EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Reverse transcriptase isolated from avian myeloblastosis virus (AMV) and Rauscher murine leukemia virus (RLV) were examined for their ability to catalyze polymerization, ribonuclease H, pyrophosphate exchange, and pyrophosphorolysis reactions. A detailed characterization and a study of requirements for the expression of pyrophosphate exchange and pyrophosphorolysis reactions indicated that a variety of RNA and DNA template-primers supported these catalytic reactions. Furthermore, hydrogen bonding of template to primer was essential, although RNA:RNA template-primers, e.g. poly(rA) . (rU)9 or 70 S RNA . tRNA complex, were not utilized for these reactions. AMV enzyme required Mg2+, and RLV enzyme Mn2+, as the preferred divalent metal ion for the expression of these activities. Response of various catalytic reactions to site-specific inhibitors revealed that polymerization and pyrophosphate exchange reactions were susceptible to reagents that affected either the substrate or the template binding site, intrinsic zinc, or sulfhydryl groups. RNase H and pyrophosphorolysis activities, on the other hand, exhibited susceptibility only to the template site-specific reagent. We, therefore, conclude that RNase H and pyrophosphorolysis reactions are catalyzed through the template binding site while polymerization and pyrophosphate exchange reactions require additional participation of the substrate binding site, as well as that of intrinsic zinc and the presence of reactive sulfhydryl groups.
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PMID:Enzymatic activities associated with avian and murine retroviral DNA polymerases. Catalysis of and active site involvement in pyrophosphate exchange and pyrophosphorolysis reactions. 615 89

The family Bunyaviridae comprises over 200 viruses (serotypes, subtypes, and varieties) that infect vertebrates and/or invertebrates. Four genera of viruses have been defined (Bunyavirus, Nairovirus, Phlebovirus, and Uukuvirus). The main characteristics of the member viruses are: (i) the virus particles are for the most part uniformly spherical, 80-110 nm in diameter, and possess a unit membrane envelope from which protrude polypeptide spikes 5-10nm long; (ii) the viruses have three helical nucleocapsids, often in the form of supercoiled circles, each consisting of a single species of single-stranded RNA, major nucleocapsid polypeptide, N, and at least in some cases minor amounts of a large polypeptide which may be a transcriptase component; (iii) the genome is composed of three species of RNA (L, large; M, medium; and S, small), organized in end-hydrogen bonded circular structures; (iv) most viruses have three major virion polypeptides (N, and two surface polypeptides, designated G1 and G2); (v) for at least some member viruses, the virions have been shown to contain an RNA-directed RNA polymerase, believed to be responsible for the synthesis of viral complementary mRNA, so that bunyaviruses are considered to be negative-stranded viruses; (vi) at least some bunyaviruses are capable of heterologous virus genome segment reassortment and can form recombinant viruses at high or low frequency; (vii) viruses appear to mature primarily at smooth membrane surfaces and accumulate in Golgi vesicles and saccules, or nearby; (viii) transovarial, venereal and/or transstadial transmission in arthropods has been shown to occur for some members of the family.
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PMID:Bunyaviridae. 616 2

By fluorimetric titration of Rifs (E. coli B) and Rifr (E. coli rpoB255) RNA polymerases with rifamycin, the mutant polymerase was demonstrated to bind rifamycin. A comparison of spatial structures of rifamycin and dinucleotide fragment of RNA in the hybrid with DNA revealed their similarity. Taking into account this structural similarity and also the fact that two phosphodiester bonds can be formed by RNA polymerase in the presence of rifamycin, a model for the inhibition mode was proposed. According to this model, rifamycin occupies the place of two terminal nucleotides of synthesized, but not translocated pentanucleotide in the transcribing complex. Asp-516 of the wild type beta-subunit was assumed to form a hydrogen bond with the rifamycin C(23) hydroxyl group. On the base of this model, reduced "cycling" synthesis of tetra-, penta-... up to decanucleotides by the Rifr RNA polymerase, in comparison with Rifs, was predicted.
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PMID:[RNA polymerase-rifamycin. A molecular model of inhibition]. 620 42

Several general principles emerge from the studies of Cro, lambda repressor, and CAP. The DNA-binding sites are recognized in a form similar to B-DNA. They do not form cruciforms or other novel DNA structures. There seem to be proteins that bind left-handed Z-DNA (87) and DNA in other conformations, but it remains to be seen how these structures are recognized or how proteins recognize specific sequences in single-stranded DNA. Cro, repressor, and CAP use symmetrically related subunits to interact with two-fold related sites in the operator sequences. Many other DNA-binding proteins are dimers or tetramers and their operator sequences have approximate two-fold symmetry. It seems likely that these proteins will, like Cro, repressor, and CAP, form symmetric complexes. However, there is no requirement for symmetry in protein-DNA interactions. Some sequence-specific DNA-binding proteins, like RNA polymerase, do not have symmetrically related subunits and do not bind to symmetric recognition sequences. Cro, repressor, and CAP use alpha-helices for many of the contacts between side chains and bases in the major groove. An adjacent alpha-helical region contacts the DNA backbone and may help to orient the "recognition" helices. This use of alpha-helical regions for DNA binding appears to be a common mode of recognition. Most of the contacts made by Cro, repressor, and CAP occur on one side of the double helix. However, lambda repressor contacts both sides of the double helix by using a flexible region of protein to wrap around the DNA. Recognition of specific base sequences involves hydrogen bonds and van der Waals interactions between side chains and the edges of base pairs. These specific interactions, together with backbone interactions and electrostatic interactions, stabilize the protein-DNA complexes. The current models for the complexes of Cro, repressor, and CAP with operator DNA are probably fundamentally correct, but it should be emphasized that model building alone, even when coupled with genetic and biochemical studies, cannot be expected to provide a completely reliable "high-resolution" view of the protein-DNA complex. For example, the use of standard B-DNA geometry for the operator is clearly an approximation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Protein-DNA recognition. 623 44

DNA base sequence comparisons demonstrate that the principal family of 300-nucleotide interspersed human DNA sequences, the repetitive double-strand regions of HeLa cell heterogeneous nuclear RNA, and specific RNA polymerase III in vitro transcripts of cloned human DNA sequences are all representatives of a closely related family of sequences. A segment of approximately 30 residues of these sequences is highly conserved in mammalian evolution because it is also present in the interspersed repeated DNA sequences of Chinese hamsters. Further DNA sequence comparisons demonstrate that a portion of this highly conserved segment of repetitive mamalian DNA sequence is similar to a sequence found within a low molecular weight RNA that hydrogen-bonds to poly(A)-terminated RNA molecules of Chinese hamsters and a sequence that forms half of a perfect inverted repeat near the origin of DNA replication in papovaviruses.
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PMID:Ubiquitous, interspersed repeated sequences in mammalian genomes. 624 92

Oxygen enhanced the bactericidal activity of rifamycin SV to Escherichia coli K12. Anaerobically grown cells, which had a low level of superoxide dismutase, were more susceptible to the bactericidal activity than aerobically grown cells, which contained a high level of superoxide dismutase. Oxygen also enhanced the inhibition of RNA polymerase activity of rifamycin SV, when Mn2+ was used as a cofactor. Rifamycin S was reduced to rifamycin SV by NADPH catalyzed by cell-free extracts of Escherichia coli K12. These results indicate that the inhibition of bacterial growth by rifamycin SV is due to the production of active species of oxygen resulting from the oxidation-reduction cycle of rifamycin SV in the cells. The aerobic oxidation of rifamycin SV to rifamycin S was induced by metal ions, such as Mn2+, Cu2+, and Co2+. The most effective metal ion was Mn2+. In the presence of Mn2+, accompanying the consumption of 1 mol of oxygen and the oxidation of 1 mol of rifamycin SV, 1 mol of hydrogen peroxide and 1 mol of rifamycin S were formed. Superoxide was generated during the autoxidation of rifamycin SV. Superoxide dismutase inhibited the formation of rifamycin S, but scavengers for hydrogen peroxide and the hydroxyl radical did not affect the oxidation. A mechanism of Mn2+-catalyzed oxidation of rifamycin SV is proposed and its relation to bactericidal activity is discussed.
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PMID:Oxygen Enhancement of bactericidal activity of rifamycin SV on Escherichia coli and aerobic oxidation of rifamycin SV to rifamycin S catalyzed by manganous ions: the role of superoxide. 627 85

Chloroacetaldehyde-modified poly(rC) or poly(dC) was prepared containing either 8-36% 3,N4-ethenocytidine (epsilon C) or 8-36% of a mixture of epsilon C and the hydrated epsilon C (epsilon C . H2O), with the hydrate greatly predominating (greater than 90%). These ribo- and deoxyribonucleotide templates were transcribed with DNA-dependent RNA polymerases from Escherichia coli and calf thymus, in the presence of either Mn2+ or Mg2+ and all four ribonucleoside triphosphates. All the polymers tested were transcribed with either cation present. In an earlier report from this laboratory [Spengler, S., & Singer, B. (1981) Nucleic Acids Res. 9. 365], transcriptional ambiguities resulting from epsilon C residues in enzymatically synthesized poly(rC, epsilon rC) were studied with E. coli DNA-dependent RNA polymerase in the presence of Mn2+. The misincorporations there reported were confirmed when poly(rC, epsilon rC) and poly(dC, epsilon dC), prepared by reaction of poly(rC) and poly(dC) with CAA, were transcribed in the presence of either Mn2+ or Mg2+. We now report that the presence of hydrated epsilon C in polymers also leads to misincorporations but with reproducible differences from those found with epsilon C alone. Nearest-neighbor analysis of the transcription products showed that the hydrate caused misincorporation of A greater than U much greater than C while epsilon C caused misincorporation of U greater than A much greater than C. The extent of misincorporation in transcription was less with Mg2+ than with Mn2+, but the pattern of ambiguity was the same with both cations and with both ribo- and deoxyribocytidylate polymers. Calf thymus DNA-dependent RNA polymerase IIB was also used to transcribe deoxyribocytidine polymers with Mn2+ as the cation. epsilon C and epsilon C . H2O both caused a high level of misincorporation of U , A, and C, but the preferred misincorporations differed slightly from those found with E. coli DNA-dependent RNA polymerase. For both prokaryotic and eukaryotic enzymes, the type of misincorporation resulting from the loss of hydrogen bonding by modification of the N-3 of C not only differed between epsilon C and the hydrated intermediate but also both differed from the transcriptional errors resulting from the presence of 3-methylcytidine in poly(dC) or poly(rC). We conclude that the errors made by these polymerases during transcription do not result primarily from the conditions used (cation, ribo- or deoxyribotemplate) but must be at least in part attributed to the enzyme recognizing some facet of the modified base other than the lack of normal hydrogen bonding.
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PMID:Chloroacetaldehyde-treated ribo- and deoxyribopolynucleotides. 2. Errors in transcription by different polymerases resulting from ethenocytosine and its hydrated intermediate. 675 74

9-beta-D-Arabinofuranosyl-6-thiopurine was used to affinity label DNA-dependent RNA polymerase isolated from Escherichia coli B. This substrate analogue displayed competitive type inhibition which could be reversed by addition of a thiol reagent, such as dithiothreitol, while exposure to hydrogen peroxide, a mild oxidizing agent, caused an increase in both the inhibitory and enzyme binding capability of arabinofuranosyl thiopurine. Chromatographic analysis of the products obtained by pronase digestion of the 9-beta-D-arabinofuranosyl-6-[35S]thiopurine-enzyme complex suggests that disulfide bond formation occurs between the inhibitor and a cysteine residue located in or near the active center of the enzyme. In addition, polyacrylamide gel electrophoresis indicated that the arabinofuranosyl thiopurine moeity was bound to the beta' subunit of the enzyme.
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PMID:Affinity labeling of a cysteine at or near the catalytic center of Escherichia coli B DNA-dependent RNA polymerase. 676 99

Ile3-amaninamide (3-R) and its diastereomeric sulfoxide (3-S) are obtained by oxidation of the bicyclic thioether peptide 2 by hydrogen peroxide in acetic acid. 2 was prepared by an intramolecular Savige-Fontana reaction of the linear octapeptide tert.-butylester 4 whose N-terminal Boc-Hpi residue on treatment with TFA loses the Boc group and reacts under thioether formation with the released cysteine-SH. The concomitantly deprotected carboxyl terminus is coupled intramolecularly with the free amino group of the secocompound 5 using the MA or DCCI method, thus forming the homodetic peptide ring. Compounds 3-R and 3-S agree very well with analog samples in chiroptical behavior. Thioether 2 and sulfoxide 3-R exert 50% inhibition of RNA polymerase II (or B) from Drosophila melanogaster in 10(-6) M solution whereas Ki of 3-S is about five times higher.
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PMID:Analogs of amanin. Synthesis of Ile3-amaninamide and its diastereoisomeric (S)-sulfoxide. 679 36

The crystal and molecular structure of the sodium salt of rifamycin SV (clinically known as rifacin) as the monohydrate ethanol solvate has been determined to study the conformation of the ansa chain in unsubstituted rifamycins and also to clarify the metal complexation with rifamycins. The crystals belong to the space group P2(1)2(1)2(1) with cell dimensions (estimated standard deviations in parentheses) of a = 12.061 (2), b = 13.936 (2), and c = 24.731 (4) A. The structure was solved by direct methods and refined to an R factor of 0.069. The conformation of the ansa chain differs from that of other active rifamycins, e.g., rifampcin and rifamycin B at the joining point of the ansa chain to the naphthohydroquinone chromophore. The conformation of the middle part of the ansa chain, which is essential for activity against DNA-dependent RNA polymerase, remains the same. The sodium ion is penta-coordinated and has a trigonal bipyramidal geometry. The intermolecular hydrogen bonding involves O(9), O(10), O(5), and O(6) through water and ethanol molecules. A two-step mode of action of rifamycins has been postulated, and the conformations of antibiotics suitable for penetration of the membrane barrier and that for antibiotic-enzyme complex formation have been suggested.
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PMID:Correlation of structure and activity in ansamycins. Molecular structure of sodium rifamycin SV. 686 97

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