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)

The interaction of two natural tetra-azacyclopentazulene dyes with native calf thymus DNA was studied by means of microcalorimetric, viscosimetric, and spectroscopic measurements. The results are consistent with the hypothesis of an intercalative-binding. However, comparison of calorimetric studies shows that the changes in enthalpy associated with the interaction of these compounds with DNA are, in absolute value, significantly lower than those found with known intercalating agnets (daunomycin, ethidium bromide). The influence of these dyes on the template capacity of DNA in the in vitro synthesis of nucleic acids was also determined. Under the conditions used, these compounds selectively inhibited DNA synthesis. No appreciable inhibitory effect upon E. coli RNA polymerase was observed. Both compounds had greater inhibitory effect on rat liver high molecular weight DNA polymerase than E. coli DNA polymerase I. Zoanthoxanthin was a more effective inhibitor than 3-norzoanthoxanthin.
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PMID:The interaction of natural tetra-azacyclopentazulene dyes with DNA and their effects on the DNA and RNA polymerase reactions. 109 42

The T7 gene 4 protein, a protein known from genetic analysis to participate in phage DNA replication in vivo, has been purified approximately 500-fold with an in vitro complementation assay. The protein, purified from cells infected with a T7 gene 4 temperature-sensitive mutant, is thermolabile, establishing that the complementation activity is in the protein product of the phage gene 4. The purified protein has no detectable nuclease, DNA polymerase, or RNA polymerase activity. However, in addition to stimulating the rate of DNA replication in crude extracts of T7 gene 4 mutant-infected cells, the gene 4 protein effects a marked stimulation of DNA synthesis by the purified T7 DNA polymerase when duplex T7 DNA is used as template. This effect is not observed when denatured T7 DNA is used as template, or when phage T4 DNA polymerase or Escherichia coli DNA polymerase I, II, OR III is substituted for the T4 enzyme. Analysis of the DNA synthesized by the T7 DNA polymerase in the presence of the gene 4 protein indicates that much of the product is in short DNA chains which are not covalently attached to the template. This result suggests a novel mechanism for the initiation of DNA chains in this reaction.
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PMID:Bacteriophage T7 deoxyribonucleic acid replication in vitro. Purification and properties of the gene 4 protein of bacteriophage T7. 109 80

The protein responsible for the initiation of conversion of single-stranded phage G4 DNA to the duplex replicative form has been purified approximately 3000-fold and identified with Escherichia coli dnaG gene product. The protein is a rifampicin-resistant RNA polymerase of approximately 64,000 daltons. It catalyzes the incorporation of the four ribonucleoside triphosphates into an oligoribonucleotide, using as template the single-stranded DNA coated with the DNA unwinding protein of E. coli. An RNA transcript of a unique region of the chromosome can serve as a primer by covalent extension by DNA polymerase III holoenzyme to form a nearly full-length linear complementary strand. A similar role for the dnaG protein in the initiation of nascent (Okazaki) fragments in replication of the host chromosome is discussed.
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PMID:dnaG gene product, a rifampicin-resistant RNA polymerase, initiates the conversion of a single-stranded coliphage DNA to its duplex replicative form. 109 46

DNA has been covalently linked to insoluble matrices of agarose (Sepharose) in high yield using cyanogen bromide activation. Both double-stranded and single-stranded DNA have been coupled with yields up to 225 nmol/mg dry weight Sepharose or 3-8 mumol nucleotide phosphate/ml bed volume. The DNA-Sepharose has been used for (a) the affinity chromatography of various enzymes (Escherichia coli DNA polymerase I and RNA polymerase) from crude extracts or after initial purification steps, resulting in high yields and degrees of purification, and for (b) nucleic acid hybridization. The DNA-Sepharose is stable to high temperature, prolonged storage, and in the case of single-stranded DNA, can be washed with NaOH to destroy nuclease activity and to release any digested oligonucleotides or mononucleotides.
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PMID:Covalent attachment of DNA to agarose. Improved synthesis and use in affinity chromatography. 110 Mar 76

Rhodium(II) acetate, propionate, and butyrate showed a considerable variation in their antitumor activity against Ehrlich ascites tumor cells in mice, with the butyrate complex being the most active. The three complexes markedly inhibited DNA synthesis of Ehrlich ascites tumor cells in vivo. Rhodium (II) butyrate was the most potent inhibitor followed by the propionate complex. One hour after administration, rhodium(II) propionate and butyrate induce more uridine-5-3H incorporation into RNA than is seen in the controls. Equilibrium dialysis studied showed that rhodium(II) acetate-1-14C binds to single stranded DNA, poly-A, ribonuclease A, and bovine serum albumin but not to highly polymerized native calf thymus DNA, poly-G, or poly-C. In these cases binding occurred at the two axial positions of rhodium(II) acetate to a nitrogen donor in the ligands. The formation constants of the rhodium(II) acetate and propionate complexes with 5'-adenosine monophosphate were determined. The rhodium(II) propionate complex was more stable. Sedimentation and viscosity measurements of poly-A and poly-A/rhodium(II) acetate complexes indicate a high degree of intramolecular crosslinking in the rhodium(II) acetate/poly-A complex. The rhodium(II) carboxylate complexes were also found to be potent inhibitors of purified DNA polymerase I and RNA polymerase from Escherichia coli.
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PMID:Interaction of Rhodium(II) carboxylates with molecules of biologic importance. 110 39

A soluble extract prepared from T7-infected E. coli is able to initiate DNA synthesis on an exogenous T7 DNA template. We have developed a fractionation procedure to resolve and identify the proteins required for T7 DNA synthesis. By this method we have purified the following T7 replication-related proteins (each greater than 50% pure as judged by sodium dodecyl sulfate gel electrophoresis): T7 DNA-binding protein (27,000 daltons), T7 RNA polymerase (105,000 daltons), T7 DNA polymerase (gene 5-protein, 85,000 daltons, plus host-factor), T7 DNA ligase (40,000 daltons), and T7 DNA-priming protein (65,000 daltons). The T7 DNA-priming protein, synthesized between 7.5 and 15 min following infection, was not detectable if the infecting phage carried an amber mutation in gene 4. Using an in vitro complementation assay which specifically measures the stimulation of DNA synthesis in an extract prepared from T7 gene 4-mutant infected cells, we have purified the DNA-priming protein about 2,000-fold. The purified priming protein preparations are essentially free of endonuclease, exonuclease, DNA ligase and DNA polymerase activity, but they do contain measurable DNA-dependent RNA synthetic acitvity. The enzyme is rapidly inactivated by heating to 46 degrees C and by treatment with N-ethylmalemide. In the presence of T7 DNA-binding protein and all four ribonucleoside triphosphates, the DNA-priming protein enables T7 DNA polymerase to initiate DNA synthesis on intact duplex T7 DNA. Closer studies of its enzymatic function as well as of the possible roles of the other proteins in the T7 replication system will be presented in the accompanying paper.
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PMID:Studies on bacteriophage T7 DNA synthesis in vitro. I. Resolution of the T7 replication system into its components. 110 17

With synchronized tissue culture cells (L929), daunomycin had the greatest inhibitory effect on cell growth when the drug was administered during the later stages of cell division (late S, G2, and M). The level of binding of daunomycin to DNA was not found to be influenced by the phase of the cell cycle. The highest level of radioactivity from [eH]-daunomycin was bound to DNA of the heterochromatin fraction. Both RNA and DNA syntheses were inhibited in isolated enzyme systems when daunomycin-treated DNA, from which the unbound drug was removed by passage through Sephadex column, was used. DNA polymerase was reduced to one-fifth of the control activity, while that of RNA polymerase was reduced to one-half. Similar experiments with daunomycin-treated RNA and DNA polymerase preparations showed that the drug had no effect on the activities of the enzymes per se. Hence, the reduction of RNA and DNA polymerase activities could be accounted for by the loss of template activity of the drug-treated DNA. Daunomycin caused by a marked drop in the formation of a complex between RNA polymerase and DNA, indicating that the binding of daunomycin to DNA may give rise to steric hindrance effects that interfere with the association of the template to RNA polymerase enzyme. Sedimentation profile in alkaline sucrose density gradient of DNA that had been treated with daunomycin showed that no change in the molecular weight could be demonstrated.
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PMID:Binding of daunomycin to DNA and the inhibition of RNA and DNA synthesis. 116 9

Incorporation of labeled thymidine into testicular DNA of hypophysectomized rats began to increase after the administration of testosterone propionate and choriogenic gonadotrophin. While the thymidine incorporation reached maximum in 4 days, the DNA polymerase activity did not culminate until 8 days after the initiation of hormone treatment. The high molecular weight (6--8 S), presumably cytoplasmic DNA polymerase accounted almost entirely for this increase. Administration of testosterone propionate and chorionic gonadotrophin to hypophysectomized rats results in an increase of testicular RNA polymerase and chromatin templating activity. Chain elongation and initiation studies revealed that the increased templating capacity of androgen-stimulated testicular chromatin was almost entirely caused by the increase in the number of initiation sites. While the nuclear polymerase I responded relatively rapidly to hormone stimulation and reached a prominent maximum in about three days, the activity of polymerase II was more sluggish and not as prominent. The in vivo incorporation of ortho[32P]phosphate into chromosomal phosphoproteins occurred early during the androgen treatment and reached a maximum in about 20 h. The protein phosphokinase activity peaked later, approx. 72 h after the first administration of hormones.
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PMID:Testicular chromatin activation in hypophysectomized rats. 127 99

The effect of adriamycin on DNA, RNA, and protein synthesis was investigated in cell-free systems and intact cells. In studies with purified mammalian cell enzymes, adriamycin produced a greater inhibition of DNA-dependent DNA polymerase than of RNA polymerase. The extent of inhibition of both these enzymes was decreased by increasing the concentration of the DNA template in the reaction mixture. In studies with isolated nuclei, adriamycin was also a more potent inhibitor of DNA synthesis than RNA synthesis. However, with intact cells, adriamycin inhibited both DNA and RNA synthesis to about the same extent. The inhibition produced by adriamycin on RNA synthesis in intact cells was greater than that observed in the cell-free systems. Adriamycin inhibited protein synthesis in a cell-free system consisting of polyribosomes, transfer RNA, and enzymes but did not inhibit protein synthesis in intact cells. These differences in the pattern of inhibition may be due to biotransformation of the drug and/or preferential binding to chromosomal DNA in the intact cell.
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PMID:Effect of adriamycin on DNA, RNA, and protein synthesis in cell-free systems and intact cells. 127 99

Reverse transcriptase (RT) was first discovered as an essential catalyst in the biological cycle of retroviruses. However, in the past years evidence has accumulated showing that RTs are involved in a surprisingly large number of RNA-mediated transpositional events that include both viral and nonviral genetic entities. Although it is probable that some RT-bearing genetic elements like the different types of AIDS viruses and the mammalian LINE family have arisen in recent geological times, the possibility that reverse transcription first took place in the early Archean is supported by (1) the hypothesis that RNA preceded DNA as cellular genetic material; (2) the existence of homologous regions of the subunit tau of the E. coli DNA polymerase III with the simian immunodeficiency virus RT, the hepatitis B virus RT, and the beta' subunit of the E. coli RNA polymerase (McHenry et al. 1988); (3) the presence of several conserved motifs, including a 14-amino-acid segment that consists of an Asp-Asp pair flanked by hydrophobic amino acids, which are found in all RTs and in most cellular and viral RNA polymerases. However, whether extant RTs descend from the primitive polymerase involved in the RNA-to-DNA transition remains unproven. Substrate specificity of the AMV and HIV-1 RTs can be modified in the presence of Mn2+, a cation which allows them to add ribonucleotides to an oligo (dG) primer in a template-dependent reaction. This change in specificity is comparable to that observed under similar conditions in other nucleic acid polymerases. This experimentally induced change in RT substrate specificity may explain previous observations on the misincorporation of ribonucleotides by the Maloney murine sarcoma virus RT in the minus and plus DNA of this retrovirus (Chen and Temin 1980). Our results also suggest that HIV-infected macrophages and T-cell cells may contain mixed polynucleotides containing both ribo- and deoxyribonucleotides. The evolutionary significance of these changes in substrate specificities of nucleic acid polymerases is also discussed.
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PMID:On the early emergence of reverse transcription: theoretical basis and experimental evidence. 128 61

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