Phenotypic characterization of temperature-sensitive mutants of vaccinia virus with mutations in a 135,000-Mr subunit of the virion-associated DNA-dependent RNA polymerase

The phenotypic defects of three temperature-sensitive (ts) mutants of vaccinia virus, the ts mutations of which were mapped to the gene for one of the high-molecular-weight subunits of the virion-associated DNA-dependent RNA polymerase, were characterized. Because the virion RNA polymerase is required for the initiation of the viral replication cycle, it has been predicted that this type of mutant is defective in viral DNA replication and the synthesis of early viral proteins at the nonpermissive temperature. However, all three mutants synthesized both DNA and early proteins, and two of the three synthesized late proteins as well. RNA synthesis in vitro by permeabilized mutant virions was not more ts than that by the wild type. Furthermore, only one of three RNA polymerase activities that was partially purified from virions assembled at the permissive temperature displayed altered biochemical properties in vitro that could be correlated with its ts mutation: the ts13 activity had reduced specific activity, increased temperature sensitivity, and increased thermolability under a variety of preincubation conditions. Although the partially purified polymerase activity of a second mutant, ts72, was also more thermolabile than the wild-type activity, the thermolability was shown to be the result of a second mutation within the RNA polymerase gene. These results suggest that the defects in these mutants affect the assembly of newly synthesized polymerase subunits into active enzyme or the incorporation of RNA polymerase into maturing virions; once synthesized at the permissive temperature, the mutant polymerases are able to function in the initiation of subsequent rounds of infection at the nonpermissive temperature.     

Inhibition of Interjacent Ribonucleic Acid (26S) Synthesis in Cells Infected by Sindbis Virus

The interrelationship of viral ribonucleic acid (RNA) and protein synthesis in cells infected by Sindbis virus was investigated. When cultures were treated with puromycin early in the course of infection, the synthesis of interjacent RNA (26S) was preferentially inhibited. A similar result was obtained by shifting cells infected by one temperature-sensitive mutant defective in RNA synthesis from the permissive (29 C) to the nonpermissive (41.5 C) temperature. Under both conditions, the viral RNA produced appeared to be fully active biologically. Once underway, the synthesis of viral RNA in wild-type Sindbis infections did not require concomitant protein synthesis.     

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.     

Physical mapping of herpes simplex virus type 1 mutations by marker rescue.

Thirty temperature-sensitive mutants of encephalomyocarditis virus have been isolated and partially characterized. Fifteen of these mutants are phenotypically RNA+ thirteen are RNA-, and two are RNA +/-. Six RNA + mutants, one RNA- mutants, and one RNA +/- mutant have virions which are more thermosensitive at 56 degree C than the wild-type virions. Hela cells infected at the nonpermissive temperature with any of the RNA+ mutants produced neither infective nor noninfective viral particles. The cleavage of the precursor polypeptides in cells infected with 11 of the RNA+ mutants was defective at the nonpermissive temperature. This defect in cleavage occurred only in those precursor polypeptides leading to capsid proteins.     

Characterization of an adenovirus early protein required for viral DNA replication: A single strand specific DNA binding protein

1. The human adenoviruses types 2, 5 and 12 code for the production of a single strand specific DNA binding protein. The molecular weights of these proteins were 72,000 for types 2 and 5 and 60,000 for type 12. In all three cases proteolytic breakdown fragments of these binding proteins (48,000 MW) were also observed. 2. Analysis of the methionine containing tryptic peptides of these proteins indicate that the types 2 and 5 proteins are similar and clearly distinguishable from the type 12 protein. The peptide maps of these three viral proteins are clearly different from a similar protein found in mock infected cells. 3. Temperature sensitive mutants of type 5 (H5ts125) and type 12(H12tsA275) adenoviruses fail to produce these proteins at the nonpermissive temperature. H5ts125 infected cells grown at the permissive temperature produce a 72,000 MW protein that is thermolabile, for continued binding to DNA, when compared to type 5 wild type adenovirus 72,000 MW protein. An analysis of the phenotype of this adenovirus mutant indicates that it codes for a viral function at early times after infection that is required for viral DNA replication. 4. The in vitro translation of adenovirus specific m-RNA results in the synthesis of a small amount of a 72,000 MW protein that binds to single stranded DNA just like the authentic adenovirus DNA binding proteins produced in infected cells. 5. Adenovirus anti-Tumor antigen (T) anti-serum from hamsters carrying independently derived adenovirus tumors, have been tested for the presence of antibody to purified DNA binding proteins. One antiserum is positive for these antibodies while the other is negative. These results indicate that some, but not all, adenovirus tumors contain large enough levels of the DNA binding proteins to elicit an antibody response. 6. The type 5 adenovirus temperature sensitive mutant, H5ts125, that codes for a thermolabile DNA binding protein, was complemented or suppressed at the nonpermissive temperature, for the replication of adenovirus DNA, by SV40. SV40tsA temperature sensitive mutants, defective in SV40 DNA replication, do not suppress or complement H5ts125 at the nonpermissive temperature.     

Reovirus sigmaNS protein is required for nucleation of viral assembly complexes and formation of viral inclusions

Progeny virions of mammalian reoviruses are assembled in the cytoplasm of infected cells at discrete sites termed viral inclusions. Studies of temperature-sensitive (ts) mutant viruses indicate that nonstructural protein sigmaNS and core protein mu2 are required for synthesis of double-stranded (ds) RNA, a process that occurs at sites of viral assembly. We used confocal immunofluorescence microscopy and ts mutant reoviruses to define the roles of sigmaNS and mu2 in viral inclusion formation. In cells infected with wild-type (wt) reovirus, sigmaNS and mu2 colocalize to large, perinuclear structures that correspond to viral inclusions. In cells infected at a nonpermissive temperature with sigmaNS-mutant virus tsE320, sigmaNS is distributed diffusely in the cytoplasm and mu2 is contained in small, punctate foci that do not resemble viral inclusions. In cells infected at a nonpermissive temperature with mu2-mutant virus tsH11.2, mu2 is distributed diffusely in the cytoplasm and the nucleus. However, sigmaNS localizes to discrete structures in the cytoplasm that contain other viral proteins and are morphologically indistinguishable from viral inclusions seen in cells infected with wt reovirus. Examination of cells infected with wt reovirus over a time course demonstrates that sigmaNS precedes mu2 in localization to viral inclusions. These findings suggest that viral RNA-protein complexes containing sigmaNS nucleate sites of viral replication to which other viral proteins, including mu2, are recruited to commence dsRNA synthesis.     

Temperature-sensitive Mutants of Sindbis Virus: Biochemical Correlates of Complementation

Temperature-sensitive mutants of Sindbis virus fail to grow at a temperature that permits growth of the wild type, but when certain pairs of these mutants, mixed together, infect cells at that temperature, viral growth (i.e., complementation) occurs. The yield from this complementation, however, is of the same order of magnitude as the infectivity in the inoculum. Since in animal virus infections the protein components of the virion probably enter the cell with the viral nucleic acid, it was necessary to demonstrate that the observed complementation required synthesis of new viral protein and nucleic acid rather than some sort of rearrangement of the structural components of the inoculum. To demonstrate that complementation does require new biosynthesis, three biochemical events of normal virus growth have been observed during complementation and correlated with the efficiency of viral growth seen in complementation. These events include: (i) entrance of parental viral ribonucleic acid (RNA) into a double-stranded form; (ii) subsequent synthesis of viral RNA; and (iii) synthesis and subsequent incorporation of viral protein(s) into cell membranes where they were detected by hemadsorption. Although the infecting single-stranded RNA genome of the wild type was converted to a ribonuclease-resistant form, the genome of a mutant (ts-11) incapable of RNA synthesis at a nonpermissive temperature was not so converted. However, during complementation with another mutant also defective in viral RNA synthesis, some of the RNA of mutant ts-11 was converted to a ribonuclease-resistant form, and total synthesis of virus-specific RNA was markedly enhanced. The virus-specific alteration of the cell surface, detected by hemadsorption, was also extensively increased during complementation. These observations support the view that complementation between temperature-sensitive mutants and replication of wild-type virus are similar processes.     

Rotavirus RNA replication: VP2, but not VP6, is necessary for viral replicase activity.

Temperature-sensitive mutants of simian rotavirus SA11 were previously developed and organized into 10 of a possible 11 recombination groups on the basis of genome reassortment studies. Two of these mutants, tsF and tsG, map to genes encoding VP2 (segment 2) and VP6 (segment 6), respectively. To gain insight into the role of these proteins in genome replication, MA104 cells were infected with tsF or tsG and then maintained at permissive temperature (31 degrees C) until 9 h postinfection, when some cells were shifted to nonpermissive temperature (39 degrees C). Subviral particles (SVPs) were recovered from the infected cells at 10.5 and 12 h postinfection and assayed for associated replicase activity in a cell-free system shown previously to support rotavirus genome replication in vitro. The results showed that the level of replicase activity associated with tsF SVPs from cells shifted to nonpermissive temperature was ca. 20-fold less than that associated with tsF SVPs from cells maintained at permissive temperature. In contrast, the level of replicase activity associated with tsG SVPs from cells maintained at nonpermissive temperature was only slightly less (twofold or less) than that associated with tsG SVPs from cells maintained at permissive temperature. Analysis of the structure of replicase particles from tsG-infected cells shifted to nonpermissive temperature showed that they were similar in size and density to virion-derived core particles and contained the major core protein VP2 but lacked the major inner shell protein VP6. Taken together, these data indicate that VP2, but not VP6, is an essential component of enzymatically active replicase particles.     

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.     

Proposed replicative role of the NS polypeptide of vesicular stomatitis virus: structural analysis of an electrophoretic variant.

The structural lesion in the temperature-sensitive mutant E1 of the New Jersey serotype of vesicular stomatitis virus has been assigned to the NS protein. Although the packaged wild-type and mutant NS proteins were similarly phosphorylated, the mutant NS protein migrated faster than the wild-type NS protein in polyacrylamide slab gels electrophoresed in the presence of sodium dodecyl sulfate. The resolution appears to be the result of conformational rather than size differences since the two proteins comigrated in polyacrylamide gels which contained 4 M urea in addition to sodium dodecyl sulfate. Peptide maps, obtained by limited proteolysis of 32P-labeled wild-type and mutant NS proteins with Staphylococcus aureus V8 protease and papain, revealed striking differences which suggested that the mutant alteration could involve an aspartic or glutamic acid residue. Since NS proteins obtained from naturally occurring revertants of E1 were indistinguishable from the wild-type protein in all of these analyses, the structural alteration in the mutant NS protein correlates with the functional lesion. Because E1 is defective in the RNA replication pathway at the restrictive temperature, a replicative role is proposed for the NS protein.     

Defined mutations in a small region of the brome mosaic virus 2 gene cause diverse temperature-sensitive RNA replication phenotypes

The central portion of the brome mosaic virus (BMV) 2a protein represents the most conserved element among the related RNA replication components of a large group of positive-strand RNA viruses of humans, animals, and plants. To characterize the functions of the 2a protein, mutations were targeted to a conserved portion of the 2a gene, resulting in substitutions between amino acids 451 and 484. After the temperature profile of wild-type BMV RNA replication was defined, RNA replication by nine selected mutants was tested in barley protoplasts at permissive (24 degrees C) and nonpermissive (34 degrees C) temperatures. Four mutants did not direct RNA synthesis at either temperature. Various levels of temperature-sensitive (ts) replication occurred in the remaining five mutants. For two ts mutants, no viral RNA synthesis was detected at 34 degrees C, while for two others, an equivalent reduction in positive- and negative-strand RNA accumulation was observed. For one mutant, positive-strand accumulation was preferentially reduced over negative-strand accumulation at 34 degrees C. Moreover, this mutant and another displayed preferential suppression of genomic over subgenomic RNA accumulation at both 24 and 34 degrees C. The combination of phenotypes observed suggests that the 2a protein may play a role in the differential initiation of specific classes of viral RNA in addition to a previously suggested role in RNA elongation.     

Temperature-Sensitive Mutants of a Chinese Hamster Cell Line. I. Selection of Clones with Defective Macromolecular Biosynthesis

Temperature-sensitive clones have been selected from a mutagenized culture of Chinese hamster lung cells by a procedure involving bromodeoxyuridine (BrdU) incorporation and irradiation with black light. The selection procedure used in these studies was adapted from methods developed by others to yield mutants that cease DNA replication within a short time after they are transferred to nonpermissive temperature. After mutagenesis with ethyl methanosulfonate ten clones survived the selection procedure. Three of the clones (mutants) were temperature-sensitive as measured by growth properties. Two mutants ceased DNA synthesis within six hours of being shifted to 39degrees and the third mutant continued to synthesize DNA at nonpermissive temperature at a reduced rate for at least 24 hours. Thus, all three mutants survived the selection procedure for understandable reasons, since each was unable to incorporate sufficient BrdU at 39degrees to lethally protosensitize its DNA during the standard exposure period. The two mutants that cease DNA synthesis at high temperature (clones 115-47 and 115-53) also stop incorporating radioactive amino acids and uridine within six hours at 39degrees. Their complex phenotype, i.e. defective DNA, RNA and protein biosynthesis, is reversible. When these mutants were returned to 33 degrees after 8 hours at 39 degrees, both resumed DNA synthesis immediately (less than 1 hour). Reversal of defective DNA synthesis in both mutants were sensitive to drugs that inhibit protein biosynthesis specifically. Those same drugs, as well as toxic amino acids analogs, also effected a striking mutant phenocopy in wild-type cells. The phenocopy produced by amino acid analogs that are incorporated into mammalian proteins suggested that one or more proteins must be synthesized continuously to support mammalian cells engaged in programmed DNA replication.