EC:6.5.1.2 - FACTA Search

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Query: EC:6.5.1.2 (DNA ligase)
2,749 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The DNA in gently lysates of T4-infected Escherichia coli cells sediments in sucrose gradients as two major components; the slower sedimenting component is designated as the S-5 fraction and the faster sedimenting component as the pad fraction. The distribution of these fractions in lysates of cells infected with T4 maturation-defective and DNA-arrest mutants was determined, and their template activities were compared in a DNA-dependent amino acid-incorporating system. The S-5 DNA template was found to be completely absent in E. coli B cells infected with a T4 maturation-defective mutant (gene 55). On the other hand, DNA sedimenting as the S-5 component is greatly increased, while that sedimenting as the pad component is virtually absent in nonpermissive cells infected with a DNA-arrest mutant (gene 46). The S-5 fractions prepared from cells infected with a DNA ligase mutant (gene 30) and a gene 30 gene 46 double mutant are reduced in their ability to stimulate amino acid incorporation compared to similar preparations from cells infected with wild type T4 or a gene 46 mutant. Moreover, the template activity of partially purified replicative DNA prepared from cells infected with phage-carrying mutations either on gene 30 or in both genes 46 and 56 (dCTPase) is lower than that of DNA obtained from cells infected with wild type phage. The polypeptide products of reaction mixtures programmed with several of the mutant DNAs were found to be qualitatively different from polypeptides synthesized in response to either mature DNA or replicative DNA prepared from cells infected with wild type phage. These data suggest that the expression of phage DNA may be significantly influenced by physical changes in the DNA arising from abnormal replication.
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PMID:Template properties of bacteriophage T4 vegetative DNA. II. Effect of maturation and DNA-arrest mutations. 110 13

A highly purified DNA ligase from rat liver nuclei has been tested on DNA containing single-strand breaks ("nicks"); the DNA was present in several types of complexes which were chosen to serve as models for chromatin. These model systems included complexes of polylysine or histones with DNA as well as reconstituted chromatin preparations. In all these cases, the limit of ligase sealing was measured as a function of the ratio of polypeptide or protein to DNA. With an excess of either polylysine or histones, the ligase is totally prevented from sealing nicks in the DNA. However, at ratios of histones to DNA similar to those occurring in chromatin, about half of the nicks are accessible to the ligase. In the reconstitution of chromatin, the proteins are dissociated from the DNA by exposure to high ionic strength either with or without urea. If such procedures are carried out in the presence of labeled nicked DNA, the proteins will redistribute over this ligase substrate as well. When the chromatin is reconstituted at protein/DNA ratios similar to those occurring in chromatin, once more only about half of the nicks are accessible to the ligase. Similar results were obtained with preparations reconstituted with either rat liver or duck reticulocyte chromatin. The rate of ligase action has been measured on a variety of the complexes. While the rate falls as the DNA is increasingly covered with polylysine or histones, this is largely or entirely due to the decrease in concentration of sealable sites. At saturating concentrations of these DNA complexes, the original rate on uncovered DNA is approached.
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PMID:DNA ligase activity in chromatin and its analogs. Rejoining of DNA strands in polylysine-DNA complexes and in reconstituted chromatins. 112 93

Genetic studies have previously demonstrated that the Saccharomyces cerevisiae CDC9 gene product, which is functionally homologous to mammalian DNA ligase I, is required for DNA replication and is also involved in DNA repair and genetic recombination. In the present study we have purified the yeast enzyme. When measured under denaturing conditions, Cdc9 protein has a polypeptide molecular mass of 87 kDa. The native form of the enzyme is an 80-kDa asymmetric monomer. Both estimates are in good agreement with the M(r) = 84,406 predicted from the translated sequence of the CDC9 gene. Cdc9 DNA ligase acts via the same basic reaction mechanism employed by all known ATP-dependent DNA ligases. The catalytic functions reside in a 70-kDa C-terminal domain that is conserved in mammalian DNA ligase I and in Cdc17 DNA ligase from Schizosaccharomyces pombe. The ATP analog ATP alpha S inhibits the ligation reaction, although Cdc9 protein does form an enzyme-thioadenylate intermediate. Since Cdc9 DNA ligase exhibited the same substrate specificity as mammalian DNA ligase I, this enzyme can be considered to be the DNA ligase I of S. cerevisiae. There is genetic evidence suggesting that DNA ligase may be directly involved in error-prone DNA repair. We examined the ability of Cdc9 DNA ligase to join nicks with mismatches at the termini. Mismatches at the 5' termini of nicks had very little effect on ligation, whereas mismatches opposite a purine at 3' termini inhibited DNA ligation. The joining of DNA molecules with mismatched termini by DNA ligase may be responsible for the generation of mutations.
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PMID:DNA ligase I from Saccharomyces cerevisiae: physical and biochemical characterization of the CDC9 gene product. 144 10

Sequence analysis of the SalI g region of the genome of a virulent isolate of ASFV (Malawi Lil 20/1) has revealed an open reading frame with the potential to encode a 48 kilodalton (kD) polypeptide which has significant homology with eukaryotic and prokaryotic DNA ligases. This ASFV encoded gene also contains the putative active site region of DNA ligases including the lysine residue which is necessary for enzyme-adenylate adduct formation, but lacks the C-terminal basic region conserved in other eukaryotic DNA ligases. A novel [32P]-labelled potential DNA ligase-adenylate adduct of M(r) 45 kD was observed upon incubation of ASFV infected cell cytoplasmic extracts with alpha-[32P]-ATP and subsequent analysis of products by SDS/PAGE. These data together suggest that ASFV encodes its own DNA ligase.
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PMID:An African swine fever virus gene with homology to DNA ligases. 161 52

We have analyzed the expression of DNA ligase I protein during oogenesis and early development of Xenopus laevis. The protein is already present in stage I oocytes and then accumulates throughout oogenesis to reach a steady state level by stage VI. It remains at this level at least until tadpole stage. In stage VI oocytes DNA ligase I protein is almost exclusively localized in the germinal vesicle. We have partially purified a DNA ligase II activity from stage VI oocytes, unfertilized eggs, and stage 8 embryos. An 80-kDa polypeptide can be specifically adenylated in all three purified extracts. It is not recognized by antibodies directed against DNA ligase I and is active on oligo(dT)-poly(rA) substrate. It could therefore represent DNA ligase II protein. The presence of both DNA ligases I and II in oocytes and embryos is inconsistent with the DNA ligase model that had been previously proposed for amphibia.
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PMID:Expression of DNA ligases I and II during oogenesis and early development of Xenopus laevis. 162 56

DNA ligase I is the major DNA ligase activity in proliferating mammalian cells. The protein has been purified to apparent homogeneity from calf thymus. It has a monomeric structure and a blocked N-terminal residue. DNA ligase I is a 125-kDa polypeptide as estimated by sodium dodecyl sulfate-gel electrophoresis and by gel chromatography under denaturing conditions, whereas hydrodynamic measurements indicate that the enzyme is an asymmetric 98-kDa protein. Immunoblotting with rabbit polyclonal antibodies to the enzyme revealed a single polypeptide of 125 kDa in freshly prepared crude cell extracts of calf thymus. Limited digestion of the purified DNA ligase I with several reagent proteolytic enzymes generated a relatively protease-resistant 85-kDa fragment. This domain retained full catalytic activity. Similar results were obtained with partially purified human DNA ligase I. The active large fragment represents the C-terminal part of the intact protein, and contains an epitope conserved between mammalian DNA ligase I and yeast and vaccinia virus DNA ligases. The function of the N-terminal region of DNA ligase I is unknown.
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PMID:Mammalian DNA ligases. Catalytic domain and size of DNA ligase I. 169 31

We have recently shown that the exclusion process causing the replacement of DNA ligases II by DNA ligase I in amphibian eggs after fertilization does not occur in the case of Xenopus laevis [Hardy, S., Aoufouchi, S., Thiebaud, P., and Prigent, C., (1991) Nucleic Acids Res. 19, 701-705]. Since this result is in contradiction with the situation reported in axolotl and Pleurodeles we decided to reinvestigate such results in both species. Three different approaches have been used: (1) the substrate specificity of DNA ligase I; (2) the DNA ligase-AMP adduct reaction and (3) the immunological detection using antibodies raised against the X.laevis DNA ligase I. Our results clearly demonstrate that DNA ligase I activity is associated with a single polypeptide which is present in oocyte, unfertilized egg and embryo of both amphibians. Therefore, the hypothesis of a change in DNA ligase forms, resulting from an expression of the DNA ligase I gene in axolotl and Pleurodeles early development must be rejected. We also show that, in contradiction with published data, the unfertilized sea urchin egg contains a DNA ligase activity able to join blunt ended DNA molecules.
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PMID:Reinvestigation of DNA ligase I in axolotl and Pleurodeles development. 188 65

We purified a mouse DNA repair enzyme having apurinic/apyrimidinic endonuclease, DNA 3'-phosphatase, 3'-5'-exonuclease and DNA 3' repair diesterase activities, and designated the enzyme as APEX nuclease. A cDNA clone for the enzyme was isolated from a mouse spleen cDNA library using probes of degenerate oligonucleotides deduced from the N-terminal amino acid sequence of the enzyme. The complete nucleotide sequence of the cDNA (1.3 kilobases) was determined. Northern hybridization using this cDNA showed that the size of its mRNA is about 1.5 kilobases. The complete amino acid sequence for the enzyme predicted from the nucleotide sequence of the cDNA (APEX nuclease cDNA) indicates that the enzyme consists of 316 amino acids with a calculated molecular weight of 35,400. The predicted sequence contains the partial amino acid sequences determined by a protein sequencer from the purified enzyme. The coding sequence of APEX nuclease was cloned into pUC18 SmaI and HindIII sites in the control frame of the lacZ promoter. The construct was introduced into BW2001 (xth-11, nfo-2) strain cells of Escherichia coli. The transformed cells expressed a 36.4-kDa polypeptide (the 316 amino acid sequence of APEX nuclease headed by the N-terminal decapeptide of beta-galactosidase) and were less sensitive to methyl methanesulfonate than the parent cells. The fusion product showed priming activity for DNA polymerase on bleomycin-damaged DNA and acid-depurinated DNA. The deduced amino acid sequence of mouse APEX nuclease exhibits a significant homology to those of exonuclease III of E. coli and ExoA protein of Streptococcus pneumoniae and an intensive homology with that of bovine AP endonuclease 1.
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PMID:cDNA and deduced amino acid sequence of a mouse DNA repair enzyme (APEX nuclease) with significant homology to Escherichia coli exonuclease III. 193 31

Ku protein is a relatively abundant DNA-binding protein which was first detected as the autoantigen in a patient with scleroderma-polymyositis overlap syndrome (hence the name 'Ku'). It is a heterodimer of two polypeptide chains of molecular weights 85,000 and 72,000, and it characteristically binds, in vitro, to the ends of DNA fragments, and translocates to form regular multimeric complexes, with one protein bound per 30 bp of DNA. We have studied the mechanism of interaction of Ku protein with DNA in vitro, using protein extracted from cultured monkey cells. We find that the precise structure of the DNA ends is not important for binding, as Ku protein can bind to hairpin loops and to mononucleosomes. Bound protein also does not require DNA ends for continued binding, since complexes formed with linear DNAs can be circularized by DNA ligase. Dissociation of the complex also appears to require DNA ends, since ligase closed circular complexes were found to be extremely stable even in the presence of 2 M NaCl. We also found that Ku molecules slide along DNA, with no preferential binding to specific sequences. Thus, Ku protein behaves like a bead threaded on a DNA string, a binding mechanism which allows us to make a new hypothesis concerning the function of this protein in the nucleus.
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PMID:Analysis of the mechanism of interaction of simian Ku protein with DNA. 194 39

The Mr = 38,300 polypeptide of the purified recombinant rat DNA polymerase beta served as an excellent substrate for protein kinase C (PKC) in vitro but not for the catalytic subunit of cAMP-dependent protein kinase. The phosphorylation by PKC resulted in inactivation of DNA polymerase beta activity, and recovery was achieved by dephosphorylation with alkaline phosphatase. Since the phosphorylated DNA polymerase beta was retained with use of a single-stranded DNA-cellulose column, inactivation might occur at a site different from that for the DNA binding. Amino acid sequence analysis of the phosphopeptides revealed that the phosphorylated sites were 2 serine residues at positions 44 and 55 from the NH2 terminus, either or both of which might be involved in the catalytic activity of DNA polymerase beta. Thus, the inactivation of the DNA repair enzyme, DNA polymerase beta, by PKC may be an important process in the modification of DNA metabolism in the nucleus through signal transduction processes.
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PMID:Inactivation of DNA polymerase beta by in vitro phosphorylation with protein kinase C. 204 Jun 2

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