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)

About 50% of the SV40 DNA in the process of replication (sv40(ri) dna) completed replication in lysates of infected BSC-1 cells by conversion to covalently closed, superhelical SV40 DNA (SV40(I) DNA). Fractionation of the lysate into nuclear and cytoplasmic components blocked 99% of the synthesis of SV40(I) DNA in the purified nuclei. The reconstituted system, made by adding back the cytoplasmic fraction before incubation at 30 degrees, completely restored the in vitro level of SV40(I) DNA synthesis. Preliminary characterization of the activity found in the cytoplasmic fraction suggested it was a soluble, heat-labile protein (or proteins) with a minimum molecular weight of about 30,000 and an active sulfhydryl group. The activity was present in both infected and uninfected monkey cells, and at a lower level in mouse, hamster, and human cell lines. Neither serum starvation nor cycloheximide treatment of cells diminished the activity in the cytoplasmic fraction. Purified cytoplasmic DNA polymerase from KB cells did not substitute for the cytoplasmic fraction which was required for elongation of newly synthesized DNA strands. In the absence of the cytoplasmic fraction, conversion of 4 S DNA into longer strands was inhibited, and SV40(RI) DNA appeared to be broken specifically at the replication forks.
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PMID:Requirement of a Cytoplasmic Fraction for Synthesis of SV40 Deoxyribonucleic Acid in Isolated Nuclei*. 16 98

During thymine starvation, strand breaks accumulate in the chromosomal deoxyribonucleic acid (DNA) of Escherichia coli. This effect occurs to a varying extent in different strains and is particularly enhanced in strains deficient in DNA polymerase I. The inhibition of ribonucleic acid or protein synthesis suppresses the accumulation of strand breaks. In a polA strain, rifampin is more effective than chloramphenicol or puromycin in suppressing strand break accumulation. To a certain extent the pehenomenon othymineless death correlates with the appearance of strand breaks. Although the killing can not be explained by the bulk of strand breaks, it is possible that some of them represent lethal events. On the basis of our observations we proposed the following model. (i) Transcription may be accompanied by single-strand breaks in DNA. (ii) DNA polymerase I is involved in the efficient repair of these breaks. (iii) Thymine deprivation results in the accumulation of unrepaired breaks. (iv) Polymerase I-mediated repair is less affected by thymine deprivation than are the alternative pathways because it closes the breaks with short patches, requiring less thymine.
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PMID:Sedimentation analysis of deoxyribonucleic acid from thymine-starved Escherichia coli. 109 May 81

In eukaryotic cells, nucleus-cytoplasm exchanges play an important role in genomic regulation. We have analyzed the localization of four nuclear antigens in different growth conditions: two replicative proteins, DNA polymerase alpha and proliferating cell nuclear antigen (PCNA), and two oncogenic regulatory proteins, c-Myc and c-Fos. A kinetic study of subcellular localization of these proteins has been done. In cultures in which cells were sparse, these proteins were detected in the nucleus. When proliferation was stopped by the high density of culture cells or by serum starvation, these proteins left the nucleus for the cytoplasm with different kinetics. DNA polymerase alpha is the first protein to leave the nucleus, with the PCNA protein, c-Fos, and c-Myc leaving the nucleus later. In contrast, during serum stimulation c-Fos and c-Myc relocalize into the nucleus before the replicative proteins. We also noticed that in sparse cell cultures, 10% of the cells exhibit a perinuclear staining for the DNA polymerase alpha, PCNA, and c-Myc proteins but not for c-Fos. This peculiar staining was also observed as an initial step to nuclear localization after serum stimulation and in vivo in Xenopus embryos when the G1 phase is reintroduced in the embryonic cell cycle at the mid-blastula stage. We suggest that such staining could reflect specific structures involved in the initiation of the S phase.
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PMID:Comparative analysis of the intracellular localization of c-Myc, c-Fos, and replicative proteins during cell cycle progression. 135 52

Terminal deoxynucleotidyl transferase (TdT) is a template-independent DNA polymerase that is transiently expressed during the normal development of T and B lymphocytes. Phorbol 12-myristate 13-acetate (PMA) has been reported to induce maturation-like changes, including the loss of TdT, in many leukemic cell lines. We investigated the mechanism of TdT repression by PMA in an early thymocyte-like cell line, RPMI 8402. At a concentration of 8 nM, PMA caused both repression of TdT synthesis and arrest of proliferation. At greater concentrations of PMA, these same changes initially occurred, but then cell proliferation resumed, and TdT was reexpressed. At both 8 and 160 nM PMA, TdT biosynthesis and TdT mRNA became undetectable within 8 hours, while cell proliferation and DNA synthesis were not significantly reduced until 16 hours. Growth arrest induced by serum starvation did not result in a similar reduction of TdT RNA even after 48 hours. With 160 nM PMA, TdT mRNA could be detected again by 24 hours, and proliferation resumed. Transcription run-off assays indicated that TdT RNA synthesis ceased within 1 hour after exposure to both 8 and 160 nM PMA. T cell receptor alpha (TcR alpha) RNA was induced when TdT RNA was repressed. TcR beta RNA levels were unchanged, and TcR gamma RNA was up-regulated. TdT gene repression and modulation of cell proliferation as well as induction of TcR gene expression are normal events during intrathymic T cell maturation. This cell model provides a system for analyzing the molecular regulation of these significant developmental events.
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PMID:Phorbol ester regulation of terminal deoxynucleotidyl transferase, proliferation, and TcR alpha in a pre-T cell line. 213 60

To asses the possible roles of the two active forms of mouse DNA polymerase alpha: primase--DNA-polymerase alpha complex (DNA replicase) and DNA polymerase alpha free from primase activity (7.3S polymerase), in nuclear DNA replication the correlation of their activity levels with the rate of nuclear DNA replication was determined and a comparison made of their catalytic properties. The experiments using either C3H2K cells, synchronized by serum starvation, or Ehrlich culture cells, arrested at the S phase by aphidicolin, showed DNA replicase to increase in cells in the S phase to at least six times that of the G0-phase cells but 7.3S polymerase to increase but slightly in this phase. This increase in DNA replicase activity most likely resulted from synthesis of a new enzyme, as shown by experiments using a specific monoclonal antibody, aphidicolin and cycloheximide. Not only with respect to the presence or absence of primase activity, but in other points as well the catalytic properties of these two forms were found to differ; DNA replicase preferred the activated calf thymus DNA with wide gaps of about 100 nucleotides long as a template-primer, while the optimal gap size for 7.3S polymerase was 40-50 nucleotides long. Size analysis of the products synthesized on M13 single-stranded circular DNA with a single 17-nucleotide primer by DNA replicase and 7.3S polymerase suggested the ability of DNA replicase to overcome a secondary structure formed in single-stranded DNA to be greater than that of 7.3S polymerase.
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PMID:Activity levels of mouse DNA polymerase alpha-primase complex (DNA replicase) and DNA polymerase alpha, free from primase activity in synchronized cells, and a comparison of their catalytic properties. 308 93

Previous results from this laboratory have shown that thymidylate deprivation results in dramatic elevation of intracellular dUTP and incorporation of dUMP into DNA. The goal of the present studies was to determine whether the latter changes may play a part in the associated cytotoxicity ("thymineless death"), which is ordinarily assumed to be a direct result of reduced intracellular dTTP. The approach used here was to increase intracellular dUTP without allowing dTTP to diminish and observe the effects on cell viability. dUMP pools were expanded by exposure of cells to deoxyuridine [in cell growth medium containing hypoxanthine, methotrexate, and thymidine (HAT medium)], resulting in accumulation of dUTP to levels that approached those of dTTP, which were at, or higher than, the levels in untreated cells. In conjunction with this the cells became nonviable, and newly synthesized DNA was fragmented, both of which occur with thymidylate depletion and, we assume, result from the active process of excision repair at the many uracil-containing sites in DNA. The results indicate that, although the relative importance of low dTTP remains unknown, elevated dUTP can account for the cytotoxicity caused by thymidine starvation. Most of the "dTTP" measured by the DNA polymerase assay in cells treated with methotrexate (MTX) (plus purine supplement) was, in fact, dUTP, which may explain some previous observations of only modest depression of dTTP in cells treated with MTX or similarly acting drugs.
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PMID:DNA fragmentation and cytotoxicity from increased cellular deoxyuridylate. 352 74

Treatment of the eukaryotic organism Tetrahymena with various types of DNA-damaging agents has been reported to cause a 35-fold induction of a mitochondrial DNA polymerase. We here report that the enzyme can be induced in large-scale cultures by exposure of the cells to thymine starvation and/or intercalating agents. The induced DNA polymerase has been purified to near homogeneity, with a specific activity of approx. 300,000 units/mg protein. The relative molecular mass of the active form of the enzyme is approx. 100,000, as determined by glycerol gradient sedimentation. The subunit structure has been analysed by SDS polyacrylamide gel electrophoresis of the highly purified preparation and by immunoprecipitation with a monoclonal antibody directed to the DNA polymerase. A polypeptide of Mr 47,000 has been observed to be a subunit of the enzyme. This corresponds to the size of the subunits suggested for mitochondrial DNA polymerase from chicken embryos and mouse myeloma cells.
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PMID:Purification and characterization of an inducible mitochondrial DNA polymerase from Tetrahymena thermophila. 381 2

The phenomenon of metabolic mutagenesis is found to be determined by stabilization of metabolic breaks in DNA chains, being linked with disbalance of intracellular synthesis of DNA and protein. The rate of metabolic mutagenesis observed in case of the DNA-protein synthesis disbalance due to thymine starvation is influenced by cell genotype. The lack of exonuclease V in recB-thy- cells decreases (reduces) the rate of metabolic mutagenesis and does not effect the viability. The lack of DNA polymerase I activity in polA-thy- cells causes a sharp increase in the metabolic mutagenesis rate and a parallel sharp drop in the survival under thymine starvation, as compared to cells with polA+thy- genotype.
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PMID:[Relation between Escherichia coli K-12 viability and mutability and the balance between DNA and protein synthesis. III. Relation between disruptions in the balance between DNA and protein synthesis and mutagenesis and viability during thymidine deprivation of thy- cells defective with respect to recB and polA genes]. 625 61

Investigation of the formation of metabolic imbalance breaks in the DNA of thy- cells of E. coli during thymine starvation is described. The results of experiments indicate that two enzymes--exonuclease V and 3' exonuclease activity of DNA polymerase II take part in the formation of metabolic imbalance gaps. The manifestation of activity of the enzymes has a tandem character.
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PMID:[Molecular mechanisms of stabilization and preparation of metabolic breaks in DNA strands in vivo. I. Tandem action of exonuclease V and DNA polymerase II]. 628 32

This review discusses the potential relationships between ADP-ribosylation reactions, DNA repair, cell differentiation, and cancer. ADP-ribosylation of chromatin proteins has been shown to participate in DNA excision repair in all nucleated cells. ADP-ribosylation of chromatin proteins is catalysed by nuclear ADP-ribosyl transferase (ADPRT). This enzyme is entirely dependent on DNA for its activity because it has an absolute requirement for ends or nicks in double-stranded DNA. Exposure of cells to small alkylating agents or to radiation causes a fall in cellular NAD+ levels due to a transient activation of ADPRT and a consequent ADP-ribosylation of chromatin proteins. Inhibitors of ADPRT retard DNA strand-rejoining induced by radiation or by small alkylating agents; such inhibition has at least two biological consequences; a synergistic potentiation of cytotoxicity and an enhancement of sister chromatid exchanges and chromosomal aberrations. No species differences have yet been reported; there are variations between cell types and between different damaging agents. The enzyme inhibitors do not block early steps in DNA repair, and repair synthesis does not require ADPRT activity. DNA damage increases the activity of both DNA polymerase beta and DNA ligase II. The activation of DNA ligase II can be blocked by ADPRT inhibitors; presumably ADPRT activity is required for the activation of DNA ligase II. A plausible molecular explanation for the function of ADPRT in DNA repair is that ADPRT regulates the activity of DNA ligase II, the "non-replicative" ligase. In addition to its function in DNA repair, ADPRT is an obligatory requirement in certain categories of cell differentiation. Inhibitors of ADPRT and nicotinamide starvation both reversibly block cell differentiation. We suggest that a similar mechanism to that of DNA repair may be involved because we observe 100 to 300 single-strand DNA breaks during the cytodifferentiation of primary chick myoblasts. These breaks are not due to a general deficiency in DNA repair. I suggest that in certain categories of cell differentiation there are rearrangements or transpositions within the mammalian genome, and that ADP-ribosylation reactions have a general function to be sensitive to DNA breaks and to regulate subsequent DNA ligation in DNA repair, in DNA recombination, in sister chromatid exchanges, in chromosome aberrations, in gene rearrangements, in transpositions and in certain categories of cell differentiation. The relevance of these observations and ideas to cancer is discussed.
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PMID:ADP-ribosylation, DNA repair, cell differentiation and cancer. 631 41

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