Showing papers on "RNA-dependent RNA polymerase published in 1977"

Covalent linkage of a protein to a defined nucleotide sequence at the 5'-terminus of virion and replicative intermediate RNAs of poliovirus.

Abstract: The 5'-terminus of poliovirus polyribosomal RNA is pUp. A candidate for the 5'-terminus of poliovirion RNA was recovered as a compound migrating toward the cathode when 32P-labeled virion RNA was completely digested with ribonucleases T1, T2 and A and analyzed by paper ionophoresis at pH 3.5. Treatment with proteinase K reversed its direction of migration, indicating the presence of protein. Treatment with venom phosphodiesterase liberated all of the radioactivity as pUp, suggesting that poliovirion RNA has a protein-pUp 5'-terminus. Treatment of virion RNA with T1 ribonuclease alone generated a proteinase K-sensitive oligoribonucleotide. Analysis of the oligoribonucleotide using ribonucleases A and U2 showed its structure to be protein-pU-U-A-A-A-A-C-A-G. Digests of replicative intermediate RNA contained sufficient protein-pUp to suggest that this structure is at the 5'-end of most nascent poliovirus RNA molecules. We suggest that a protein-nucleotide structure acts as a primer for initiating synthesis of poliovirus RNA.

Cell Transformation by RNA Tumor Viruses

Abstract: Along with other carcinogens of physical or chemical origin, viruses are known to be associated with and to cause tumors in a variety of experimental animals. RNA tumor viruses in particular are widespread in many species of animals, and frequently cause sarcomas or leukemia. The isolation of fowl sarcoma-leukemia virus in the early 1910s by a number of investigators marked the first successful identification of such tumor viruses (Ellermann and Bang, 1909; Rous, 1911; Fujinami and Inamoto, 1914). The cell-virus systems used for the studies of basic aspects of the pathogenesis of avian tumor viruses illustrate the progress in methodology for studying animal viruses in general. Early work in animal hosts was gradually replaced by a system using the chorioallantoic membrane of eggs (Keogh, 1938), then by tissue culture cells (Manaker and Groupe, 1956). The establishment of an assay system for Rous sarcoma virus (RSV) in tissue culture cells (Temin and Rubin, 1958) eventually led to an era of quantitative studies on the mechanism of cellular alteration by viruses.

The location of the polio genome protein in viral RNAs and its implication for RNA synthesis.

Abstract: Evidence is presented that a small protein (VPg) is covalently attached to the 5′-terminal oligonucleotide VPg–pU-U–A–A–A–A–C–A–Gp of the polio genome, to nascent strands of the polio replicative intermediate and to poly(U) of minus strands. A model of polio RNA replication is proposed implicating VPg in initiation of RNA synthesis, possibly as primer.

Size and genetic content of viral RNAs in avian oncovirus-infected cells.

Abstract: Viral complementary DNA (cDNA) sequences corresponding to the gag, pol, env, src, and c regions of the Rous sarcoma virus genome were selected by hybridizing viral cDNA to RNA from viruses that lack the env or src gene or to polyadenylic acid [poly(A)]-containing RNA fragments of different lengths and isolating either hybridized or unhybridized DNA. The specificities, genetic complexities, and map locations of the selected cDNA's were shown to be in good agreement with the size and map locations of the corresponding viral genes. Analyses of virus-specific RNA, using the specific cDNA's as molecular probes, demonstrated that oncovirus-infected cells contained genome-length (30-40S) RNA plus either one or two species of subgenome-length viral RNA. The size and genetic content of these RNAs varied, depending on the genetic makeup of the infecting virus, but in each case the smaller RNAs contained only sequences located near the 3' end of the viral genome. Three RNA species were detected in Schmidt-Ruppin Rous sarcoma virus-infected cells: 39S (genome-length) RNA; 28S RNA, with an apparent sequence of env-src-c-poly(A); and 21S RNA, with an apparent sequence of src-c-poly(A). Cells infected with the Bryan high-titer strain of Rous sarcoma virus, which lacks the env gene, contained genome-length (35S) RNA and 21S src-specific RNA, but not the 28S RNA species. Leukosis virus-infected cells contained two detectable RNA species: 35S (genome-length) RNA and 21S RNA, with apparent sequence env-c-poly(A). Since gag and pol sequences were detected only in genome-length RNAs, it seems likely that the full-length transcripts function as mRNA for these two genes. The 28S and 21S RNAs could be the active messengers for the env and src genes. Analyses of sequence homologies among nucleic acids of different avian oncoviruses demonstrated substantial similarities within most of the genetic regions of these viruses. However, the "common" region of Rous-associated virus-0, an endogenous virus, was found to differ significantly from that of the other viruses tested.

Transcription termination at the trp operon attenuators of Escherichia coli and Salmonella typhimurium: RNA secondary structure and regulation of termination.

Abstract: Transcription termination at the attenuators of the trp operons of Escherichia coli and Salmonella typhimurium was studied in vitro using DNA restriction fragments as templates. Readthrough transcription beyond the terminators occurred with 5 and 30% efficiency, respectively, in E. coli and S. typhimurium. This difference is correlated with the stability of proposed secondary structures of the respective trp leader transcripts. Secondary structure analyses of the two leader transcripts revealed a well-conserved pattern of RNA base paring. This and the possibility that trp leader RNA is translated suggest a model for regulation of transcription termination that is based on ribosome movement along the RNA and a shift between alternative RNA base-pairing configuration.

The 5'-terminal structures of poliovirion RNA and poliovirus mRNA differ only in the genome-linked protein VPg.

Abstract: The 5'-terminal, RNase T1-resistant oligonucleotide of poliovirus mRNA has been isolated. Its sequence is pU-U-A-A-A-A-C-A-Gp, which is identical to that of virion RNA except that the genome-linked protein VPg is absent [Nomoto, A., Detjen, B., Pozzatti, R. & Wimmer, E. (1977) Nature 268, 208-213]. Because all newly synthesized viral RNAs are VPg-linked, we propose that VPg is cleaved from progeny RNA at the linkage between protein and nucleic acid prior to polyribosome formation. This may represent a new mode of processing of viral macromolecules. Virion RNA from which VPg has been cleaved proteolytically retains its specific infectivity, an observation suggesting that VPg is not involved in early steps (penetration and translation) of the infectious cycle initiated by RNA.

Nature of inhibitor of cell-free protein synthesis formed in response to interferon and double-stranded RNA.

Abstract: PROTEIN synthesis in cell-free systems from mouse L-cells pretreated with the antiviral agent interferon1 shows an enhanced sensitivity to inhibition by double-stranded RNA (dsRNA) (refs 2–4). A dsRNA-dependent protein kinase5–7 and a heat-stable, low-molecular-weight inhibitor (LMW inhibitor) of protein synthesis which is formed in such systems on incubation with ATP and dsRNA (ref. 7), seem likely to be involved. We have shown8 that the LMW inhibitor can be conveniently synthesised using a highly-purified enzyme fraction from interferon-treated cells bound to dsRNA on an inert support. Here we report its partial characterisation.

Evidence that herpes simplex virus DNA is transcribed by cellular RNA polymerase B.

Abstract: In herpes simplex virus type 1 (HSV-1)-infected HEp-2 cells, amanitin added before or at various times after infection always reduced viral multiplication. Also, the three waves of transcription of HSV-1 DNA, which led to the synthesis of alpha, beta-, and gamma-polypeptides, were all sensitive to amanitin in HEp-2 cells, and the amanitin-sensitive RNA polymerase activities of isolated nuclei were equally sensitive to the inhibitor before and during the infection. On the contrary, HSV-1 DNA transcription was totally unaffected by amanitin in AR1/9-5B cells, a mutant subline of CHO cells that possesses an amanitin-resistant RNA polymerase B. Together, these results strongly suggest that HSV-1 DNA utilizes for its transcription a polymerase undistinguishable from host cell RNA polymerase B with respect to its sensitivity to amanitin.

Specific cleavage of ribosomal RNA caused by alpha sarcin.

Abstract: Alpha sarcin causes the specific cleavage of RNA from 80S ribosomes and 60S subunits of yeast, but not from the 40S subunits to produce a small RNA fragment. The fragment was also produced on treatment of the 60S subunits of wheat germ ribosomes. The fragment has a molecular weight of 100,000 and is a cleavage product of the large RNA species in the 60S subunits. The fragment is not derived from the 5'end of the yeast 25S RNA nor does it bind to 5.8S RNA and we propose that the fragment represents the 3' terminal 320 nucleotides of 25S rRNA. The ability to produce fragment could not be separated from the ability of alpha sarcin to inhibit protein synthesis. Alpha sarcin also causes the specific cleavage of the 23S RNA of the E. coli subunit to produce a smaller fragment of RNA than that produced from eukaryote ribosomes.

Characterization of the autoregulation of simian virus 40 gene A.

Abstract: Cells infected by tsA mutants of simian virus 40 (SV40) overproduce early RNA. Overproduction results from failure of the temperature-sensitive A protein (T antigen) to inhibit early transcription. The amount of early RNA in the cytoplasm, determined quantitatively from the kinetics of hybridization to labeled complementary SV40 DNA, was elevated at both permissive (32°C) and nonpermissive (41°C) temperatures in all the early mutants tested (tsA7, -30, -58, and -209), but not in the late mutant tsB4. The amount of early RNA in a culture maintained at 32°C for 72 h and then shifted to 41°C was maximum when each cell was infected initially with at least one plaque-forming unit of tsA58. Azidocytidine (2′-deoxy-2′-azidocytidine), which inhibits initiation of DNA synthesis, did not cause overproduction of early RNA in cells infected with wild-type SV40, showing that the effect seen with tsA mutants is not due to interference with initiation of DNA synthesis per se. In parallel infections at 41°C, the amount of early RNA per copy of viral DNA was as much as 2,000 times greater with tsA58 than with wild-type SV40, even though there was no replication of the tsA58 DNA. Synthesis of late RNA could not be detected during the first 20 h of an infection by either virus at 32°C, indicating that late and early transcription are under different control. In three cell lines transformed by tsA mutants, the amount of early RNA increased moderately after a shift from 32 to 41°C, whereas with homologous cells transformed by wild-type virus, the amount of early RNA decreased, indicating that the A protein may be able to repress transcription of integrated SV40 DNA. All the observations are consistent with a simple model in which the binding of A protein at the origin of replication blocks either binding of RNA polymerase to the early promoter or its progress through the early gene(s).

Regulation of Early and Late Simian Virus 40 Transcription: Overproduction of Early Viral RNA in the Absence of a Functional T-Antigen

Abstract: Virus-specific RNA synthesized in monkey cells after infection by both wild-type simian virus 40 (SV40) and the early SV40 temperature-sensitive mutant tsA58 has been analyzed. The fraction of SV40-specific RNA increased throughout infection with either wild-type SV40 or with tsA58 in direct proportion to the accumulation of progeny DNA molecules, suggesting their role in the late transcriptional process. Cytoplasmic fractions from cells infected at various temperatures (31.5 to 41°C) by wild-type virus and harvested 48 h later contained 4 to 8% virus-specific RNA, of which 5 to 10% was early SV40 RNA. In contrast, though 5 to 8% of the cytoplasmic RNA from tsA 58-infected cells incubated at 31.5 to 37°C for 48 h was virus specific, the percentage of early virus-specific RNA ranged from 25 to 80% as the incubation temperature increased. In tsA58-infected cultures incubated for 48 h at 41°C (a temperature at which essentially no tsA 58 DNA synthesis occurred), only 0.4% of the cytoplasmic RNA was virus specific, but at least 90% of this RNA was early. In experiments where cells were inoculated at 32°C and shifted at 48 h postinfection to 40°C for various times, the percentage of virus-specific pulse-labeled RNA varied from 3.5 to 10.0%. Of the virus-specific RNA, early SV40 RNA ranged from 14 to 65% in tsA 58-infected cultures. Analogous studies with Sarkosyl-extracted viral transcription complexes to incorporate label into nascent (unprocessed) viral RNA yielded essentially identical results. This finding strongly suggests that the overproduction of early SV40 RNA occurs at the level of synthesis. While cytosine arabinoside effectively terminated most viral DNA replication in wild-type-infected cells, the ratio of early to late viral RNA remained less than 1:9. These results demonstrate that: (1) the amount of virus-specific RNA synthesized depends directly on the amount of viral DNA available for use as templates; once viral DNA replication has occurred, presumably providing progeny SV40 DNA molecules for templates, the level of transcription remains high; (ii) termination of viral DNA replication does not terminate late SV40 transcription; (iii) early SV40 RNA is overproduced by tsA 58 at all temperatures, but especially at higher temperatures; and (iv) overproduction of early SV40 RNA appears to be correlated with defectiveness of the tsA mutant T-antigen. These results suggest that T-antigen may regulate its own production either by repressing the synthesis of early viral RNA or by stimulating the synthesis of late SV40 RNA or both.

Novel mechanism for RNA maturation: the leader sequences of simian virus 40 mRNA are not transcribed adjacent to the coding sequences

Abstract: The 5'-terminal 100-200 ribonucleotides of late simian virus 40 (SV40) mRNAs are not transcribed immediately adjacent to their coding sequences. This conclusion is based on the following observations. The major late SV40 cytoplasmic RNA species, 16S and 19S, were purified from poly(A)-containing cytoplasmic RNA by hybridization to and elution from an SV40 DNA fragment that maps between 0.67 and 0.76. This fragment is remote from the DNA fragments that include the coding sequences. The RNA transcripts from the fragment located between 0.67 and 0.76 were found in abundance. Even though selected on oligo(dT)-cellulose columns, the 5'-terminal sequences did not contain poly(A) tails directly adjacent to their 3' termini. The 5' terminus of the 16S mRNA, as monitored by hybridization of the sequences adjacent to the "cap" structure, was found adjacent to the coding sequences when intact [3H]methyl-labeled RNA was hybridized with restriction fragments. However, after fragmentation, the methyl label of this same RNA hybridized with a fragment that is remote from the coding sequences and maps between 0.67 and 0.73. These results imply a novel mechanism for biosynthesis of SV40 mRNA.

The RNA of avian acute leukemia virus MC29

Abstract: The RNA of myelocytoma virus MC29, a replication-defective avian acute leukemia virus, was investigated Sedimentation and electrophoretic analyses indicated that the virus contains a distinct 28S RNA with about 5700 nucleotides It is the smallest avian tumor virus RNA detected to date The small size of the RNA suggests that the defectiveness of the virus is due to deletions in replicative genes The RNA shared 3 to 5 of 30 large RNase T1-resistant oligonucleotides with the RNA of other avian leukosis and sarcoma and may represent the transforming information of the virus Sequences of the conserved transforming gene of avian sarcoma viruses were not detected in MC29 RNA define a new class of avian tumor viral transforming genes

Translation of 35S and of subgenomic regions of avian sarcoma virus RNA

Abstract: Rabbit antiserum monospecific for an internal structural protein, p27, of avian sarcoma viruses (ASV) was found to immunoprecipitate polypeptides with molecular weights (Mr) of 180,000 and 76,000 from cell-free reticulocyte lysates programmed by ASV 35S RNA and also from lysates of ASV-infected cells. In addition, the Mr 180,000 protein was also precipitated by antiserum raised against virion DNA polymerase, suggesting that is a product of the two genes nearest the 5' end of virion 35S RNA. We have also investigated the ability of subgenomic portions of virion RNA to program cell-free protein synthesis. A 10-12S poly(A)-containing fragment of RNA from both nondefective and transformation-defective ASV directed the synthesis of a polypeptide of Mr 29,000 immunologically unrelated to the gs antigens; 20-24S poly(A)-containing RNA from nondefective ASV directed the synthesis of a polypeptide of Mr 60,000 not found when a similar RNA preparation from transformation-defective ASV was translated, suggesting that it is the product of the ASV src gene. These results indicate that internal initiation sites for protein synthesis exist on the 35S RNA genome.

Selective and accurate transcription of the Xenopus laevis 5S RNA genes in isolated chromatin by purified RNA polymerase III.

Abstract: Chromatin isolated from immature oocytes was found to contain an endogenous RNA polymerase activity (RNA nucleotidyltransferase; nucleoside triphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) that synthesizes predominately 5S RNA. However, the levels of total RNA synthesis and 5S RNA synthesis in chromatin were each stimulated 10- to 50-fold by an exogenous RNA polymerase III purified from X. laevis oocytes. The 5S genes in chromatin were transcribed by the exogenous enzyme in a highly selective (3000-fold above random) and predominately asymmetric fashion. A significant fraction of 5S RNA sequences were also found in a discrete transcript, approximately 5S in size. Total RNA synthesis was significantly stimulated when chromatin was transcribed by oocyte RNA polymerase I, murine RNA polymerase II, and low levels of Escherichia coli RNA polymerase. However, these enzymes did not significantly stimulate 5S RNA synthesis above the endogenous levels. Both homologous oocyte RNA polymerase I and III and E. coli RNA polymerase transcribed the 5S genes in deproteinized DNA to approximately the same extent (severalfold above random) and both the sense and anti-sense strands of the gene were transcribed. It appears, therefore, that both chromatin-associated components and a purified RNA polymerase III are necessary and sufficient for the selective and accurate transcription of the 5S RNA genes in vitro.

Steroid induction of mouse mammary tumor virus: effect upon synthesis and degradation of viral RNA.

Abstract: Steroid hormones have been demonstrated to induce in tissue culture the production of mouse mammary tumor viral (MMTV) RNA, proteins, and particles 10-fold compared with constitutive levels. However, previous data of increased viral RNA levels did not distinguish between an increased rate of viral-specific RNA synthesis and a slower rate of viral RNA degradation. According to the recently developed assay of Coffin et al. (1974) for measuring rates of viral RNA synthesis, short-term labeling experiments of a mouse mammary tumor cell line indicate that the glucocorticoid hormone dexamethasone stimulates a 3-fold increase in the synthesis of MMTV-specific RNA within 10 min after the addition of hormone and that stimulation of RNA synthesis reaches 5- to 10-fold within 30 to 60 min, while the synthesis of Moloney leukemia virus-specific RNA in the same cell is unaffected by steroids. The decay rates of pulse-labeled and accumulated MMTV RNA in the presence or absence of dexamethasone show this RNA to have a half-life of greater than 8 h. In addition, hormone-stimulated MMTV RNA appears to have an increased rate of decay compared to basal MMTV RNA, thus ruling out an increased stability of MMTV RNA in the presence of steroid hormones as the basis for increased RNA levels. Thus, the magnitude, rapidity, and specificity of hormone action on MMTV RNA synthesis indicate a primary effect upon transcription.

Anatomy of herpes simplex virus DNA VII. alpha-RNA is homologous to noncontiguous sites in both the L and S components of viral DNA.

Abstract: Previous reports from this laboratory (Honess and Roizman, 1974) have operationally defined alpha polypeptides as the viral proteins that are synthesized first in HEp-2 cells treated with cycloheximide from the time of infection with herpes simplex virus type 1 until the withdrawal of the drug 12 to 15 h after infection. It has also been shown that the viral RNA (designated alpha RNA) that accumulates in the cytoplasm during cycloheximide treatment and on polyribosomes immediately upon withdrawal of the drug is homologous to 10 to 12% of viral DNA, whereas the viral RNA accumulating in the cytoplasm of untreated cells at 8 to 14 h after infection is homologous to 43% of viral DNA (Kozak and Roizman, 1974). In the present study, alpha RNA and cytoplasmic RNA extracted from untreated cells 8 h after infection were each hybridized in liquid to in vitro labeled restriction endonuclease fragments generated by cleavage of herpes simplex virus type 1 DNA with Hsu I, with Bgl II, and with both enzymes simultaneously. The data show that only a subset of the fragments hybridized to alpha RNA, and these are scattered within both the L and S components of the DNA. There are at least five noncontiguous regions in the DNA homologous to alpha RNA; two of these are located partially within the reiterated sequences in the S component. All fragments tested hybridized more extensively with 8-h cytoplasmic RNA than with alpha RNA. Four adjacent fragments, corresponding to 30% of the DNA and mapping within the L component, hybridized exclusively with the cytoplasmic RNA extracted from cells 8 h after infection.

Genetic variation in the RNA transcripts of endogenous virus genes in uninfected chicken cells.

Abstract: Uninfected cells from two different phenotypes of chicken embryos express significant amounts of endogenous viral information, though they do not produce virus particles. Cells of the phenotype gs(+)chf(+) are positive for both group-specific (gs) antigens and chicken helper factor (chf) activity, whereas cells of a second phenotype, gs(L)chf(+)(h(E)), demonstrate noncoordinate expression of these two viral activities (very low amounts of gs antigens, but extremely high helper activity). RNA from these cells was analyzed to determine the size, genetic content, and relative abundance of virus-specific RNAs in cells of each phenotype. Two major size classes of polyadenylic acid-containing RNA, homologous to the avian leukosis virus genome, were detectable in cells of both types. The larger RNA, which contained most of the sequences of the leukosis virus genome, was of different sizes in the two phenotypes, 31S in gs(+)chf(+) cells but 35S in the noncoordinate cell type. Analysis of the viral RNA with gene-specific complementary DNA probes revealed the following characteristics. (i) The 31S RNA appeared to lack portions of the gag and pol genes. (ii) A smaller RNA species, which sedimented at 21S in both cell types, was a transcript of the 3'-proximal portion of the viral genome, consisting of the env gene and the "common" sequences. (iii) The amount of env-specific RNA in the 21S region was more than six times higher in the noncoordinate cell type than in the gs(+)chf(+) cells; this difference was concordant with the 5- to 10-fold higher chf activity in the noncoordinate cells. (iv) The endogenous viral RNA in uninfected cells and the RNA from Rous-associated virus-0 virions hybridized only partially with DNA complementary to the common region of the Rous-associated virus-2 genome, whereas the RNA of all exogenous viruses tested hybridized almost completely to this complementary DNA. Small amounts of src-specific polyadenylated RNA were also present in uninfected chicken cells. This RNA sedimented as a single peak at 26S and was not covalently linked to any other identifiable virus-specific RNA sequences. The amount of src RNA was the same in the above two types of expression-positive cells and also in cells that were gs(-)chf(-), indicating that the transcription of the cellular sequences homologous to the src gene is independent of the transcription of the other endogenous viral genes.