EC:3.1.26.4 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.26.4 (RNase H)
2,751 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Three forms of the RNA-dependent DNA polymerase were isolated from highly purified avian sarcoma virus B77 grown in duck embryo fibroblasts, using sequential chromatography on DEAE-cellulose, phosphocellulose, and poly(U)-cellulose. One form, which sedimented with about 5.2 S, contained only one species of polypeptide, with a molecular weight of 63,000; a second sedimented with about 7.8 S and contained only one species of polypeptide with a molecular weight of 81,000; and a third form, which sedimented with about 7.3 S, contained two species of polypeptides with molecular weights of 63,000 and 81,000. The molecular constitution of the three enzyme forms were therefore alpha, beta2, and alphabeta. All three possessed almost the same specific activity with poly(rA)-oligo(dT) as the primer-template. Forms alpha and alphabeta of avian sarcoma virus DNA polymerase have already been described in the literature; form beta2 is a new form. All three forms possessed ribonuclease H activity, the relative specific activities of the alpha, beta2, and alphabeta forms being about 1:4:5. All three enzyme forms were inhibited by antiserum to the alphabeta form, but whereas the alpha and alphabeta forms could be inhibited about 95%, the maximum degree of inhibition of the beta2 form was about 80%. The three enzyme forms also differed with respect to heat stability at 46 degrees, the monomeric alpha form of the enzyme being only about one-half as stable as the two dimeric forms.
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PMID:RNA-dependent DNA polymerase of avian sarcoma virus B77. I. Isolation and partial characterization of the alpha, beta2, and alphabeta forms of the enzyme. 6 34

We have investigated the use of oligodeoxycytidylic acid [oligo(dC)] as a primer for the initiation of DNA synthesis by the avian retrovirus reverse transcriptase in vitro, employing the viral RNA genome as template. The addition of oligo(dC)(12-18) to viral 35S RNA results in a stimulation of DNA synthesis by the viral RNA-directed DNA polymerase comparable to that observed when oligo(dT) is employed as a primer. Under similar conditions neither oligo(dA)(12-18) nor oligo(dG)(12-18) was active as primer for transcription of the avian retrovirus genome. Several different approaches have been employed to localize the oligo(dC)(12-18) binding site on the viral genome, including isolation of poly(A)-containing fragments, competition hybridization, and RNase H hydrolysis. These analyses indicate that oligo(dC)(12-18) binds to a site approximately 2,000 to 3,000 nucleotides from the 3' terminus of the genome of transforming strains of avian sarcoma viruses and approximately 700 to 1,000 nucleotides from the 3' terminus of nontransforming avian retroviruses. Therefore, the major site of initiation of DNA synthesis by oligo(dC)(12-18) appears to be in the vicinity of the 3' end of the env gene and the 5' end of the src gene, although the presence of minor initiation sites located elsewhere on the viral genome cannot be excluded by these data. Characterization of oligonucleotides after pancreatic RNase hydrolysis and poly(C)-Sepharose chromatography of viral RNA directly demonstrates the presence of oligoguanylic acid residues in the avian sarcoma virus genome. DNA sequences transcribed from the oligo(dC) primer appear to be conserved in all of the avian leukosis-sarcoma viruses tested. The use of oligo(dC) as a tool for the production of specific complementary DNA probes is discussed.
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PMID:Initiation of DNA synthesis by the avian retrovirus reverse transcriptase in vitro: nature and location of the oligodeoxycytidylic acid primer binding site. 9 Jan 58

Two mutants of avian sarcoma virus which exhibit different phenotypes have been analyzed for the properties of their RNA-dependent DNA polymerase and RNase H activities. LA 338 is a complex multiple mutant with at least one lesioneach in transformation and replication functions. The purified RNA-dependent DNA polymerase-RNase H complex from the mutant is twofold more thermolabile than that from the wild-type parent. A peculiarity of this mutant is that the ability of the enzyme to respond to synthetic template-primers is lost more rapidly than is the response to native RNA as template. The mutant enzyme cannot be protected from inactivation by the addition of synthetic template-primers. LA 672 represents a different phenotype among reverse transciptase mutant, showing a "late"-acting block in replication which affects only production of progeny by infected cells grown at the nonpermissive temperature. The purified DNA polymerase-RNase H complex of LA 672 is not thermolabile; rather, progeny grown at the nonpermissive temperature yield purified enzyme with a 20-fold-reduced specific activity in both DNA polymerase and RNase H. The content of reverse transcriptase protein in such noninfectious progeny, furthermore, did not appear to be significantly diminished since immunologically active enzyme could be demonstrated in a competition test for anti-reverse transcriptase antibody and since beta and alpha subunits of reverse transcriptase could be identified after polyacrylamide gel electrophoresis of partially purified enzyme preparations. The amounts of beta and alpha from the mutant were about twofold lower.
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PMID:Two avian sarcoma virus mutants with defects in the DNA polymerase-RNase H complex. 9 85

The 5'-terminal nucleotide sequences of the avian sarcoma virus (ASV) genome are transcribed by the reverse transcriptase in vitro into a DNA transcript that represents the entire distance ( approximately 100 nucleotides) between the tRNA(Trp) primer molecule and the 5' terminus. We have used these DNA(100) transcripts in hybridization reactions with ASV-specific RNA from infected avian cells and find nucleotide sequences complementary to these transcripts on all of the various size classes of viral mRNA identified. Similar hybridization results were obtained with a specific DNA transcript complementary to viral genomic nucleotide sequences between the tRNA(Trp) primer molecule and up to, but not including, the terminal redundant sequences (DNA(70)), indicating that the observed hybridization of DNA(100) to all size classes of viral RNA in infected cells did not reflect hybridization of DNA(100) to the terminal redundant sequences at the 3' end of the viral genome. Escherichia coli RNase H hydrolysis of RNA.DNA hybrids consisting of genomic 35S RNA obtained from virus and DNA(100) transcripts indicated that viral genomic sequences complementary to these DNA transcripts were not present at sites distal to the ends of the RNA genome and therefore not adjacent to the corresponding gene sequences representing the various species of viral mRNA from infected cells. These studies suggest that the 5'-terminal genomic nucleotide sequences, or a portion thereof, are somehow added or "spliced" onto each ASV-specific mRNA species in infected cells either during or after transcription of proviral DNA for some as yet undetermined purpose.
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PMID:Evidence for splicing of avian sarcoma virus 5'-terminal genomic sequences into viral-specific RNA in infected cells. 20 93

We investigated the influence of viral RNase H on the transcription of the avian sarcoma virus RNA in a virion-associated reaction. The ability of RNase H to degrade the RNA moiety of the initially formed RNA-DNA hybrid at the 5' end of the viral genome was found to be greatly dependent on the exact concentration of nonionic detergent used to activate the reaction. At a detergent concentration optimal for extensive and faithful in vitro transcription of avian sarcoma virus RNA by the virion-associated RNA-dependent DNA polymerase, most of the 5' terminus of the RNA was digested in 30 min at 41 degrees C. At higher than optimal detergent concentrations, however, little of that RNA was digested. We conclude that removal of the 5'-terminal redundancy in the RNA after its transcription into DNA is a prerequisite for base pairing of the DNA to the 3'-terminal redundant sequence. Lack of removal of this sequence leads to incorrect elongation and substantial reduction of DNA synthesis. When tested with a synthetic RNA-DNA hybrid, virion-associated RNase H did not reveal a detergent dependence.
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PMID:Effect of viral RNase H on the avian sarcoma viral genome during early transcription in vitro. 22 44

Retroviral integrase (IN) functions to insert retroviral DNA into the host cell chromosome in a highly coordinated manner. IN catalyzes two biochemically separable reactions: processing of the viral DNA ends and joining of these ends to the host DNA. Previous studies suggested that these two reactions are chemically similar and are carried out by a single active site that is characterized by a highly conserved constellation of carboxylate residues, the D,D(35)E motif. We report here the crystal structure of the isolated catalytic domain of avian sarcoma virus (ASV) IN, solved using multiwavelength anomalous diffraction data for a selenomethionine derivative and refined at 1.7 A resolution. The protein is a crystallographic dimer with each monomer featuring a five-stranded mixed beta-sheet region surrounded by five alpha-helices. Based on the general fold and the arrangement of catalytic carboxylate residues, it is apparent that ASV IN is a member of a superfamily of proteins that also includes two types of nucleases, RuvC and RNase H. The general fold and the dimer interface are similar to those of the analogous domain of HIV-1 IN, whose crystal structure has been determined at 2.5 A resolution. However, the ASV IN structure is more complete in that all three critical carboxylic acids, Asp64, Asp121 and Glu157, are ordered. The ordered active site and the considerably higher resolution of the present structure are all important to an understanding of the mechanism of retroviral DNA integration, as well as for designing antiviral agents that may be effective against HIV.
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PMID:High-resolution structure of the catalytic domain of avian sarcoma virus integrase. 756 93

Both the RNase H domain of Moloney murine leukemia virus (Mo-MLV) reverse transcriptase (RT) and Escherichia coli RNase H possess a positively charged alpha-helix (C helix) and a loop that are not present in the RNase H domains of human immunodeficiency virus (HIV) RT or avian sarcoma virus RT. Although a mutant Mo-MLV RT lacking the C helix (DeltaC RT) retains DNA polymerase activity on homopolymeric substrates and partial RNase H activity, reverse transcription of the viral RNA genome in vivo is defective. To identify the essential features of the C helix, a panel of Mo-MLV RT mutants was generated. Analyses of these mutant viruses revealed the importance of residues H594, I597, R601, and G602. The mutants were tested for their ability to synthesize viral DNA after acute infections and to form proper 5' and 3' viral DNA ends. The mutant RTs were tested in vitro for exogenous RT activity, minus-strand strong-stop DNA synthesis in endogenous RT reactions, nonspecific RNase H activity, and finally, proper cleavage at the polypurine tract-U3 junction. The R601A mutant was the most defective mutant both in vivo and in vitro and possessed very little RNase H activity. The H594A, I597A, and G602A mutants had significant reductions in RNase H activity and in their rates of viral replication. Many of the mutants formed improper viral DNA ends and were less efficient in PPT-U3 recognition and cleavage in vitro. The data show that the C helix plays a crucial role for overall RNase H cleavage activity. The data also suggest that the C helix may play an important role in polypurine tract recognition and proper formation of the plus-strand DNA's 5' end.
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PMID:Mutations of the RNase H C helix of the Moloney murine leukemia virus reverse transcriptase reveal defects in polypurine tract recognition. 1213 40