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)

Poly(ADP-ribose) polymerase activity in nuclei isolated from differentiating cardiac muscle of the rat has been characterized and its activity measured during development. Optimum enzyme activity is observed at pH 8.5. Poly(ADP-ribose) polymerase is inhibited by ATP, thymidine, nicotinamide, theophylline, 3-isobutyl-1-methylxanthine and caffeine and stimulated by actinomycin D. The activity measured under optimal assay conditions increases during differentiation of cardiac muscle and is inversely related to the rate of DNA synthesis and to the activities of DNA polymerase alpha and thymidine kinase. When DNA synthesis and the activity of DNA polymerase alpha are inhibited in cardiac muscle of the 1-day-old neonatal rat by dibutyryl cyclic AMP or isoproterenol, the specific activity of poly(ADP-ribose) polymerase measured in isolated nuclei is increased. The concentration of NAD+ in cardiac muscle increases during postnatal development. In the adult compared with the 1-day-old neonatal rat the concentration of NAD+ relative to fresh tissue weight, DNA or protein increased 1.7-fold, 5.2-fold or 1.4-fold respectively. The concentration of NAD+ in cardiac muscle of the 1-day-old neonatal rat can be increased by approx. 20% by dibutyryl cyclic AMP. These data suggest that NAD+ and poly(ADP-ribose) polymerase may be involved with the repression of DNA synthesis and cell proliferation in differentiating cardiac muscle.
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PMID:Poly(adenosine diphosphate ribose) polymerase activity and nicotinamide adenine dinucleotide in differentiating cardiac muscle. 18 Sep 77

The direct measurement of ultraviolet light-stimulated DNA synthesis in the permeable Bacillus subtilis cells was performed. Bacillus subtilis spores germinated in the presence of chloramphenicol were treated with Brij 58 and irradiated with ultraviolet light, and (3H)dTTP was incorporated into these cells by the DNA polymerase assay system. Characteristics of the incorporation were distinct from those into spores germinated in the absence of chloramphenicol and treated with Brij 58, in the respect that the former incorporation did not require ATP and only partially depended on the presence of all four deoxyribonucleoside triphosphates. The incorporation of (3H)dTTP into DNA was confirmed by CsCl density gradient centrifugation. A DNA polymerase I-deficient strain, JBl 49(59) had no (3H)sTTP incorporating activity induced by ultraviolet light irradiation when the germinated spores were treated with Brij 58. Analysis of alkaline sucrose gradient centrifugation revealed that fragmented DNA caused by ultraviolet light irradiation was rejoined to the size of DNA of non-irradiated cells by incubating irradiated cells in the DNA polymerase assay mixture containing NAD+. The results also suggested that a machinery of DNA repair probably pre-existed in the spore.
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PMID:Deoxyribonucleic acid synthesis induced with ultraviolet light in Brij 58-treated Bacillus subtilis spores germinated in the presence of chloramphenicol. 80 21

We surveyed the occurrence of unique restriction sites on the cDNAs of viroids, virusoids, and plant viral satellite RNAs that have a circular RNA as an intermediate of replication and found that four such sites would linearize their circular cDNAs. A rapid and simple method was then developed for cloning a naturally occurring viroid from Nematanthus wettsteinii plants. First-strand cDNA was synthesized using random hexanucleotide DNA primers and M-MuLV reverse transcriptase (Superscript RT). Second-strand DNA was synthesized by employing the replacement synthesis method using Escherichia coli RNase H, E. coli DNA polymerase I, E. coli DNA ligase, and beta-NAD+. The circular double-stranded DNA was analyzed for the presence of commonly available, unique restriction sites and subsequently linearized with a selected restriction enzyme. The linear cDNA was ligated to dephosphorylated plasmid vector pGEM 3Z f(+) and cloned in E. coli strain DH5 alpha. This cDNA cloning procedure is suitable for cloning sequence variants of well-characterized viroids, virusoids, certain plant viral satellite RNAs, and new such pathogens of unknown sequence.
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PMID:A rapid and versatile method for cloning viroids or other circular plant pathogenic RNAs. 138 86

The cell cycle dependent fluctuation of adenosine diphosphoribosyl transferase (ADPRT) activity was demonstrated by both nicotinamide adenine dinucleotide (3H-NAD+) incorporation into the acid insoluble fraction of permeabilized cells and changes in the cellular content of NAD, the only substrate of ADPRT, in intact FL cells. The ADPRT activity was lowest in the G1 phase and highest in the S/G2-G2 phase. Aphidicolin, a specific inhibitor of DNA polymerase a, abolished the fluctuation of ADPRT activity. Meanwhile, in 5-fluorodeoxy-uridine (FUdR) exposed cells whose DNA synthesis was interfered with by the inhibition of thymidylate synthetase and the rate of ligation of short replicative intermediates, the ADPRT activity remained at a higher level than in controls. However, 3-aminobenzamide (3AB), a potent ADPRT inhibitor, showed down DNA synthesis in the S phase and also extended the S phase. These results indicate that ADP-ribosylation may be involved in DNA replication and cell cycle progression, and suggest that ADPRT activity may be stimulated by transient short fragments of newly replicated DNA, exerting its effects at the later stages of DNA replication, most probably at the ligation step of DNA synthesis.
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PMID:On the relationship between adenosine diphosphoribosyl transferase and S phase DNA synthesis in cultured mammalian cells. 253 93

Using polysomal immunoselected rat liver glutathione S-transferase mRNAs, we have constructed cDNA clones using DNA polymerase I, RNase H, and Escherichia coli ligase (NAD+)-mediated second strand cDNA synthesis as described by Gubler and Hoffman (Gubler, U., and Hoffman, B. S. (1983) Gene 25, 263-269). Recombinant clone, pGTB42, contained a cDNA insert of 900 base pairs whose 3' end showed specificity for the Yc mRNA in hybrid-select translation experiments. The nucleotide sequence of pGTB42 has been determined, and the complete amino acid sequence of a Yc subunit has been deduced. The cDNA clone contains an open reading frame of 663 nucleotides encoding a polypeptide comprising 221 amino acids with a molecular weight of 25,322. The NH2-terminal sequence deduced from pGTB42 is in agreement with the first 39 amino acids determined for a Ya-Yc heterodimer by conventional protein-sequencing techniques. A comparison of the nucleotide sequence of pGTB42 with the sequence of a Ya clone, pGTB38, described previously by our laboratory (Pickett, C. B., Telakowski-Hopkins, C. A., Ding, G. J.-F., Argenbright, L., and Lu, A.Y.H. (1984) J. Biol. Chem. 259, 5182-5188) reveals a sequence homology of 66% over the same regions of both clones; however, the 5'- and 3'-untranslated regions of the Ya and Yc mRNAs are totally divergent in their sequences. The overall amino acid sequence homology between the Ya and Yc subunits is 68%, however, the NH2-terminal domain is more highly conserved than the middle or carboxyl-terminal domains. Our data suggest that the Ya and Yc subunits of the rat liver glutathione S-transferases are products of two different mRNAs which are derived from two related yet different genes.
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PMID:Rat liver glutathione S-transferases. Construction of a cDNA clone complementary to a Yc mRNA and prediction of the complete amino acid sequence of a Yc subunit. 298 14

Fibroblasts from patients with Cockayne Syndrome (CS) are hypersensitive to UV light. DNA repair was analyzed in these cells by sedimentation behaviour of DNA nucleoids in sucrose gradients and compared to normal control cells. The initiation of repair, the incision of the DNA strand next to the UV lesion appeared to be normal. The rejoining of DNA stretches, however, is retarded in CS cells. DNA repair synthesis of UV damages was measured by autoradiography of [14C]thymidine incorporation into resting cells. Up to 4 h the DNA repair synthesis was comparable with normal cells. From 4 to 7 h the incorporation of radioactive precursors declined in CS cells. Besides a defective DNA polymerase this could be due to accelerated excorporation of radioactive nucleotides as a consequence of delayed ligation. In ligation the enzyme itself could be affected as well as its activation by ADP-ribosylation. Nicotine adenine dinucleotide (NAD+) is needed for the ADP ribosylation process. The cellular NAD+ content, however, was found to be the same in normal and in CS fibroblasts. Increase of the extracellular NAD+ supply accelerated the rejoining of UV damaged DNA in CS cells.
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PMID:DNA repair in human cells: in Cockayne syndrome cells rejoining of DNA strands is impaired. 375 88

Incubation of DNA polymerase alpha, DNA polymerase beta, terminal deoxynucleotidyl transferase, or DNA ligase II in a reconstituted poly(ADP-ribosyl)ating enzyme system markedly suppressed the activity of these enzymes. Components required for poly(ADP-ribose) synthesis including poly(ADP-ribose) polymerase, NAD+, DNA, and Mg2+ were all essential for the observed suppression. Purified poly(ADP-ribose) itself, however, was slightly inhibitory to all of these enzymes. Furthermore, the suppressed activities of DNA polymerase alpha, DNA polymerase beta, and terminal deoxynucleotidyl transferase were largely restored (3 to 4-fold stimulation was observed) by a mild alkaline treatment, a procedure known to hydrolyze alkaline-labile ester linkage between poly(ADP-ribose) and an acceptor protein. All of these results strongly suggest that the four nuclear enzymes were inhibited as a result of poly(ADP-ribosyl)ation of either the enzyme molecule itself or some regulatory proteins of these enzymes.
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PMID:Inhibition of DNA polymerase alpha, DNA polymerase beta, terminal deoxynucleotidyl transferase, and DNA ligase II by poly(ADP-ribosyl)ation reaction in vitro. 392 Oct 27

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

A model for eukaryotic DNA damage repair is proposed in which poly(ADP-ribose) polymerase(NAD+ ADP-ribosyl transferase, EC 2,4,2,30) plays an important role. In this model, poly(ADP-ribose) polymerase regulates transcription of genes that are induced by DNA-damaging agents. This transcriptional regulation results from poly(ADP-ribosyl)ation and inactivation of DNA sequence-specific regulatory proteins such as silencer element-binding proteins, thereby inducing transcription of DNA polymerase beta, which is a DNA repair enzyme in higher eukaryotes. Poly(ADP-ribose) polymerase has a number of similarities to RecA in Escherichia coli. Therefore, the genes related to DNA damage repair in higher eukaryotes are proposed to form a "poly(ADP-ribose) polymerase regulatory network" similar to the "SOS regulatory network" in E. coli.
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PMID:Speculations on the roles of ADP-ribosyl transferase based on analogies between RecA and poly(ADP-ribose) polymerase. 824 22

The family Poxviridae contains two subfamilies: the Entomopoxvirinae (poxviruses of insects) and the Chordopoxvirinae (poxviruses of vertebrates). Here we present the first characterization of the genome of an entomopoxvirus (EPV) which infects the North American migratory grasshopper Melanoplus sanguinipes and other important orthopteran pests. The 236-kbp M. sanguinipes EPV (MsEPV) genome consists of a central coding region bounded by 7-kbp inverted terminal repeats and contains 267 open reading frames (ORFs), of which 107 exhibit similarity to previously described genes. The presence of genes not previously described in poxviruses, and in some cases in any other known virus, suggests significant viral adaptation to the arthropod host and the external environment. Genes predicting interactions with host cellular mechanisms include homologues of the inhibitor of apoptosis protein, stress response protein phosphatase 2C, extracellular matrixin metalloproteases, ubiquitin, calcium binding EF-hand protein, glycosyltransferase, and a triacylglyceride lipase. MsEPV genes with putative functions in prevention and repair of DNA damage include a complete base excision repair pathway (uracil DNA glycosylase, AP endonuclease, DNA polymerase beta, and an NAD+-dependent DNA ligase), a photoreactivation repair pathway (cyclobutane pyrimidine dimer photolyase), a LINE-type reverse transcriptase, and a mutT homologue. The presence of these specific repair pathways may represent viral adaptation for repair of environmentally induced DNA damage. The absence of previously described poxvirus enzymes involved in nucleotide metabolism and the presence of a novel thymidylate synthase homologue suggest that MsEPV is heavily reliant on host cell nucleotide pools and the de novo nucleotide biosynthesis pathway. MsEPV and lepidopteran genus B EPVs lack genome colinearity and exhibit a low level of amino acid identity among homologous genes (20 to 59%), perhaps reflecting a significant evolutionary distance between lepidopteran and orthopteran viruses. Divergence between MsEPV and the Chordopoxvirinae is indicated by the presence of only 49 identifiable chordopoxvirus homologues, low-level amino acid identity among these genes (20 to 48%), and the presence in MsEPV of 43 novel ORFs in five gene families. Genes common to both poxvirus subfamilies, which include those encoding enzymes involved in RNA transcription and modification, DNA replication, protein processing, virion assembly, and virion structural proteins, define the genetic core of the Poxviridae.
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PMID:The genome of Melanoplus sanguinipes entomopoxvirus. 984 59

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