at the permissive (31 degrees C) and restrictive (39 degrees C) temperatures. RNA synthesis at 39 degrees C by the RNA-negative ts A1 and the RNA-positive ts C1 and ts D1 mutants was similar to that of wild-type virus. The RNA-negative ts B1 synthesized only small amounts of RNA in vitro at 39 degrees C. The three mutants of complementation group E were dissimilar in the amounts of RNA they synthesized at 39 degrees C: ts E1 synthesized very little RNA, ts E2 synthesized moderate amounts, and RNA synthesis by ts E3 was not inhibited. The two mutants of group F were also dissimilar, since ts F1 synthesized very little RNA at 39 degrees C, whereas ts F2 synthesized as much RNA as wild-type virus. The revertant clones ts B1/R1, ts E1/R1, and ts F1/R1 synthesized RNA at 39 degrees C in amounts comparable to wild-type virus, indicating that the heat sensitivity of the transcriptase activity of the mutants ts B1, ts E1, and ts F1 was associated with temperature sensitivity. Similar heat sensitivities were observed when transcribing nucleoprotein complexes were used in the assays, showing that the mutated polypeptides were part of the viral core. The heat stability of the mutant ts B1 was similar to that of wild-type virus, and in vitro RNA synthesis was fully restored when the temperature was lowered to 31 degrees C after 30 min of preincubation at 39 degrees C, showing that the inhibition was due to reversible configurational change of the mutated polypeptide. When virions of the mutant ts E1 were heated for 5 h at 39 degrees C, their infectivity and transcriptase activity were as stable as those of the wild-type virus, whereas transcriptase activity became very heat labile after disruption of the viral coat with a neutral detergent. This suggests an interaction between the mutated polypeptide and a coat polypeptide which stabilizes the activity of the transcriptase. The RNA transcriptase activity of the mutant ts F1 was also heat labile, although to a lesser extent than that of ts E1. Thus, the defects in transcriptase activity of groups B, E, and F suggest that all three polypeptides of the virus core, polypeptides L, N, and NS, are involved in the transcription. In addition, we postulate that the mutated gene products of groups E and F are multifunctional, being required both in transcription and replication, and that the gene product of group E may also be involved in some late stage of virus development.