EC:2.7.7.48 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

In the presence of Mg(2+) and a specific primer, ApG or GpG, the influenza WSN virion transcriptase synthesizes large, polyadenylic acid-containing complementary RNA (cRNA) (Plotch and Krug, J. Virol., 21:24-34, 1977). After removal of its polyadenylic acid with RNase H in the presence of polydeoxythymidylic acid, the in vitro cRNA distributed into seven discrete bands during electrophoresis in acrylamide gels containing 6 M urea. The eight known segments of virion RNA (vRNA) also distributed into seven bands under these conditions as two, rather than the expected three, large-sized segments were resolved. Each of the in vitro cRNA segments migrated slightly faster than the corresponding vRNA segment. To determine whether this difference in mobility reflects a difference in size between cRNA and vRNA, the double-stranded RNA formed by annealing labeled in vitro cRNA to unlabeled vRNA was subjected to various nuclease treatments and was analyzed by gel electrophoresis. Hybrids treated with RNase T2 or a combination of RNase T2 and RNase H migrated slightly faster than those treated only with RNase H, indicating that RNase T2 removed an RNA sequence other than polyadenylic acid, most probably a short sequence of vRNA not hydrogen bonded to cRNA. These results suggest that the in vitro cRNA segments are shorter than, and thus incomplete transcripts of the corresponding vRNA segments. All eight hybrids were resolved by gel electrophoresis, indicating that all eight vRNA segments are transcribed into cRNA in vitro. We also present evidence suggesting that the ApG primer initiates in vitro transcription exactly at the 3' end of vRNA.
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PMID:Segments of influenza virus complementary RNA synthesized in vitro. 62 84

Human coronavirus RNA, prepared by extraction of purified virions with phenol-chloroform, consists of a major 15 to 55S class and a minor 4S class of RNA fragments. Polyadenylic acid [poly (A)] sequences are present in 15 to 55S but not in 4S RNA, suggesting different functions for each class. A stretch of poly (A) of approximately 19 adenosine monophosphate residues was obtained in sizing experiments after digesting OC-43 RNA with pancreatic and T1 ribonucleases. An OC-43 virion RNA transcriptase could not be detected with systems optimal for detecting the transcriptases of influenza and Newcastle disease virus.
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PMID:Presence of genomic polyadenylate and absence of detectable virion transcriptase in human coronavirus OC-43. 64 31

In the presence of Mg(2+) and a specific dinucleotide primer (ApG or GpG), the influenza virion transcriptase synthesizes the eight discrete segments of complementary RNA (cRNA) containing polyadenylic acid (Plotch and Krug, J. Virol. 21:24-34, 1977). Virions were examined for their ability to cap and methylate cRNA containing di- or triphosphorylated 5' termini. By using the primers ppApG, pppApG, or ppGpG, viral cRNA was synthesized in vitro with [alpha-(32)P]-GTP and S-[methyl-(3)H]adenosylmethionine as labeled precursors. DEAE-Sephadex chromatography of the RNase T2 digest of the cRNA product demonstrated no (3)H incorporation at all and the absence of a (32)P-labeled cap structure. The 5' terminus of ppApG-primed cRNA could be capped and methylated by enzymes from vaccinia virus, indicating that the two 5'-terminal phosphates derived from the primer were preserved in the product cRNA. The cap structure formed by the vaccinia enzymes and released by RNase T2 digestion as m(7)GpppA(m)pGp was radioactively labeled at its 3'-terminal phosphate only when [alpha-(32)P]CTP was used as the labeled precursor during transcription. This indicates that the 5'-terminal sequence of the cRNA is ppApGpC and that, therefore, ppApG most probably initiates transcription exactly at the 3' GpCpU(OH) terminus of the virion RNA templates. Virions were also tested for their ability to cap and methylate ppApG in the absence of transcription. No such activities were detected, whereas under the same conditions the vaccinia virus enzymes successfully capped and methylated this compound. Consequently, these experiments, together with those reported earlier, have not detected in influenza virions any capping and methylating enzymes active on the 5'-initiated termini of viral cRNA chains synthesized in vitro, whether these termini possess one, two, or three phosphates. Some mechanism for capping and methylation of viral cRNA must, however, exist, because the viral mRNA (cRNA) synthesized in the infected cell contains 5'-terminal methylated cap structures (Krug et al., J. Virol. 20:45-53, 1976). Possible mechanisms are discussed.
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PMID:Absence of detectable capping and methylating enzymes in influenza virions. 70 57

The influenza virion transcriptase is capable of synthesizing in vitro complementary RNA (cRNA) that is similar in several characteristics to the cRNA synthesized in the infected cell, which is the viral mRNA. Most of the in vitro cRNA is large (approximately 2.5 X 10(5) to 10(6) daltons), similar in size to in vivo cRNA. The in vitro transcripts initiate in adenosine (A) or guanosine (G) at the 5' end, as also appears to be the case with in vivo cRNA (R.M. Krug et al., 1976). The in vitro transcripts contain covalently linked polyadenylate [poly(A)] sequences, which are longer and more heterogeneous than the poly(A) sequences found on in vivo cRNA. The synthesis in vitro of cRNA with these characteristics requires both the proper divalent cation, Mg2+, and a specific dinulceside monophosphage (DNMP), ApG or GpG. These DNMPs stimulate cRNA synthesis about 100-fold in the presence of Mg2+ and act as primers to initiate RNA chains, as demonstrated by the fact that the 5'-phosphorylated derivatives of these DNMP's, 32pApG or 32pGpG, are incroporated at the 5' end of the product RNA. The RNA synthesized in vitro differs from in vivo cRNA in that neither capping nor methylation of the in vitro transcripts has been detected. The virion does contain a methylase activity, as shown by its ability to methylate exogenous methyl-deficient Escherichia coli tRNA.
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PMID:Influenza virion transcriptase: synthesis in vitro of large, polyadenylic acid-containing complementary RNA. 83 24

Temperature-sensitive mutants of WSN influenza virus (10, 11, 12) were tested in vitro for activity of the virion RNA-dependent RNA transcriptase at various temperatures. Temperature-sensitivity was found for virion transcriptase activity of mutants belonging to complementation/recombination group I, but not groups II, IV and V. It was not possible on the basis of the results to specify the precise biochemical lesion of mutants from group III.
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PMID:Temperature-sensitive virion transcriptase activity in mutants of WSN influenza virus. 99 15

An anti-influenza preparation, rimantadine (alpha-methyl-1-adamantane methylamine hydrochloride) at concentrations of 10--25 mkg/ml depresses the RNA-dependent RNA polymerase induction in a culture of cells infected with influenza virus (fowl plague virus). The inhibitory effect is also observed 2 hours following cell infection. In vitro studies have demonstrated that rimantadine has no effect on the activity of virus-induced RNA-dependent RNA polymerase, as well as on that of RNA-dependent RNA polymerase associated with virus particles.
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PMID:[Inhibitory effect of alpha-methyl-1-adamantane methylamine hydrochloride (rimantadine) on RNA-dependent RNA polymerase induction in culture of cells, infected with influenza virus]. 102 84

A comparative study of the in vitro reaction kinetics of the virion RNA polymerase of influenza A strains WS and WSN was conducted to establish phenotypic differences for enzyme activity that might be exchanged as genetic markers among recombinants of these viruses. Characteristically, the RNA polymerase activity of WS virus showed an initial rate of synthesis about two- to threefold higher than that of WSN when assayed at 32 C. The two strains were also distinguishable by comparing the transcription rates of each strain at 32 and 37 C. The initial rate of WS was invariably higher at 37 than at 32 C, whereas the opposite was found with WSN. When a series of recombinants obtained from mixed infections with the WS and WSN viruses were examined for virion transcriptase activity, it was found that the two polymerase related markers behaved as properties which segregated independently of each other and of additional nonselective markers that were scored. Seven temperature-sensitive mutants of WSN virus representing distinct recombination-complementation groups were found to show a diminished transcriptase activity as compared to wild-type virus, and one of these clones (ts 24) was largely deficient for this function. None of these mutants appeared to possess a heat-liable virion polymerase.
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PMID:Virion-associated transcriptase activity of influenza recombinant and mutant strains. 115 93

Influenza WSN virus temperature-sensitive (ts) mutants were examined for defects in viral complementary RNA (cRNA) synthesis. The synthesis of viral cRNA was determined by hybridizing RNA from infected cells to radiolabeled virion RNA of known specific activity. Mutants in complementation groups I and III synthesized little, or no, cRNA at the nonpermissive temperature (39.5 C). When cells infected by these mutants were incubated for 5 h at the permissive temperature (33 C) and were then shifted to 39.5 C, net synthesis of cRNA ceased. This strongly suggests that mutants in these two complementation groups possess a ts defect in the transciptase complex. Mutants in group II and group V synthesize reduced amounts of cRNA at 39.5 C. In contrast to the group I and group III mutants, cRNA synthesis in cells infected by a group II or a group V mutant continues after a shift-up. This indicated that these mutants do not possess a ts transcriptase complex and that these mutants are most probably defective in some step in the amplification of cRNA synthesis. As will be discussed, the most likely defect in these mutants is in the synthesis of virion-type RNA. These results suggest that there are two influenza viral gene functions required for transcription and most likely two additional gene functions required for RNA replication.
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PMID:Temperature-sensitive mutants of influenza WSN virus defective in virus-specific RNA synthesis. 116 95

Influenza virus RNA polymerase catalyzes multiple step reactions in transcription and replication of the genome RNA. The core enzyme is composed of each one of the three P proteins, PB1, PB2 and PA (Honda et al. (1990) J. Biochem. 107, 624-628). For detailed analysis of the role of each P protein and of the functional domains on each P polypeptide, we expressed individual P proteins in cultured insect cells after infection with recombinant baculoviruses. PB1 and PB2 accumulated in cell nuclei whereas PA stayed in cytoplasm. Both the PB1 and PB2 proteins were purified from aggregates in the respective nuclear extract, and the PA was partially purified from the cytoplasm. RNA polymerase was reconstituted by mixing the three P proteins in a urea solution and then dialyzing against a reconstitution buffer. The reconstituted enzyme was able to transcribe model RNA templates. Minus-sense RNA was a better template than plus-sense RNA.
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PMID:Reconstitution of influenza virus RNA polymerase from three subunits expressed using recombinant baculovirus system. 162 19

Several antitumor substances that effectively inhibited the growth of ascites and solid tumor cells transplanted in mice were isolated from pine cone NaOH extract by acid- and ethanol-precipitation. These antitumor substances were also potent antiviral agents against human immunodeficiency virus, herpes simplex virus and influenza virus; they induced antimicrobial activity against Staphylococcal aureus, Escherichia coli, Pseudomonas aeruginosa, Klebsiella pneumoniae and Candida albicans, and induced antiparasite activity against Hymenolepis nana in mice. Chemical analysis of these substances by IR, UV, NMR, ESR and partition chromatography on cellulose-TLC plate disclosed that they had lignin-related structures complexed with sugars or polysaccharides. Chlorinated decomposition of the lignin portion significantly reduced their antiviral activity. In agreement with this, the antiviral activity of synthesized lignins prepared by polymerization of phenylpropanoid precursors was comparable to that of the undecomposed counterparts of the pine cone extract. Acid hydrolysis of the polysaccharide portion significantly reduced the ability of the substances to induce antitumor and antimicrobial activities in mice. With an appropriate eliciting agent, intravenous administration of natural lignified substances transiently induced endogenous production of a cytotoxic factor (possibly tumor necrosis factor) in normal mice. Their priming activity was significantly higher than that of their component units or degradation products. These data suggest the importance of conjugating lignins with polysaccharides for in vivo expression of various kinds of immunopotentiating activity. As possible explanations for their induction of a variety of immunopotentiating activities, these natural and synthetic lignins stimulated macrophage NBT-reducing activity, polymorphonuclear cell (PMN) iodination and splenocyte DNA synthesis and inhibited poly (ADP-ribose) glycohydrolase, RNA-dependent DNA polymerase (reverse transcriptase) and RNA-dependent RNA polymerase activities.
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PMID:Antitumor, antiviral and immunopotentiating activities of pine cone extracts: potential medicinal efficacy of natural and synthetic lignin-related materials (review). 164 35

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