EC:2.7.7.7 - FACTA Search

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Query: EC:2.7.7.7 (DNA polymerase)
17,007 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

These studies were designed to determine if RIDP was present in a particulate fraction of brains from patients with ALS and PD. Evidence that we have detected RIDP is as follows: (a) DNA polymerase activity persists in the presence of concentrations of actinomycin D and distamycin that inhibit most DNA-directed DNA synthesis (25); (b) the majority of endogenous DNA polymerase activity is sensitive to prior treatment with RNase; (c) the early reaction product is a 4-5 S DNA heteropolymer joined by hydrogen bonds to an RNA molecule; and (d) the purified [3H]DNA product anneals to RNA extracted from the enzyme-containing pellet more extensively than to normal brain RNA or poly(rA). The enzyme activity is in a cytoplasmic particle that can be sedimented at high speed and has the buoyant density of RNA tumor viruses (1.16-1.18 gm/ml). This particulate fraction is not disrupted by physical manipulation and maintains its characteristic density with repeated centrifugations. Treatment with the nonionic surfactant Sterox changes the buoyant density of the enzyme-containing particle to 1.24 gm/ml, the density of the onconavirus virion core. Synthesis of RNA-DNA hybrids by an endogenous reverse transcriptase reaction was found only in normal and diseased Chamorro brains. Examination of a limited number of normal and diseased brains from individuals who lived in the United States produced negative results (39). Definitive characterization of this polymerase activity and identification as a true viral polymerase will depend on purification of biochemically active quantities of this polymerase to determine its template specificities, its cation preference, the fidelity of its transcription product, as well as its antigenic relationship to animal virus and human leukemic RIDP. Of critical importance in these studies will be differentiation of this activity from normal brain DNA polymerase gamma and terminal deoxynucleotidyltransferase.
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PMID:RNA tumor viruses as causative agents of chronic neurological disease. 6 87

The secondary structure of the hydrogen bonded hybrids polycytidylate-oligodeoxguanylate (poly(rC)-(dG)12-18 and poly (2'-oMe) cytidylate-oligodeoxyguanylate (poly (rCm)-(dG)12-18 was studied at several magnesium and manganese ion concentrations. These hybrids are effective template-primer complexes for the synthesis of poly(dG) by avian myeloblastosis virus (AMV) DNA polymerase under disparate ionic conditions. Circular dichroism spectra and thermal melting data were obtained as a function of ion concentration, including conditions that allow optimum rates of poly (dG) synthesis by each complex. These studies demonstrate that both hybrids can change conformation and stability depending on their ionic environment. Comparison of enzyme activity and physical data suggest that the polymerase recognizes particular secondary structure features. Changes in the activity of the AMV polymerase can be induced by varying the Mg++ and Mn++ concentrations alone and in combination. These variations in enzyme activity are correlated with observed changes in the base-stacking alignment of the synthetic template primers. The ions, therefore, seem to affect enzyme activity by altering the conformation of the polnucleotide complexes.
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PMID:The effect of magnesium and manganese ions on the structure and template activity for reverse transcriptase of polyribocytidylate and its 2'-0-methyl derivative. 7 65

Extracts from over 100 normal human placentas have been examined for RNA-directed DNA polymerase (DNA nucleotidyltransferase, EC 2.7.7.7) activity. More than 80% of these placentas contained this enzyme activity, which banded at a density of 1.15-1.17 g/ml in sucrose. After heat treatment, this enzyme activity was shifted in density to 1.22-1.24 g/ml. The enzymatic activity was greater with (rC)n.(dG)12-18 than with (dC)n.(dG)12-18 and was not stimulated by (dG)12-18 alone. The product of the endogenous reaction, which was sensitive to RNase, had the characteristics of a small DNA associated with a large RNA by hydrogen bonding. Electron microscopic inspection of the material with a density of 1.15-1.17 g/ml revealed numerous retrovirus-like particles with central electron-dense cores and double-membraned envelopes. The enzyme may be associated with the retrovirus-lik particles noted in the trophoblast layer of some human placentas.
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PMID:Normal human placentas contain RNA-directed DNA polymerase activity like that in viruses. 8 52

When closed circular SV40 DNA containing 58 negative superhelical turns is used as a template for RNA synthesis with Escherichia coli RNA polymerase, a fraction of the RNA product remains complexed with the DNA. The RNA in the complex is resistant to ribonuclease in high salt, and the Tm indicates that it is hydrogen bonded to the DNA. The mole ratio of RNA to DNA nucleotides in the complex ranges from 0.01 to 0.08; the RNA ranges in length from 80 to 600 nucleotides. The formation of the complex is dependent on the circular DNA being topologically underwound since no complex is formed when closed circular DNA containing zero superhelical turns is used as the template. The DNA-RNA complex can serve as a primer-template combination for in vitro DNA synthesis by E. coli DNA polymerase I. After synthesis with (alpha-32P)-labeled deoxyribonucleoside triphosphates followed by alkaline hydrolysis, the isolation of 32P-labeled ribonucleotides is evidence for a covalent linkage between the RNA and the DNA synthesized. During the in vitro DNA synthesis, the template is nicked at a low rate, and the nicked molecules support extensive DNA synthesis. This observation indicates that only limited synthesis can occur on unnicked molecules possibly owing to the topological constraints against unwinding of the helix. Possible models for in vivo priming of double-stranded DNA by E. coli RNA polymerase are discussed.
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PMID:Priming of superhelical SV40 DNA by Escherichia coli RNA polymerase for in vitro DNA synthesis. 16 2

An RNA polymerase activity that synthesizes a U-rich RNA hydrogen bonded to a large viral RNA molecule was found in the cores of virions of avian reticuloendotheliosis viruses (REV). The RNA polymerase activity was separable from the DNA polymerase activity of REV virions. The 5'-terminus of the newly synthesized RNA was A. In addition, a tRNA nucleotidyl transferase activity, which added -CpCpA ends to tRNA, appears to be present in the REV virions.
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PMID:RNA polymerase activity in purified virions of avian reticuloendotheliosis viruses. 18 17

A cell-free system for the study of viral DNA replications was developed by the isolation of a nuclear membrane fraction "DNA replication complex" from adenovirus 2-infected human KB cells late after infection. This complex which possesses both DNA polymerase activity and a virus-specific endonuclease synthesizes exclusively virus-specific DNA sequences in vitro by a semiconservative mechanism. Analysis by rate zonal sedimentation in alkaline sucrose gradients showed that the products of the reaction are small DNA chains approximately 6 to 9 S, presumably "Okazaki intermediates," that are not sealed under our in vitro conditions. Analysis by rate zonal sedimentation in neutral sucrose gradients showed that labeled viral DNA fragments are hydrogen bonded to viral 18 S DNA segments, 0.25 the size of the linear, viral 31 S DNA genome. The 18 S DNA is probably a specific cleavage product of the viral endonuclease found in the replication complex and could represent intermediates in viral DNA replication or degradation products.
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PMID:Adenovirus deoxyribonucleic acid replication. II. Synthesis of viral deoxyribonucleic acid in vitro by a nuclear membrane fraction from infected KB cells. 23 46

In crude extracts from Escherichia coli cells the ATP-dependent exonuclease V was found to be most active in converting double-stranded DNA into a suitable template for DNA polymerase. This phenomenon was studied in some detail with isolated exonuclease V and T7 DNA polymerase. We found that, at ATP concentrations arount 1 mM, the exonuclease produces a broad spectrum of DNA fragments. One class of fragments is largely single stranded with hydrogen-bonded small primer sequences. These structures allow the synthesis of remarkably homogeneous polynucleotide strands by T7 DNA polymerase.
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PMID:The mechanism of template activation by exonuclease V. 110 Mar 74

The responses of Escherichia coli to X rays and hydrogen peroxide were examined in mutants which are deficient in one or more DNA repair genes. Mutant cells deficient in either exonuclease III (xthA) or endonuclease IV (nfo) had normal resistance to X rays, but an xthA-nfo double mutant showed a sensitivity increased over that of either parental strain. A DNA polymerase I mutant (polA) was more sensitive than the xthA-nfo mutant. Cells bearing mutations in all of the polA, xthA, and nfo genes were more sensitive to X rays than polA and xthA-nfo mutants. Similar repair responses were obtained by exposing these mutant cells to hydrogen peroxide, with the exception of the xthA mutant, which was hypersensitive to this agent. The DNA polymerase III mutant (polC(Ts)) was slightly more sensitive to the agents than the wild-type strain at the restrictive temperature. The sensitivity of the polC-xthA-nfo mutant to X rays and hydrogen peroxide was greater than that of polC but almost the same as that of the xthA-nfo mutant. From these results it appears that there are at least four repair pathways, the DNA polymerase I-, exonuclease III/endonuclease IV and DNA polymerase I-, exonuclease III/endonuclease IV and DNA polymerase III-, and exonuclease III/endonuclease IV-dependent pathways, for the repair of oxidative DNA damages in E. coli.
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PMID:Multiple pathways for repair of oxidative DNA damages caused by X rays and hydrogen peroxide in Escherichia coli. 128 65

Molecular models describing intermediates that may lead to proflavin-induced 1 bp deletions during in vitro polymerization by E. coli DNA polymerase I Klenow fragment are proposed. The models provide structural explanations for the fact that the induced frameshifts always occur opposite template bases that are adjacent to 5' pyrimidines and are based on the underlying hypothesis that the deletions arise because the polymerase passes by a template base without copying it. Because the most frequent mutations are opposite Pu in the template sequence 5' Py Pu 3', a single-strand loop-out model was constructed for this sequence and proflavin was added, using structures found in crystalline oligonucleotides and their complexes with proflavin. The model seeks to rationalize the roles of the 5' pyrimidine and proflavin in facilitating the bypass. Four potential roles for proflavin in mutagenesis are described: 1) stacking on the looped-out base; 2) stacking on the base pair immediately preceding the site of mutation; 3) hydrogen bonding with the 5' pyrimidine; 4) hydrogen bonding with the phosphate backbone. These models point to the possibility that a number of proflavin-DNA interactions may be involved. In contrast, modeling does not suggest a role for classically intercalated proflavin in frameshift mutagenesis arising during in vitro DNA polymerization.
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PMID:A structural model for sequence-specific proflavin-DNA interactions during in vitro frameshift mutagenesis. 146 12

The APN1 gene of Saccharomyces cerevisiae encodes the major apurinic/apyrimidinic endonuclease and 3'-repair DNA diesterase in yeast cell extracts. The Apn1 protein is a homolog of Escherichia coli endonuclease IV, which functions in the repair of some oxidative and alkylation damages in that organism. We show here that yeast strains lacking Apn1 (generated by targeted gene disruption or deletion-replacement) are hypersensitive to both oxidative (hydrogen peroxide and t-butylhydroperoxide) and alkylating (methyl- and ethylmethane sulfonate) agents that damage DNA. These cellular hypersensitivities are correlated with the accumulation of unrepaired damages in the chromosomal DNA of apn1 mutant yeast cells. Hydrogen peroxide-treated APN1+ but not apn1 mutant cells regenerate high-molecular-weight DNA efficiently after the treatment. The DNA strand breaks that accumulate in the Apn1-deficient mutant contain lesions that block the action of DNA polymerase but can be removed in vitro by purified Apn1. An analogous result with DNA from methylmethane sulfonate-treated cells corresponded to the accumulation of unrepaired DNA apurinic sites in the apn1 mutant cells. The rate of spontaneous mutation in apn1 mutant S. cerevisiae was 6- to 12-fold higher than that measured for wild-type yeast cells. This increase indicates that under normal growth conditions, the production of DNA damages that are targets for Apn1 is substantial and that such lesions can be mutagenic when left unrepaired.
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PMID:Cellular role of yeast Apn1 apurinic endonuclease/3'-diesterase: repair of oxidative and alkylation DNA damage and control of spontaneous mutation. 171 20

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