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.     

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.     

Isolation and genetic characterization of temperature-sensitive mutants of vaccinia virus WR.

One hundred temperature-sensitive mutants of vaccinia virus WR were isolated from virus that had been mutagenized with 5-bromodeoxyuridine or N-methyl-N'-nitro-N-nitrosoguanidine. A rapid screening procedure based on the ability of vaccinia virus to form plaques under liquid overlay medium was used to identify potential mutants among randomly picked plaque isolates or plaques preselected for their small size after temperature shift-up. The preselection technique resulted in a sixfold increase in the number of successful mutant isolations relative to the number of plaques picked. All of the mutants had efficiencies of plating at 39.5 degrees C relative to that at 33 degrees C of 10(-4) or less, and 33 of 40 produced 10% or less of the amount of virus at the nonpermissive temperature (39.5 degrees C) relative to that at the permissive temperature (33 degrees C). Experiments with the fluorescent DNA binding dye Hoechst 33258 demonstrated that 6 of the 100 mutants failed to form characteristic cytoplasmic DNA factories at 39.5 degrees C. To facilitate the functional grouping of such a large number of mutants, a rapid infectious center assay was developed. Thirty of the mutants were assigned to 16 or 17 complementation-recombination groups by using this assay. Recombination experiments have allowed the construction of a genetic map representing 22 mutants in 12 of these groups.     

Molecular genetic analysis of vaccinia virus DNA polymerase mutants.

To further our understanding of the structure and function of the vaccinia virus DNA polymerase, we have performed fine genetic analysis of three mutants with lesions in the polymerase gene. By performing marker rescue analysis with DNA fragments of decreasing size, each lesion was localized to within 500 base pairs of DNA. The relevant regions of the mutant alleles were then cloned and subjected to DNA sequence analysis, which allowed the assignment of a single nucleotide and amino acid change to each mutant. As well as providing structure-function correlations germane to an understanding of polymerase activity, these data have provided insights into the frequency and possible mechanisms of viral homologous recombination.     

Intramolecular homologous recombination in cells infected with temperature-sensitive mutants of vaccinia virus.

I have used a plasmid containing two copies of the Saccharmyces cerevisiae his3 gene to study intramolecular homologous recombination in vaccina virus-infected cells. Recombination of the plasmid was monitored by restriction enzyme digestion and Southern blot hybridization in cells infected with representatives from each of 32 complementation groups of temperature-sensitive mutants ts42 and ts17 did not replicate nor detectably recombine the input plasmid. All except one of the mutants that synthesized normal amounts of viral DNA and protein replicated and recombined the plasmid in a manner indistinguishable from wild-type virus. The remaining mutant, ts13, only poorly replicated and recombined the input plasmid. Thus, the processes of replication and recombination could not be separated by using this battery of mutants. Viral mutants defective in late protein synthesis were unable to resolve the vaccinia virus concatemer junction in plasmids but carried out intramolecular homologous recombination with plasmids as efficiently as did wild-type virus at the conditionally lethal temperature. This result distinguishes homologous recombination, which requires early gene products, from resolution of concatemer junctions, which requires additional late gene products.     

Growth complementation of influenza virus temperature-sensitive mutants in mouse cells which express the RNA polymerase and nucleoprotein genes.

In order to establish cell lines which complement the growth of temperature-sensitive (ts) mutants of influenza virus, three RNA polymerase and nucleoprotein (NP) genes each linked to the mouse mammary tumor virus LTR were cloned into the bovine papillomavirus vector DNA. After co-transfection of mouse C127 cells with these recombinant plasmids, a cell line, clone 76, in which the expression of the three polymerase and NP genes could be stimulated by dexamethasone, was established. The clone 76 cells could complement the growth of ts-mutants defective in one of the polymerase subunit genes at the nonpermissive temperature in response to dexamethasone. The results suggest that the simultaneous expression of the three polymerase genes in the same compartment of protein synthesis machinery is required for an efficient complementation of ts-mutant growth.     

Isolation and characterization of temperature-sensitive RNA polymerase II mutants of Saccharomyces cerevisiae.

Three independent, recessive, temperature-sensitive (Ts-) conditional lethal mutations in the largest subunit of Saccharomyces cerevisiae RNA polymerase II (RNAP II) have been isolated after replacement of a portion of the wild-type gene (RPO21) by a mutagenized fragment of the cloned gene. Measurements of cell growth, viability, and total RNA and protein synthesis showed that rpo21-1, rpo21-2, and rpo21-3 mutations caused a slow shutoff of RNAP II activity in cells shifted to the nonpermissive temperature (39 degrees C). Each mutant displayed a distinct phenotype, and one of the mutant enzymes (rpo21-1) was completely deficient in RNAP II activity in vitro. RNAP I and RNAP III in vitro activities were not affected. These results were consistent with the notion that the genetic lesions affect RNAP II assembly or holoenzyme stability. DNA sequencing revealed that in each case the mutations involved nonconservative amino acid substitutions, resulting in charge changes. The lesions harbored by all three rpo21 Ts- alleles lie in DNA sequence domains that are highly conserved among genes that encode the largest subunits of RNAP from a variety of eucaryotes; one mutation lies in a possible Zn2+ binding domain.     

Fine structure mapping of an avian tumor virus RNA by immunoelectron microscopy.

The RNA of a deleted strain (lacking Src gene) of an avian sarcoma virus (ASV) was examined by a newly developed immunoelectron microscopic procedure which uses anti-nucleotide antibodies as probes. After denaturation of the RNA and reaction with a high affinity, highly specific anti-7-methylguanosine-5'-phosphate (anti-pm 7G), 81% of 106 molecules examined were found to have antibody at one terminus, in agreement with the presence of a pm 7G cap in ASV-RNA. Hapten inhibition by pm 7G could be demonstrated. Experiments with anti-A and with anti-poly A gave results consistent with the known structure of ASV-RNA, in particular the presence of a 3' poly A tail. These studies illustrate the feasibility of using anti-nucleotide antibodies in a combined immunochemical and electron microscopic study of the fine structure of nucleic acids.     

Quantification of DNA-dependent RNA polymerase subunits and initiation factor(s) by antibody-linked polymerase assays

The antibody-linked polymerase assay is a method which allows one to assign RNA polymerase activity to SDS-denatured polypeptides on nitrocellulose membranes using antibodies which were raised against only partially purified polymerase preparations. Here we show that with this method not only enzyme subunits but also initiation factor(s) can be determined in crude homogenates. Moreover the determination is quantitative. Therefore changes in the amount of individual polymerase subunits and factor(s) can be visualized within different crude homogenates.