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)

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

A complex network of interacting proteins and enzymes is required for DNA replication. Much of our present understanding is derived from studies of the bacterium Escherichia coli and its bacteriophages T4 and T7. These results served as a guideline for the search and the purification of analogous proteins in eukaryotes. model systems for replication, such as the simian virus 40 DNA, lead the way. Generally, DNA replication follows a multistep enzymatic pathway. Separation of the double-helical DNA is performed by DNA helicases. Synthesis of the two daughter strands is conducted by two different DNA polymerases: the leading strand is replicated continuously by DNA polymerase delta and the lagging strand discontinuously in small pieces by DNA polymerase alpha. The latter is complexed to DNA primase, an enzyme in charge of frequent RNA primer syntheses on the lagging strand. Both DNA polymerases require several auxiliary proteins. They appear to make the DNA polymerases processive and to coordinate their functional tasks at the replication fork. 3'----5'-exonuclease, mostly part of the DNA polymerase delta polypeptide, can perform proof-reading by excising incorrectly base-paired nucleotides. The short DNA pieces of the lagging strand, called Okazaki fragments, are processed to a long DNA chain by the combined action of RNase H and 5'----3'-exonuclease, removing the RNA primers, DNA polymerase alpha or beta, filling the gap, and DNA ligase, sealing DNA pieces by phosphodiester bond formation. Torsional stress during DNA replication is released by DNA topoisomerases. In contrast to prokaryotes, DNA replication in eukaryotes not only has to create two identical daughter strands but also must conserve higher-order structures like chromatin.
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PMID:Eukaryotic DNA replication. Enzymes and proteins acting at the fork. 226 94

Four 25-nt oligonucleotides consisting of sequences of dA and dT (D1-4) have been synthesized. As shown in a companion paper (Rippe et al., 1989), the two combinations D1.D3 and D2.D4 form normal antiparallel duplexes, whereas the pairs D1.D2 and D3.D4 constitute duplexes with the same sequences, but with the two strands parallel to each other. The activities of the following DNA processing enzymes and chemical reagents on the parallel stranded (ps) and antiparallel stranded (aps) duplexes were tested. (i) The restriction endonucleases DraI, SspI, and MseI do not cut the ps duplexes. (ii) DNase I and exonuclease III exhibit a much lower activity with the ps duplexes. (iii) The nuclease activities of S 1 nuclease, micrococcal nuclease (S 7), phage lambda 5'-exonuclease, and the 3'-5' nuclease activity of Escherichia coli DNA polymerase I and its large fragment are higher with the ps than with the aps substrates. (iv) Bal 31 nuclease and the chemical nuclease 1,10-phenanthroline-copper ion [(OP)2Cu+] degrade ps-DNA and aps-DNA at approximately the same rate but show preferred cutting sites only with the aps molecules. (v) The iron(II)-EDTA complex has equivalent nuclease activities with the ps and the aps molecules. (vi) The ps duplex is not a substrate for blunt-end ligation with phage T4 DNA ligase.
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PMID:Substrate properties of 25-nt parallel-stranded linear DNA duplexes. 255 23

APEX nuclease is a mammalian DNA repair enzyme having apurinic/apyrimidinic endonuclease, 3'-5'-exonuclease, DNA 3' repair diesterase and DNA 3'-phosphatase activities. This report describes the organization of the gene (APEX gene) for human APEX nuclease. Human APEX gene was cloned using human APEX cDNA and a human leukocyte genomic library in bacteriophage vector EMBL-3. We proved that human APEX gene consists of 5 exons spanning 2.64 kilobases and suggested that the gene exists as a single copy in the haploid genome. The boundaries between exon and intron follow the GT/AG rule. The major transcription initiation site was assigned by primer extension analysis to C at 515 nucleotides upstream from the ATG initiation codon. The translation initiation and termination sites locate in the exon II and V, respectively. The 5' flanking region (0.89 kilobase) sequenced lacks typical TATA and CAAT boxes, but contains TATA- and CAAT-like sequences and putative cis-acting regulatory elements such as binding sites for Sp1, AP2 and ATF. A part of the 5' flanking region belongs to a CpG island, which extends to the intron II. The CpG island is thought to be a transcription regulatory region of APEX gene, a housekeeping gene. The promoter activity of the 5' upstream region was analyzed by introducing the region in HeLa cells in an expression construct containing luciferase gene as a reporter gene, and the region from position 130 bp upstream to position 205 bp downstream of the major transcription initiation site was shown to be enough for high promoter activity. Northern hybridization experiments suggested that the gene is expressed ubiquitously in human cells. The locus of APEX gene was mapped to human chromosome 14q11.2-q12 using the in situ hybridization technique.
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PMID:Structure, promoter analysis and chromosomal assignment of the human APEX gene. 808 53

Protein kinase activity was revealed in complex forms of rat liver DNA polymerase alpha containing 3'-5'-exonuclease, primase, helicase, DNA ligase. Protein kinase (mol. mass about 200 kDa) has been partially purified from a specimen of high molecular mass DNA polymerase alpha of nuclear membrane of regenerating liver. The protein kinase activity of the complex form of DNA polymerase alpha was maximal in the cytosol in normal rat liver cells and in the nuclear membrane in dividing cells (40 h after partial hepatectomy). The main phosphokinase properties of this enzyme were determined.
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PMID:[Isolation of protein phosphokinase from a complex form of DNA polymerase alpha from rat liver]. 831 39

APEX nuclease is a mammalian DNA repair enzyme having apurinic/apyrimidinic (AP) endonuclease, 3'-5'-exonuclease, DNA 3' repair diesterase and DNA 3'-phosphatase activities. It is also a redox factor (Ref-1), stimulating DNA binding activity of AP-1 binding proteins such as Fos and Jun. In the present paper, a cDNA for the enzyme was isolated from a rat brain cDNA library using mouse Apex cDNA as a probe and sequenced. The rat Apex cDNA was 1221 nucleotides (nt) long, with a 951-nt coding region. The amino acid sequence of rat APEX nuclease has 98.4% identity with mouse APEX nuclease. Using the rat Apex cDNA as a probe for Northern blot analysis, the size of rat Apex mRNA was shown to be approximately 1.5 kb. Its expression was compared in 9 rat organs on postnatal days 7 and 28. Although Apex mRNA was expressed ubiquitously, the levels varied significantly, suggesting organ- or tissue-specific expression of the Apex gene. The highest level was observed in the testis, relatively high levels in the thymus, spleen, kidney and brain, and the lowest level in the liver. The level of expression at postnatal day 28, with the exception of the testis, was almost the same as or lower in respective organs than that at postnatal day 7. Postnatal developmental changes of Apex mRNA expression in the testis and thymus were further studied. The expression in testis was markedly increased on postnatal days 21 and 28. The expression in thymus increased once at postnatal day 14, and then decreased. The developmental changes of Apex mRNA expression in testis and thymus suggest that APEX nuclease is involved in processes such as recombinational events.
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PMID:cDNA cloning of rat major AP endonuclease (APEX nuclease) and analyses of its mRNA expression in rat tissues. 870 82

Uracil can arise in DNA by misincorporation of dUTP into nascent DNA and/or by cytosine deamination in established DNA. Based on recent findings, both pathways appear to be promoted in the methyl-deficient model of hepatocarcinogenesis. A chronic increase in the ratio dUTP:dTTP with folate/methyl deficiency can result in a futile cycle of excision and reiterative uracil misincorporation leading to premutagenic apyrimidinic (AP) sites, DNA strand breaks, DNA fragmentation and apoptotic cell death. The progressive accumulation of unmethylated cytosines with chronic methyl deficiency will increase the potential for cytosine deamination to uracil and further stress uracil mismatch repair mechanisms. Uracil is removed by a highly specific uracil-DNA glycosylase (UDG) leaving an AP site that is subsequently repaired by sequential action of AP endonuclease, 5'-phosphodiesterase, a DNA polymerase and DNA ligase. Since the DNA polymerases cannot distinguish between dUTP and dTTP, an increase in dUTP:dTTP ratio will promote uracil misincorporation during both DNA replication and repair synthesis. The misincorporation of uracil for thymine (5-methyluracil) may constitute a genetically significant form of DNA hypomethylation distinct from cytosine hypomethylation. In the present study a significant increase in the level of uracil in liver DNA as early as 3 weeks after initiation of folate/methyl deficiency was accompanied by parallel increases in DNA strand breaks, AP sites and increased levels of AP endonuclease mRNA. In addition, uracil was also detected within the p53 gene sequence using UDG PCR techniques. Increased levels of uracil in DNA implies that the capacity for uracil base excision repair is exceeded with chronic folate/methyl deficiency. It is possible that enzyme-induced extrahelical bases, AP sites and DNA strand breaks interact to negatively affect the stability of the DNA helix and stress the structural limits of permissible uracil base excision repair activity. Thus substitution of uracil for thymine induces repair-related premutagenic lesions and a novel form of DNA hypomethylation that may relate to tumor promotion in the methyl-deficient model of hepatocarcinogenesis.
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PMID:Presence and consequence of uracil in preneoplastic DNA from folate/methyl-deficient rats. 939 4

The 5'-exonuclease domains of the DNA polymerase I proteins of Eubacteria and the FEN1 proteins of Eukarya and Archaea are members of a family of structure-specific 5'-exonucleases with similar function but limited sequence similarity. Their physiological role is to remove the displaced 5' strands created by DNA polymerase during displacement synthesis, thereby creating a substrate for DNA ligase. In this paper, we define the substrate requirements for the 5'-exonuclease enzymes from Thermus aquaticus, Thermus thermophilus, Archaeoglobus fulgidus, Pyrococcus furiosus, Methanococcus jannaschii, and Methanobacterium thermoautotrophicum. The optimal substrate of these enzymes resembles DNA undergoing strand displacement synthesis and consists of a bifurcated downstream duplex with a directly abutted upstream duplex that overlaps the downstream duplex by one base pair. That single base of overlap causes the enzymes to leave a nick after cleavage and to cleave several orders of magnitude faster than a substrate that lacks overlap. The downstream duplex needs to be 10 base pairs long or greater for most of the enzymes to cut efficiently. The upstream duplex needs to be only 2 or 3 base pairs long for most enzymes, and there appears to be interaction with the last base of the primer strand. Overall, the enzymes display very similar substrate specificities, despite their limited level of sequence similarity.
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PMID:A comparison of eubacterial and archaeal structure-specific 5'-exonucleases. 1040

During lagging strand DNA replication, the Okazaki fragment maturation machinery is required to degrade the initiator RNA with high speed and efficiency, and to generate with great accuracy a proper DNA nick for closure by DNA ligase. Several operational parameters are important in generating and maintaining a ligatable nick. These are the strand opening capacity of the lagging strand DNA polymerase delta (Pol delta ), and its ability to limit strand opening to that of a few nucleotides. In the presence of the flap endonuclease FEN1, Pol delta rapidly hands off the strand-opened product for cutting by FEN1, while in its absence, the ability of DNA polymerase delta to switch to its 3'-->5'-exonuclease domain in order to degrade back to the nick position is important in maintaining a ligatable nick. This regulatory system has a built-in redundancy so that dysfunction of one of these activities can be tolerated in the cell. However, further dysfunction leads to uncontrolled strand displacement synthesis with deleterious consequences, as is revealed by genetic studies of exonuclease-defective mutants of S. cerevisiae Pol delta. These same parameters are also important for other DNA metabolic processes, such as base excision repair, that depend on Pol delta for synthesis.
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PMID:How the cell deals with DNA nicks. 1565 50

Repair of damaged DNA is of great importance in maintaining genome integrity, and there are several pathways for repair of damaged DNA in almost all organisms. Base excision repair (BER) is a main process for repairing DNA carrying slightly damaged bases. Several proteins are required for BER; these include DNA glycosylases, AP endonuclease, DNA polymerase, and DNA ligase. In some bacteria the single-stranded specific exonuclease, RecJ, is also involved in BER. In this research, six Chlamydiophila pneumoniae (C. pneumoniae) genes, encoding uracil DNA glycosylase (CpUDG), endonuclease IV (CpEndoIV), DNA polymerase I (CpDNApolI), endonuclease III (CpEndoIII), single-stranded specific exonuclease RecJ (CpRecJ), and DNA ligase (CpDNALig), were inserted into the expression vector pET28a. All proteins, except for CpDNALig, were successfully expressed in E. coli, and purified proteins were characterized in vitro. C. pneumoniae BER was reconstituted in vitro with CpUDG, CpEndoIV, CpDNApolI and E. coli DNA ligase (EcDNALig). After uracil removal by CpUDG, the AP site could be repaired by two BER pathways that involved in the replacement of either one (short patch BER) or multiple nucleotides (long patch BER) at the lesion site. CpEndoIII promoted short patch BER via its 5'-deoxyribophosphodiesterase (5'-dRPase) activity, while CpRecJ had little effect on short patch BER. The flap structure generated during DNA extension could be removed by the 5'-exonuclease activity of CpDNApolI. Based on these observations, we propose a probable mechanism for BER in C. pneumoniae.
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PMID:The mechanism of base excision repair in Chlamydiophila pneumoniae. 1608 68

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