Screening procedure for complementation-dependent mutants of vesicular stomatitis virus.

To isolate new types of vesicular stomatitis virus (VSV) mutants, a four-stage screen was developed which identifies and characterizes mutants capable of complementing the defect in the VSV temperature-sensitive mutant tsG11. Two types of mutants of VSV, Indiana serotype, have been found by using the screen; they are new temperature-sensitive mutants which are, of necessity, not in complementation group I and mutants which do not produce plaques under conditions of single infection at 31 C (the normal permissive temperature) and are, therefore, called complementation-dependent mutants. The newly isolated, temperature-sensitive mutants fall into three complementation groups, two of which are congruent with known complementation groups; the newly identified group extends to six the number of complementation groups of VSV Indiana. The nature of the complementation-dependent mutants has not been established, but one was shown to not contain a significant deletion in its nucleic acid.     

Growth and Maturation of a Vesicular Stomatitis Virus Temperature-Sensitive Mutant and Its Central Nervous System Isolate

A temperature-sensitive (ts) mutant of vesicular stomatitis virus (VSV), tsG31, produces a prolonged central nervous system disease in mice with pathological features similar to those of slow viral diseases. tsG31 and the subsequent virus recovered from the central nervous system (tsG31BP) of mice infected with tsG31 were compared with the parental wild-type (WT) VSV for plaque morphology, growth kinetics, thermal sensitivity of the virions, and viral protein synthesis and maturation. Several properties of the central nervous system isolate distinguished this virus from the original tsG31 and the WT VSV. The WT VSV produced clear plaques with complete cell lysis, and the tsG31 produced diffuse plaques and incomplete cell lysis, whereas the tsG31BP had clear plaques similar to those of the WT VSV. Although plaque morphology suggested that tsG31BP virus was a revertant to the WT, growth kinetics in either BHK-21 or neuroblastoma (N-18) cells indicated that this virus was similar to tsG31, with a productive cycle at 31 degrees C and no infectious virus at 39 degrees C. At 37 degrees C, however, the tsG31BP matured much slower than did the original tsG31 (and produced only 1% of the yield measured at 31 degrees C). WT VSV produced similar quantities of infectious virions at 31, 37, and 39 degrees C. The lack of infectious virions at 39 degrees C for the ts mutants was presumably not due to a greater rate of inactivation at 39 degrees C. Unlike WT VSV, which synthesized viral proteins equally well at all three temperatures, tsG31 had a reduced synthesis of all the structural proteins at 37 and 39 degrees C, compared with that at 31 degrees C; the formation of the M protein was most temperature sensitive. In addition, fractionation of the infected cells indicated that the incorporation of the M and N proteins into the cellular membranes was also disrupted at the higher, nonpermissive temperatures. Several characteristics of protein synthesis during tsG31BP infection at 39 degrees C distinguished this virus from tsG31: (i) no mature viral proteins were detected at 39 degrees C; (ii) several host proteins were [ill], suggesting that the virus was incapable of completely depressing host macromolecular synthesis; and (iii) a great proportion of the incorporated radioactivity was found in unusually high-molecular-weight proteins. In addition, at 37 degrees C, the tsG31BP virus showed a decreased synthesis of viral proteins and reduced assembly of the viral structural proteins.     

Isolation and Characterization of Temperature-Sensitive Mutants of Vesicular Stomatitis Virus, New Jersey Serotype

Forty-eight temperature-sensitive (ts) mutants have been isolated from a wild-type strain of the New Jersey serotype of vesicular stomatitis virus (VSV) after exposure to the base analogue mutagen 5-fluorouracil. Of these mutants, 47 have been classified into 6 nonoverlapping complementation groups containing 21, 17, 4, 3, 2, and 1 mutant, respectively (1 mutant remaining unallocated). The ribonucleic acid (RNA) phenotype of 23 of these mutants has been established. Four of the six groups contain one or more mutants unable to synthesize detectable amounts of viral RNA under restrictive conditions (39 C). No complementation was observed in mixed infection with ts mutants from the five established complementation groups of the Indiana serotype of VSV.     

Progeny resulting from complementation between mutants of vesicular stomatitis virus.

The complementation properties of the virus progeny released from cells mixedly infected with mutants of vesicular stomatitis virus belonging to four different complementation groups have been examined. The group IV mutant, tsW16B, was tested in combinations with three group I mutants (tsW4, tsW28, and tsG11), one group II mutant (tsG22), and one group III mutant (tsW29). Virus stocks were grown from isolated plaques appearing on the cell monolayers used to assay the mixed infection yields and tested, in a second series of mixed infections, for their ability to complement each of the two parents. It was found that the virus harvested from each one of the first series of mixed infections contained mutants of both parental types.     

Inhibition of vesicular stomatitis virus infection by spike glycoprotein. Evidence for an intracellular, G protein-requiring step

In an assay measuring virus-directed RNA synthesis, infection of BHK cells by a standard test dose of vesicular stomatitis virus (VSV) was inhibited by ultraviolet light-irradiated wt VSV and by ts 045, one of a number of thermolabile, temperature-sensitive G protein mutants of VSV. After heat treatment for 1 h at 45 degrees C, the thermolabile mutants were no longer able to inhibit the VSV infection. In contrast, the thermolabile M protein mutant ts G31 and the nonthermolabile G protein mutant ts 044 could still inhibit the test VSV dose. Thus, the presence of G protein in its native conformation was necessary for inhibition of infection. There was little difference in the binding to cells or the internalization to a trypsin-resistant state of ts 045 or wt VSV before and after heat treatment, and there was no evidence of specific saturable receptors on the cell surface. None of the irradiated virions at concentrations that gave maximal inhibition of infection could prevent binding of infectious VSV to, or internalization by, BHK cells. The G protein-specific inhibition, therefore, did not occur at the cell surface but must have occurred at some intracellular site, which has been suggested to be the lysome. The lysosomal inhibitor chloroquine, when added with the infecting virus, completely inhibited VSV infection at all multiplicities of infection tested, and it gave 50% inhibition when added to 1.5 h after infection. The possible importance of the lysosome in the intracellular pathway of infection 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.     

Mechanism of vesicular stomatitis virus mRNA decay

The chemical and functional stability of the five vesicular stomatitis virus (VSV) messenger RNAs during infection of Chinese hamster ovary (CHO) cells was studied using the temperature-sensitive mutant, tsG114. By incubating infected cells at the nonpermissive temperature (39 °C), RNA synthesis was blocked and the five VSV mRNAs decayed chemically and functionally with a half-life of 1 to 1.5 h. However, all five VSV mRNAs were stable in vivo at 39 °C when protein synthesis was blocked with either cycloheximide or emetine. In contrast, when pactamycin was used to inhibit protein synthesis, the chemical and functional decay rates of the VSV mRNAs were indistinguishable from those observed in the absence of antibiotic. On the basis of the mode of action of each of the antibiotic inhibitors, these data imply that (a) ribosome movement along VSV mRNAs plays no role in their stabilities, and (b) each VSV mRNA contains a nuclease-sensitive site, at its 5′ end at or near the initiation site, which regulates its decay in vivo.     

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.     

Defective Particles in BHK Cells Infected with Temperature-Sensitive Mutants of Vesicular Stomatitis Virus

Defective particles were the major product after undiluted passage of certain temperature-sensitive (ts) mutants of the Indiana C strain of vesicular stomatitis virus in BHK-21 cells at the permissive temperature (31 C). Essentially homogeneous preparations of defective particles were obtained with the wild-type and individual ts mutants. The defective particles associated with some of the ts mutants, however, were morphologically and physically distinguishable from wild type and from each other. All varieties of defective particle interfered with the multiplication of mutant and wild-type virus at the permissive temperature at early times of infection but failed to complement virions of different complementation groups at the restrictive temperature (39 C) at any time during infection.     

Abortive transformation of temperature-sensitive mutants of rat 3Y1 cells by simian virus 40: effect of cellular arrest states on entry into S phase and cellular proliferation

Four temperature-sensitive (ts) mutants of rat 3Y1 fibroblasts, representing independent complementation groups, cease to proliferate predominantly with a 2n DNA content, at the restrictive temperature (39.8 degrees C) (temperature arrest) or at the permissive temperature (33.8 degrees C) at a confluent cell density (density arrest) (Ohno et al., 1984). We studied the temperature- or the density-arrested cells of these mutants infected with simian virus 40 (SV40) or its mutants affecting large T or small t antigen with respect to kinetics at 39.8 degrees C of entry into S phase and cellular proliferation. Three mutants, 3Y1tsD123, 3Y1tsF121 and 3Y1tsG125, expressed T antigen and entered S phase at 39.8 degrees C from both the arrested states after infection with either wild-type, tsA mutants, or a .54/.59 deletion mutant of SV40, whereas in the density-arrested 3Y1tsH203, expression of T antigen and entry into S phase were inefficient and ts. Following the WT-SV40 induced entry into S phase, the temperature-arrested 3Y1tsD123 detached from the substratum with no detectable increase in cell number, whereas the density-arrested ones completed a round of the cell cycle and then detached. 3Y1tsF121 and 3Y1tsG125 in the both arrested states proliferated through more than one generation. 3Y1tsF121 and 3Y1tsG125 in the density-arrested state infected with tsA mutants once proliferated and then ceased to increase in number as the percentage of T-antigen positive population decreased. These results suggest that wild-type and tsA-mutated large T antigens are able to overcome the cellular ts blocks of entry into S phase in the 3 ts mutants of 3Y1 cells in both the arrested states, and that small t antigen is not required to overcome the blocks. It is also suggested that cellular behaviors subsequent to S phase (viability, mitosis, and proliferation in the following generations) depend on cellular arrest states, on traits of cellular ts defects, and on the duration of large T antigen expression.     

Induction of DNA synthesis by fibroblast growth factor in temperature-sensitive cell-cycle mutants of rat 3Y1 fibroblasts arrested at restrictive temperature.

Four temperature-sensitive cell-cycle mutants of rat 3Y1 clonal fibroblasts representing separate complementation groups (3Y1tsD123, 3Y1tsF121, 3Y1tsG125 and 3Y1tsH203) are arrested at restrictive temperature, primarily with a G1-phase DNA content (temperature arrest). We examined various factors affecting signal transduction for activity which induces DNA synthesis at the restrictive temperature when added to the temperature-arrested cultures of these mutants. The factors examined were theophylline, dibutyryl cyclic AMP, cholera toxin (CT), dibutyryl cyclic GMP, sodium nitroprusside, phorbol 12-myristate 13-acetate, 1-oleoyl 2-acetylglycerol, bombesin, vasopressin, basic fibroblast growth factor (FGF), platelet-derived growth factor, A23187, monensin, epidermal growth factor (EGF), insulin and fetal calf serum (FCS). None of these factors induced DNA synthesis in 3Y1tsH203. In one mutant (3Y1ts121), FGF, EGF and FCS individually induced DNA synthesis. In the other 2 mutants (3Y1tsD123 and 3Y1tsG125), FGF and CT individually induced DNA synthesis. The FGF-induced DNA synthesis was suppressed by islet-activating protein (IAP) in 3Y1tsD123 and 3Y1tsG125, but not in 3Y1tsF121. The CT-induced DNA synthesis was also suppressed by IAP, as previously shown. When temperature-arrested cultures were shifted to a permissive temperature, all 4 mutants initiated DNA synthesis in the presence of IAP. These results suggest that (1) a cell can prepare for the initiation of DNA synthesis by using several independent signal transduction pathways, and (2) in a given situation, the cell uses a particular pathway because of its availability, which depends on the culture conditions.     

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.     

A fluorescence photobleaching study of vesicular stomatitis virus infected BHK cells. Modulation of G protein mobility by M protein

The mobility of vesicular stomatitis virus (VSV) G protein on the surface of infected BHK cells was studied by using the technique of fluorescence photobleaching recovery. The fraction of surface G protein that was mobile in that time scale of the measurement (minutes) was at least 75%, a relatively high value among cell surface proteins so far observed. For studies of the effect of an internal viral protein (M protein) on G protein mobility, cells infected with wild-type VSV were compared with those infected with temperature-sensitive VSV mutants of complementation group III, which contains lesions in the M protein. At the permissive temperature, a pronounced decrease in the mobile fraction of surface G was observed for each of three mutants studied, while mobility of surface G at the nonpermissive temperature was indistinguishable in mutant and wild-type infected cells. A significantly lower mobile fraction of G protein was also observed in SV40 transformed 3T3 cells infected with wild-type VSV, but not in 3T3 or chick embryo fibroblast cells similarly infected. None of the variables tested had a measurable effect on the lateral diffusion coefficient of the mobile G protein. These results are interpreted as modulation of the mobility of a specific cell surface protein by a specific intracellular protein.