Marker rescue of temperature-sensitive mutations of vaccinia virus WR: correlation of genetic and physical maps

The physical map locations of 62 temperature-sensitive mutations of vaccinia virus WR have been determined by marker rescue experiments, using cloned HindIII fragments of wild-type DNA. Since vaccinia virus DNA is not infectious, marker rescue was performed by infecting monolayers of cells at the nonpermissive temperature with a low multiplicity of the mutant to be rescued and transfecting with calcium phosphate-precipitated recombinant DNA. Wild-type recombinants were measured by using either a direct plaque assay technique or a two-step procedure in which the final yield of virus from the transfected cells was assayed at the permissive and nonpermissive temperatures. Mutants that had been previously assigned to the same complementation-recombination group were rescued by the same HindIII fragment, with the exception of three mutants in one group that were rescued by either one of two adjacent fragments. A comparison between the genetic linkage map of the temperature-sensitive mutations in 30 mutants with their physical locations demonstrated that not only was the order of the genetic map correct but also recombination frequencies generally reflected actual physical distances.     

Isolation of vaccinia virus mutants capable of replicating independently of the host cell nucleus

alpha-Amanitin-resistant vaccinia virus mutants were isolated after serial viral passages in BSC-40 cells that were carried out in the presence of inhibitory levels (6 micrograms/ml) of alpha-amanitin. One such mutant, alpha-27, was highly refractory (greater than 95%) to alpha-amanitin-mediated inhibition and was selected for further study. In the absence of drug, the phenotypes of alpha-27 and wild-type vaccinia virus were indistinguishable with respect to growth kinetics. DNA synthesis, protein synthesis, and morphogenesis. Infections in the presence of alpha-amanitin revealed two striking differences, however. First, wild-type virus was unable to catalyze proteolytic processing of the two major capsid proteins VP62 and VP60, whereas alpha-27 was most efficient at this process. Second, wild-type viral morphogenesis within the infected cells was arrested by alpha-amanitin at an apparently analogous step to that previously described for enucleated cells. This observation was supported by the ability of alpha-27 virus to replicate in enucleated BSC-40 cells. Restriction enzyme analyses of alpha-27 versus wild-type genomes revealed that a XhoI cleavage site was altered in the alpha-27 DNA molecule, suggesting a possible location for the alpha-amanitin resistance locus.     

Physical mapping of two herpes simplex virus type 1 host shutoff loci: rescue of each ts mutation occurs with two unique cloned regions of the viral genome.

Two complementing temperature-sensitive (ts) herpes simplex virus type 1 (HSV-1) mutants, PAA1rts1 and ts199, were defective in viral DNA synthesis and in the shutoff of cellular macromolecular synthesis at 39.5 degrees C, the nonpermissive temperature. PAA1sts1 and PAA1rts1+ recombinants and PAA1rts1+ revertants were used to examine the contributions of the PAA1r mutation and the ts1 mutation of PAA1rts1 in affecting the levels of viral and cellular DNA synthesized at 34 and 39.5 degrees C. The results of this study suggests an interaction between the viral DNA polymerase and the ts1+ gene product during HSV-1 DNA replication and possibly in the inhibition of host DNA synthesis by HSV-1. Physical mapping of the ts mutations present in ts199 and the PAA1sts1 recombinant ts1-8 were performed by intratypic marker rescue experiments. Surprisingly, both the ts1-8 and ts199 mutations were rescued by two cloned fragments: ts1-8 by BglII-K (map coordinates 0.095 to 0.163) and BglII-I (map coordinates 0.314 to 0.417), while ts199 was rescued by BglII-K and BglII-O (map coordinates 0.163 to 0.197). In more refined mapping experiments, the regions between coordinates 0.347 to 0.378 and 0.126 to 0.163 were able to rescue the ts1-8 mutation. Southern hybridization analysis confirmed that the fragments that rescued ts1-8 and those that rescued ts199 had homology, as predicted by the physical mapping results.     

Fine-structure mapping of herpes simplex virus type 1 temperature-sensitive mutations within the short repeat region of the genome.

Cloned herpes simplex virus type 1 (HSV-1) DNA fragments were used to fine-structure map the temperature-sensitive (ts) lesions from four mutants, ts T, D, c75, and K, by marker rescue. These mutants all overproduced immediate-early viral polypeptides at the nonpermissive temperature. Although one of these viruses, ts K, gave a more restricted infected-cell polypeptide profile under these conditions than the other three, no complementation was detected between pairwise crosses of these mutants in the yield test. Recombination, however, was obtained between all mutant pairs except ts T and D. In physical mapping experiments, ts+ virus was recovered from cells coinfected with DNA of ts T, D, or c75 and BamHI fragment k from wild-type strain 17 HSV-1 DNA cloned in pAT153, whereas ts K was rescued by cloned HSV-1 BamHI-y. Both of these cloned DNA fragments contained sequences from the short repeat region of the HSV-1 genome. The ts mutations were more precisely mapped by marker rescue, using restriction enzyme fragments within BamHI-k and -y from cloned DNA. The smallest fragment able to rescue a mutant was 320 base pairs long. The order of the four mutations derived from these studies was consistent with the assignment by genetic recombination. All four lesions mapped within the coding sequences of the immediate-early polypeptide Vmw IE 175 (ICP4) which lie outside the "a" sequence. The results showed that mutations in different regions of the gene encoding Vmw IE 175 could produce similar phenotype effects at the nonpermissive temperature.     

Assay of noninfectious fragments of DNA of avian leukosis virus-infected cells by marker rescue.

A marker rescue assay of noninfectious fragments of avian leukosis virus DNAs is describe. DNA fragments were prepared either by sonication of EcoRI-digestion of DNAs of chicken cells infected with wild-type Rous sarcoma virus, with a nontransforming avian leukosis virus, and with a mutant of Rous sarcoma virus temperature sensitive for transformation. Recipient cultures of chicken embryo fibroblasts were treated with noninfectious DNA fragments and infected with temperature-sensitive mutants of Rous sarcoma virus defective in DNA polymerase or in an internal virion structural protein. Wild-type progeny viruses which replicated at the nonpermissive temperature were isolated. Some of the wild-type progeny acquired both the wild-type DNA polymerase and the subgroup specificity of the Rous sarcona virus strain used for preparation of sonicated or EcoRI-digested DNA fragments. Therefore the genetic markers for DNA polymerase and envelope were linked and appeared to be located on the same EcoRi fragment of the DNA of Rous sarcoma virus-infected cells.     

Mapping of the vaccinia virus DNA polymerase gene by marker rescue and cell-free translation of selected RNA

The previous demonstration that a phosphonoacetate (PAA)-resistant (PAAr) vaccinia virus mutant synthesized an altered DNA polymerase provided the key to mapping this gene. Marker rescue was performed in cells infected with wild-type PAA-sensitive (PAAs) vaccinia by transfecting with calcium phosphate-precipitated DNA from a PAAr mutant virus. Formation of PAAr recombinants was measured by plaque assay in the presence of PAA. Of the 12 HindIII fragments cloned in plasmid or cosmid vectors, only fragment E conferred the PAAr phenotype. Successive subcloning of the 15-kilobase HindIII fragment E localized the marker within a 7.5-kilobase BamHI-HindIII fragment and then within a 2.9-kilobase EcoRI fragment. When the latter was digested with ClaI, marker rescue was not detected, suggesting that the PAAr mutation mapped near a ClaI site. The sensitive ClaI site was identified by cloning partial ClaI-EcoRI fragments and testing them in the marker rescue assay. The location of the DNA polymerase gene, about 57 kilobases from the left end of the genome, was confirmed by cell-free translation of mRNA selected by hybridization to plasmids containing regions of PAAr vaccinia DNA active in marker rescue. A 100,000-dalton polypeptide that comigrated with authentic DNA polymerase was synthesized. Correspondence of the in vitro translation product with purified vaccinia DNA polymerase was established by peptide mapping.     

Vaccinia virus morphogenesis is blocked by a temperature-sensitive mutation in the I7 gene that encodes a virion component.

The ts16 mutation of vaccinia virus WR (R. C. Condit, A. Motyczka, and G. Spizz, Virology 128:429-443, 1983) has been mapped by marker rescue to the I7L open reading frame located within the genomic HindIII I DNA fragment. The I7 gene encodes a 423-amino-acid polypeptide. Thermolabile growth was attributed to an amino acid substitution, Pro-344-->Leu, in the predicted I7 protein. A normal temporal pattern of viral protein synthesis was elicited in cells infected with ts16 at the nonpermissive temperature (40 degrees C). Electron microscopy revealed a defect in virion assembly at 40 degrees C. Morphogenesis was arrested at a stage subsequent to formation of spherical immature particles. Western immunoblot analysis with antiserum directed against the I7 polypeptide demonstrated an immunoreactive 47-kDa polypeptide accumulating during the late phase of synchronous vaccinia virus infection. Immunoblotting of extracts of wild-type virions showed that the I7 protein is encapsidated within the virus core. The I7 polypeptide displays amino acid sequence similarity to the type II DNA topoisomerase of Saccharomyces cerevisiae.     

Temperature-sensitive vaccinia virus mutants identify a gene with an essential role in viral replication.

Vaccinia virus mutants ts2 and ts25, members of the same complementation group, exhibit a temperature-dependent arrest at the stage of viral DNA replication. The lesions responsible for the mutant phenotypes have been localized to the far left region of the HindIII B genomic fragment by marker rescue studies. Hybrid selection analyses established that the DNA fragments positive for rescue represented the first open reading frame of the HindIII B fragment and encoded a 30-kilodalton protein. The gene is expressed early after infection as a rightwardly transcribed 1-kilobase-pair mRNA whose coordinates were determined by S1 nuclease mapping. To further the phenotypic analysis of the mutants, the accumulation of viral DNA sequences during permissive and nonpermissive infections was quantitated. The extent of the DNA- phenotype was shown to vary in different cell types. In mouse L cells at either high or low multiplicity of infection, nonpermissive DNA synthesis was less than 5% of that seen in permissive infections. This severe defect was mirrored by correspondingly low viral yields. In infections of BSC40 monkey cells, however, the deficiencies in both DNA synthesis and virus production were far less severe. For one mutant (ts2), the temperature sensitivity in BSC40 cells varied inversely with the multiplicity of infection.     

Vaccinia virus morphogenesis is blocked by temperature-sensitive mutations in the F10 gene, which encodes protein kinase 2.

Four previously isolated temperature-sensitive (ts) mutants of vaccinia virus WR (ts28, ts54, ts61, and ts15) composing a single complementation group have been mapped by marker rescue to the F10 open reading frame located within the genomic HindIII F DNA fragment. Sequencing of the F10 gene from wild-type and mutant viruses revealed single-amino-acid substitutions in the F10 polypeptide responsible for thermolabile growth. Although the ts mutants displayed normal patterns of viral protein synthesis, electron microscopy revealed a profound morphogenetic defect at the nonpermissive temperature (40 degrees C). Virion assembly was arrested at an early stage, with scant formation of membrane crescents and no progression to normal spherical immature particles. The F10 gene encodes a 52-kDa serine/threonine protein kinase (S. Lin and S. S. Broyles, Proc. Natl. Acad. Sci. USA 91:7653-7657, 1994). We expressed a His-tagged version of the wild-type, ts54, and ts61 F10 polypeptides in bacteria and purified these proteins by sequential nickel affinity and phosphocellulose chromatography steps. The wild-type F10 protein kinase activity was characterized in detail by using casein as a phosphate acceptor. Whereas the wild-type and ts61 kinases displayed similar thermal inactivation profiles, the ts54 kinase was thermosensitive in vitro. These findings suggest that protein phosphorylation plays an essential role at an early stage of virion assembly.     

Cloning, sequencing and translation analysis of the Vaccinia virus LIVP HINDIII N genome fragment]

The sequence of vaccinia virus (VV) LIVP HindIII N DNA fragment has been determined to be 2215 b.p. Three open reading frames designated LN1, N1 and NO1 and coding polypeptides with the calculated molecular masses (32.5 kDa, 21.8 kDa and 47.8 kDa) were located. mRNAs selected by hybridization with the VV HindIII N were translated in rabbit reticulocyte lysate. Proteins of genes for host range and resistance to alpha-amanitin corresponding to 29 and 47 kDa were detected. Two forms of polypeptides of the ORF LN1 (32 and 29K), and anomalous electrophoresis mobility of the ORF LN1 are discussed.     

Properties of mammalian cells transformed by temperature-sensitive mutants of avian sarcoma virus.

Fibroblasts from European field vole (Microtus agrestis) and from normal rat kidney (NRK) have been infected by avian sarcoma virus mutants which are temperature-sensitive for the maintenance of transformation. These cells are transformed at 33 degrees C, but show normal cell characteristics in morphology, colony formation in agar, saturation density, sugar uptake and membrane proteins at 39 degrees C and 40 degrees C, the nonpermissive temperatures. Ts mutant virus was rescued from most of the ts transformed cell lines. NRK cells infected by avian sarcoma virus ts mutants and kept at the nonpermissive temperature can be transformed by wild-type avian sarcoma virus. The susceptibility of the temperature-sensitive NRK lines to this transformation is higher than the susceptibility of uninfected NRK at either permissive or nonpermissive temperature.     

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.