EC:2.7.7.48 - FACTA Search

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Query: EC:2.7.7.48 (transcriptase)
9,479 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The extraction of a template-dependent and template-specific RNA-dependent RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) from a eukaryotic source is described. The enzyme, extracted from barley leaves infected with brome mosaic virus (BMV), is capable of incorporating high levels of radioactivity into trichloroacetic acid-insoluble products. The purification procedure included solubilization with nonionic detergent and precipitation with polyethylene glycol. The enzyme was more than 50 times more active than was a comparable preparation from mock-inoculated leaves and was stimulated more than 15-fold by the addition of BMV RNA to the reaction. Other viral RNA templates were less than 25% as efficient as was BMV RNA in stimulating UMP incorporation; poly(A), tRNA, and mRNA gave little stimulation and rRNA was inactive. Autoradiographic analysis after electrophoretic separation of the radioactive products from reaction mixtures containing BMV RNA template revealed prominent bands that coelectrophoresed with replicative forms of BMV RNAs. When BMV RNA template was enriched in RNA3 or RNA4, larger proportions of the products were replicative forms of RNA3 or RNA4, respectively.
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PMID:Highly active template-specific RNA-dependent RNA polymerase from barley leaves infected with brome mosaic virus. 29 12

Ionizing radiation markedly alters the response of the reovirus transcriptase unblocking mechanism to stimulation by K+ ions, which normally trigger the switch-on of transcription in this system. In irradiated subviral particles the concentration of K+ ions needed to trigger switch-on is reduced in a dose-dependent way. The observed alteration of switch-on characteristics appears to correlate with alteration of the electrophoretic behaviour of a single major polypeptide species. These observations have important implications for understanding some of the effects of ionizing radiation on cells, most notably the induction of both latent virus and cell differentiation.
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PMID:Ionizing radiation perturbs the switch-on of transcriptase in a model transcription complex in vitro. 31 20

Phage SP RNA-dependent RNA polymerase (SP replicase) was purified from Escherichia coli infected with RNA phage SP. The enzyme was found to be composed of four non-identical polypeptides, i.e. subunits I, II, III, and IV and molecular weights of 74,000, 69,000, 47,000, and 36,000 daltons, respectively. As in the case of phage Qbeta replicase, the largest polypeptide is identical with the ribosomal protein S1, and subunits III and IV with polypeptide chain elongation factors EF-Tu and EF-ts, respectively.. This is based on the behaviour of the subunits on SDS-polyacrylamide gel electrophoresis, isoelectric focusing and immunological cross-reaction. Subunits I, III, and IV of SP replicase are derived from the host cell, while subunit II is coded by phage RNA genome. The striking coincidence of the composition and entity of the structural components of SP replicase with those of Qbeta replicase may indicate the structural and functional requirements of host-derived polypeptides in RNA replicase. The binding activity of S1 (in 70S ribosome comples) to poly (U) is retained in SP replicase complex. In contrast, the GDP binding activity of EF-Tu is masked in SP replicase. It is concluded that S1 is required functionally whereas EF-Tu.EF-Ts are required structurally in RNA replicase.
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PMID:Identification of host-derived subunits of phage SP RNA-dependent RNA polymerase (SP replicase). 36 4

A modified form of Bacillus subtilis RNA polymerase containing a phage SP01-coded regulatory protein (the gene 28 product) selectively transcribes "middle" genes of the phage genome in vitro. In this paper, we identify a subset of restriction endonuclease fragments of SP01 DNA that promote specific transcription by the phage-modified polymerase. In the absence of nucleoside triphosphates, RNA polymerase containing the gene 28 protein selectively binds to these DNA fragments thereby forming stable binary complexes that can be isolated on nitrocellulose filters. In contrast, unmodified RNA polymerase containing sigma factor selectively binds to and transcribes a subset of phage DNA fragments that contain "early" sequences and that are in large part distinct from the fragments recognized by the phage-modified transcriptase. Our results strongly suggest that phage "early" and "middle" genes are transcribed from distinct promoters and that the RNA polymerase containing the gene 28 protein binds to sites that are located at or near promoters for SP01 "middle" genes.
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PMID:Promoter recognition by phage SP01-modified RNA polymerase. 41 6

Present epidemic influenza is uncontrolled by immuno- or chemoprophylaxis. Mutants of varying antigenic composition arise with relatively high frequency in nature and are able to circumvent herd, or induced, immunity. Also, drug-resistant viruses can be selected in vitro and this resistance can be exchanged to other viruses by gene reassortment. Combined immuno- and chemoprophylaxis may provide a more effective approach to the ultimate control of the disease. Most antiviral compounds have been selected by random screening in the laboratory. Application of more specific enzyme assays such as the virion-associated RNA transcriptase assays may produce other compounds with a defined mode of action - semi-rational chemotherapy. RNA and polypeptide sequence studies are in progress elsewhere to define transcription and translation initiation sites or virus adsorption sites. Such knowledge could lead to a new generation of antiviral compounds. Specific delivery of virus inhibitory compounds is an interesting problem. Liposomes are lipid spheres, and these have been used for the delivery of antiviral compounds.
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PMID:Approaches towards rational antiviral chemotherapy. 46 Dec 75

Recombinants of human influenza type A viruses, A/Krasnodar/101/1959 (H2N2) or A/Habarovsk/15/1976 (H3N2), and fowl plague virus (FPV), strain Weybridge (Hav1Neq1) were obtained. The genome of the recombinant obtained by recombination of influenza A/Habarovsk/15/1976 virus and FPV contained the genes 4 (HA) and 6 (NA) derived from the influenza A/Habarovsk virus and all the other genes [1, 2, 3, 5 (NP), 7 (M), 8 (NS)] from FPV. The genome of the recombinant of A/Krasnodar/101/1959 virus and FPV contained the genes 2, 4 (HA) and 6 (NA) derived from influenza A/Krasnodar virus and all the other genes [1, 3, 5, (NP), 7 (M), 8 (NS)] from FPV. The recombinants, like FPV, gave high virus yields in chick embryos and could multiply at high temperatures (40 and 42 degrees C), but, like human influenza viruses, were non-pathogenic for chickens and did not replicate in chick embryo fibroblast culture, but did replicate in a human conjunctiva cell line, clone 1-5C-4. The virion transcriptase of the recombinants, in a number of properties determined in vitro, was similar to FPV transcriptase but not to the human influenza virus enzyme.
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PMID:Investigation of recombinants of human influenza and fowl plague viruses. 47 41

The in vivo primary and secondary transcription capabilities of wild-type snowshoe hare (SSH) virus and certain of its temperature-sensitive (ts) mutants have been analyzed. The results obtained agree with in vitro studies (Bouloy et al., C.R. Acad. Sci. Paris 280:213-215, 1975; M. Bouloy and C. Hannoun, Virology 69:258-264, 1976; M. Ranki and R. Pettersson, J. Virol. 16:1420-1425, 1975) which have shown that bunyaviruses are negative-stranded RNA viruses with a virion RNA-directed RNA polymerase. The in vivo transcription studies have demonstrated that in the presence of protein synthesis inhibitors (puromycin or cycloheximide) SSH virus can synthesize viral complementary RNA (primary transcription) throughout the infection cycle. The increased levels of viral complementary RNA obtained in the absence of protein synthesis inhibitors (secondary transcription) were not markedly reduced if cells were pretreated with actinomycin D (5 mug/ml), alpha-amanitin (25 mug/ml), or rifampin (100 mug/ml), although progeny virus yields were reduced by up to 80% in the actinomycin D- and rifampin-treated cells. The in vivo transcription capabilities of SSH group I ts mutants at temperatures which were nonpermissive (40 degrees C) for virus replication gave values comparable to those obtained at permissive temperatures (33 degrees C). The SSH group I mutants appear, therefore, to be RNA-positive mutant types. When compared with their transcription capabilities at 33 degrees C, the in vivo transcription abilities of four SSH group II ts mutants (and one double group I/II ts mutant) were found to be more impaired at 40 degrees C than those of the SSH group I ts mutants or wild-type SSH virus at 40 degrees C, although the viral complementary RNA synthetic capabilities of these group II (and group I/II) mutants at 40 degrees C were significantly higher than their primary transcription capabilities (as measured at 33 degrees C in the presence of puromycin or cycloheximide). It was concluded, therefore, that these SSH group II (and double group I/II) ts mutants have an intermediate RNA phenotype. Hybridization studies using (32)P-labeled individual L, M, and S viral RNA species of SSH virus have demonstrated the presence of viral complementary RNA to all three species in extracts of cells infected with SSH ts II-30 and incubated at 33 degrees C (primary and secondary transcription) or 40 degrees C, a nonpermissive temperature for its replication. The results of pulse-labeled in vivo protein analyses indicated that greater quantities of intracellular N protein (coded for by S RNA [J. R. Gentsch and D. H. L. Bishop, J. Virol. 28:417-419, 1978]) than G1 and G2 polypeptides (coded for by M RNA [J. R. Gentsch and D. H. L. Bishop, J. Virol. 30:767-776, 1979]) were present in extracts of cells infected with wild-type SSH virus. In extracts of SSH group I, II, or I/II ts mutant-infected cells incubated at 33 degrees C, N and G1, and for the group II mutant-infected cells, G2, viral polypeptides were detected, whereas in extracts obtained from group I or II mutant virus-infected cells incubated at 40 degrees C, low levels of N and G1 polypeptides were evident.
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PMID:In vivo transcription and protein synthesis capabilities of bunyaviruses: wild-type snowshoe hare virus and its temperature-sensitive group I, group II, and group I/II mutants. 48 Apr 77

The family Rhabdoviridae comprises approximately 75 viruses infecting vertebrates, invertebrates and plants. The main characteristics of the member viruses are: (i) the viruses infecting vertebrates and invertebrates are bullet-shaped and the viruses infecting plants are usually bacilliform; (ii) the viruses have particle lengths varying from 130 to 380 nm and widths varying from 60 to 95 nm; (iii) the viruses possess unit-membrane envelopes from which protrude spikes 5 to 10 nm long; (iv) the viruses have precisely coiled helical nuecleocapsids with a diameter of approx. 50 nm; (v) most of the viruses which have been studied contain 5 proteins; the prototype, vesicular stomatitis virus, contains proteins designated L (large), G (glycoprotein), N (nucleoprotein), NS (nonstructural) and M (matrix); N or NS is phosphorylated in most members which have been studied; (vi) the viruses contain single-stranded RNA which is transcribed into several messenger RNA species with sizes corresponding to the structural proteins; (vii) the nucleocapsid contains the RNA-dependent RNA polymerase and is infectious; and (viii) many of the viruses produce morphologically distinct defective-interfering (T) particles.
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PMID:Rhabdoviridae. Report of the Rhabdovirus Study Group, International Committee on Taxonomy of Viruses. 50 Mar 29

The state of the secondary structure of RNA and proteins comprising nucleoids (cores) and RNP of influenza virus was evaluated comparatively. The identity of RNA conformation in these particles and differences from free RNA conformation due to less marked secondary structure were found. Core proteins were predominantly represented by the beta-framework, and RNP as an alpha-helix. The specific transcriptase activity of the core is significantly lower than RNP activity of influenza virus.
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PMID:[Characteristics of the structural organization and transcriptase activity of the influenza virus nucleoid]. 50 99

Reovirus mRNA's containing a 5'-terminal methylated cap structure (m(7)GpppG(m)) were shown to be effective primers for influenza viral RNA transcription in vitro catalyzed by the influenza virion transcriptase. Priming activity required the presence of methyl groups in the cap since reovirus mRNA's with 5'-terminal GpppG were inactive as primers. Both the cap and internal nucleotides were physically transferred from radiolabeled reovirus mRNA to influenza viral complementary RNA (cRNA) during transcription in vitro. By using reovirus mRNA's with methyl-(3)H-labeled caps as primers, we showed that the influenza viral cRNA synthesized in the presence of unlabeled nucleoside triphosphates contained [methyl-(3)H]m(7)GpppG(m), identical to that found in the reovirus mRNA primer. To demonstrate transfer of internal residues, reovirus mRNA's synthesized in the presence of all four alpha-(32)P-labeled ribonucleoside triphosphates were used as primers. The resulting influenza viral cRNA was (32)P-labeled. Diethyl-aminoethyl-Sephadex chromatography of the RNase T2 digest of this cRNA demonstrated (32)P radiolabel in both internal residues (charge -2) and the cap (charge -4.6). Approximately 25 internal nucleotides along with the cap of reovirus mRNA were transferred to each chain of influenza viral cRNA. Gel electrophoretic analysis indicated that the segments of influenza viral cRNA primed by reovirus mRNA were approximately the same size as those primed by a different mRNA, globin mRNA, strongly suggesting that the influenza virion transcriptase complex transfers approximately the same number of nucleotides plus the cap from different mRNA primers to the 5' end of influenza viral RNA transcripts.
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PMID:Cap and internal nucleotides of reovirus mRNA primers are incorporated into influenza viral complementary RNA during transcription in vitro. 51 5

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