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.     

Fine mapping and molecular cloning of mutations in the herpes simplex virus DNA polymerase locus.

Mutations in five phenotypically distinct mutants derived from herpes simplex virus type 1 strain KOS which lie in or near the herpes simplex virus DNA polymerase (pol) locus have been fine mapped with the aid of cloned fragments of mutant and wild-type viral DNAs to distinct restriction fragments of 1.1 kilobase pairs (kbp) or less. DNA sequences containing a mutation or mutations conferring resistance to the antiviral drugs phosphonoacetic acid, acyclovir, and arabinosyladenine of pol mutant PAAr5 have been cloned as a 27-kbp Bg+II fragment in Escherichia coli. These drug resistance markers have been mapped more finely in marker transfer experiments to a 1.1-kbp fragment (coordinates 0.427 to 0.434). In intratypic marker rescue experiments, temperature-sensitive (ts), phosphonoacetic acid resistance, and acyclovir resistance markers of pol mutant tsD9 were mapped to a 0.8-kbp fragment at the left end of the EcoRI M fragment (coordinates 0.422 to 0.427). The ts mutation of pol mutant tsC4 maps within a 0.3-kbp sequence (coordinates 0.420 to 0.422), whereas that of tsC7 lies within the 1.1-kbp fragment immediately to the left (coordinates 0.413 to 0.420). tsC4 displays the novel phenotype of hypersensitivity to phosphonoacetic acid; however, the phosphonoacetic acid hypersensitivity phenotype is almost certainly not due to the mutation(s) conferring temperature sensitivity. The ts mutation of mutant tsN20--which does not affect DNA polymerase activity--maps to a 0.5-kbp fragment at the right-hand end of the EcoRI M fragment (coordinates 0.445 to 0.448). The mapping of the mutations in these five mutants further defines the limits of the pol locus and separates mutations differentially affecting catalytic functions of the polymerase.     

Mutations in the herpes simplex virus DNA polymerase gene can confer resistance to 9-beta-D-arabinofuranosyladenine.

Mutants of herpes simplex virus type 1 resistant to the antiviral drug 9-beta-D-arabinofuranosyladenine (araA) have been isolated and characterized. AraA-resistant mutants can be isolated readily and appear at an appreciable frequency in low-passage stocks of wild-type virus. Of 13 newly isolated mutants, at least 11 were also resistant to phosphonoacetic acid (PAA). Of four previously described PAA-resistant mutants, two exhibited substantial araA resistance. The araA resistance phenotype of one of these mutants, PAAr5, has been mapped to the HpaI-B fragment of herpes simplex virus DNA by marker transfer, and araA resistance behaved in marker transfer experiments as if it were closely linked to PAA resistance, a recognized marker for the viral DNA polymerase locus. PAAr5 induced viral DNA polymerase activity which was much less susceptible to inhibition by the triphosphate derivative of araA than was wild-type DNA polymerase. These genetic and biochemical data indicate that the herpes simplex virus DNA polymerase gene is a locus which, when mutated, can confer resistance to araA and thus that the herpes simplex virus DNA polymerase is a target for this antiviral drug.     

DNA-dependent RNA polymerase subunits encoded within the vaccinia virus genome.

Antiserum to a multisubunit DNA-dependent RNA polymerase from vaccinia virions was prepared to carry out genetic studies. This antiserum selectively inhibited the activity of the viral polymerase but had no effect on calf thymus RNA polymerase II. The specificity of the antiserum was further demonstrated by immunoprecipitation of RNA polymerase subunits from dissociated virus particles. The presence in vaccinia virus-infected cells of mRNA that encodes the polymerase subunits was determined by in vitro translation. Immunoprecipitable polypeptides with Mrs of about 135,000, 128,000, 36,000, 34,000, 31,000, 23,000, 21,000, 20,000, and 17,000 were made when early mRNA was added to reticulocyte extracts. The subunits were encoded within the vaccinia virus genome, as demonstrated by translation of early mRNA that hybridized to vaccinia virus DNA. The locations of the subunit genes were determined initially by hybridization of RNA to a series of overlapping 40-kilobase-pair DNA fragments that were cloned in a cosmid vector. Further mapping was achieved with cloned HindIII restriction fragments. Results of these studies indicated that RNA polymerase subunit genes are transcribed early in infection and are distributed within the highly conserved central portion of the poxvirus genome in HindIII fragments E, J, H, D, and A.     

Mapping the genomic location of the gene encoding alpha-amanitin resistance in vaccinia virus mutants.

To facilitate the determination of the genomic location of the vaccinia virus gene(s) encoding alpha-amanitin resistance (alpha r) (Villarreal et al., J. Virol. 51:359-366, 1984), a collection of alpha r, temperature-sensitive (ts) mutants were isolated. The premise of these experiments was that mutants might be found whose dual phenotypes were the result of a single or two closely linked mutations. Genetic analyses of the alpha rts mutant library revealed two mutants, alpha rts7 and alpha rts12, that apparently fit this criterion; in alpha rts7 the two lesions were indistinguishable, whereas in alpha rts12 the two mutations were closely linked but separable. Cloned vaccinia virus HindIII DNA fragments were used to marker rescue the temperature-sensitive phenotype of these two dual mutants. The temperature-sensitive lesion of alpha rts7 was rescued by the HindIII N fragment (1.5 kilobases), whereas alpha rts12 was rescued by the neighboring HindIII M fragment (2.0 kilobases). The progeny virions of the alpha rts7 HindIII-N rescue reverted to an alpha-amanitin-sensitive phenotype, whereas the alpha rts12 HindIII-M progeny were still resistant to the drug. Taken together, these data indicate that the gene encoding alpha-amanitin resistance maps to the HindIII N fragment and provides evidence for the existence of essential vaccinia virus genes in a region of the genome previously believed to be nonessential for replication in tissue culture. Biochemical analyses revealed that both mutants were capable of synthesizing DNA as well as early and late viral proteins at the permissive and nonpermissive temperatures. At the nonpermissive temperature alpha rts12 and alpha rts7 were unable to process the major core precursors P94 and P65 into VP62 and VP60.     

A single-base change within the DNA polymerase locus of herpes simplex virus type 2 can confer resistance to aphidicolin.

An aphidicolin-resistant (Aphr) mutant of herpes simplex virus (HSV) type 2 strain 186 previously has been shown to induce an altered viral DNA polymerase that is more resistant to aphidicolin and more sensitive to phosphonoacetic acid (PAA) than is wild-type DNA polymerase. In this study the mutation responsible for the aphidicolin-resistant phenotype was physically mapped by marker transfer experiments. The physical map limits for the Aphr mutation were contained in a 1.1-kilobase pair region within the HSV DNA polymerase locus. The 1.1-kilobase-pair fragment of the Aphr mutant also conferred hypersensitivity to PAA, and DNA sequence analysis revealed an AT to GC transition within this fragment of the Aphr mutant. Analysis of the three potential open reading frames within the 1,147-base-pair fragment and comparison with the amino acid sequence of DNA polymerase of HSV type 1 indicated that the Aphr mutant polymerase had an amino acid substitution from a tyrosine to a histidine in the well-conserved region of the DNA polymerase. These results indicate that this single amino acid change can confer altered sensitivity to aphidicolin and PAA and suggest that this region may form a domain that contains the binding sites for substrates, PPi, and aphidicolin.     

Genetic characterization of the vaccinia virus DNA polymerase: cytosine arabinoside resistance requires a variable lesion conferring phosphonoacetate resistance in conjunction with an invariant mutation localized to the 3'-5' exonuclease domain.

In this report, we describe the isolation, molecular genetic mapping, and phenotypic characterization of vaccinia virus mutants resistant to cytosine arabinoside (araC) and phosphonoacetic acid (PAA). At 37 degrees C, 8 microM araC was found to prevent macroscopic plaque formation by wild-type virus and to cause a 10(4)-fold reduction in viral yield. Mutants resistant to 8 microM araC were selected by serial passage of a chemically mutagenized viral stock in the presence of drug. Because recovery of mutants required that initial passages be performed under less stringent selective conditions, and because plaque-purified isolates were found to be cross-resistant to 200 micrograms of PAA per ml, it seemed likely that resistance to araC required more than one genetic lesion. This hypothesis was confirmed by genetic and physical mapping of the responsible mutations. PAAr was accorded by the acquisition of one of three G-A transitions in the DNA polymerase gene which individually alter cysteine 356 to tyrosine, glycine 372 to aspartic acid, or glycine 380 to serine. AraCr was found to require one of these substitutions plus an additional T-C transition within codon 171 of the DNA polymerase gene, a change which replaces the wild-type phenylalanine with serine. Congenic viral stocks carrying one of the three PAAr lesions, either alone or in conjunction with the upstream araCr lesion, in an otherwise wild-type background were generated. The PAAr mutations conferred nearly complete resistance to PAA, a slight degree of resistance to araC, hypersensitivity to aphidicolin, and decreased spontaneous mutation frequency. Addition of the mutation at codon 171 significantly augmented araC resistance and aphidicolin hypersensitivity but caused no further change in mutation frequency. Several lines of evidence suggest that the PAAr mutations primarily affect the deoxynucleoside triphosphate-binding site, whereas the codon 171 mutation, lying within a conserved motif associated with 3'-5' exonuclease function, is postulated to affect the proofreading exonuclease of the DNA polymerase.     

Marker rescue of endogenous cellular genetic information related to the avian leukosis virus gene encoding RNA-directed DNA polymerase.

Endogenous cellular genetic information related to the avian leukosis virus gene encoding RNA-directed DNA polymerase was studied, using a marker rescue assay to detect biological activity of subgenomic fragments of virus-related DNAs of uninfected avian cells. Recipient cultures of chicken embryo fibroblasts were treated with sonicated DNA fragments and were infected with a temperature-sensitive mutant of Rous sarcoma virus that encoded a thermolabile DNA polymerase. Wild-type progeny viruses were isolated by marker rescue with fragments of DNA of uninfected chicken, pheasant, quail, and turkey cells. The DNAs of these uninfected avian cells, therefore, appeared to contain endogenous genetic information related to the avian leukosis virus DNA polymerase gene.     

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.     

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.     

A cowpox virus gene required for multiplication in Chinese hamster ovary cells.

Cowpox virus, in contrast to vaccinia virus, can multiply in Chinese hamster ovary cells. To study the genetic basis for this difference in host range, recombinants between vaccinia and cowpox viruses were isolated and their DNA restriction patterns were examined. The ability to multiply in Chinese hamster ovary cells could be correlated with the conservation of cowpox virus sequences mapping at the left end of the genome. This was further demonstrated by marker rescue of the host range phenotype with restricted cowpox virus DNA. Marker rescue with cloned restriction fragments of decreasing size enabled the fine localization of the host range function to a 2.3-kilobase-pair fragment. Nucleotide sequencing revealed that the fragment encoded a single major polypeptide of approximately 77,000 daltons. It is suggested that the role of the host range gene from cowpox virus is to prevent the early and extensive shutoff of protein synthesis that normally occurs in Chinese hamster ovary cells infected by vaccinia virus.     

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.     

Physical mapping of DNA-temperature-sensitive mutations of vaccinia virus

Four DNA-temperature-sensitive (ts) mutations were mapped in the genome of vaccinia virus (VV). Physical mapping of these mutations was performed by restriction analysis of the genomes of recombinants between VV DNA- ts mutants and ectromelia virus as well as by the marker rescue with cloned restriction fragments of VV DNA. One of the mutations was mapped on the HindIII-E-fragment. Biochemical studies of this mutant indicate that the mutation is not in the DNA polymerase gene which is located on the same fragment. The other three mutations were mapped in a 10 kilobase region in the middle of the HindIII-D-fragment. As shown previously, these mutations inactivate different genes, and the products of these genes participate directly in the DNA synthesis. Thus, at least three proteins involved in the VV DNA synthesis are encoded by neighboring genes in the central part of the viral genome.     

Transcriptional and translational mapping and nucleotide sequence analysis of a vaccinia virus gene encoding the precursor of the major core polypeptide 4b

We prepared antiserum that reacted with a major core polypeptide of approximately 62,000 daltons (62K polypeptide), designated 4b, and its 74K precursor, designated P4b. A cell-free translation product of vaccinia virus late mRNA that comigrated with P4b was specifically immunoprecipitated. The late mRNA encoding P4b hybridized to restriction fragments derived from the left end of the HindIII A fragment and to a lesser extent from the right side of the HindIII D fragment. A polypeptide that comigrated with P4a, the precursor of another major core polypeptide, was synthesized by mRNA that hybridized to DNA segments upstream of the P4b gene. Complete nucleotide sequence analysis of the P4b gene revealed an open reading frame, entirely within the HindIII A fragment, that was sufficient to encode a 644-amino-acid polypeptide of 73K. The 5' end of the P4b mRNA was located at or just above the translational initiation site.