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)

T4 RNA ligase joins a 3'-hydroxyl-terminated acceptor oligoribonucleotide to a 5'-phosphate-terminated donor oligoribonucleotide. An analogous reaction with single-strand DNA oligonucleotides would be useful for the synthesis of defined sequences of DNA because it would eliminate the need to synthesize complementary sequences to form the duplex substrates required by DNA ligase. We have studied the model reaction dA(pdA)5 + [5'-32P] (pdT)4pdCp leads to dA(pdA)5 [3' leads to 5'-32P]pdT(pdT)3pdCp and have obtained 40-60% yields at equimolar concentrations (100 microM to 1 mM) of the two substrates. Higher yields have been obtained when acceptor concentrations in excess of those of the donor are used. The use of a 5'-hydroxyl, 3'-hydroxyl terminated acceptor and a 5'-phosphate, 3'-phosphate terminated donor limits the reaction to a unique product. The 3'-phosphate-terminated donor was prepared by using RNA ligase to add a single deoxyribonucleoside 3',5'-bisphosphate donor to an oligo(deoxyribonucleotide) acceptor [Hinton, D.M., Baez, J.A., & Gumport, R.I. (1978) Biochemistry 17, 5091]. The DNA oligomer joining reaction requires low concentrations of ATP and an ATP regenerating system, Mn2+, high levels of nuclease-free RNA ligase (30 microM), and incubation for several days at 17 degrees C. The product of the reaction was characterized by its resistance to alkaline phosphatase, degradation by micrococcal nuclease to the expected product [3'-32P]dAMP, and mobility during high-pressure liquid chromatography on RPC-5. The joining of several other deoxyoligomers was also demonstrated. We anticipate that this reaction of RNA ligase will contribute to its usefulness as a reagent for the synthesis of DNA of defined sequence.
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PMID:T4 ribonucleic acid ligase joins single-strand oligo(deoxyribonucleotides). 698 3

A DNA ligase has been purified from a subnuclear soluble replication complex isolated from adenovirus type 2-infected human KB cells. DNA ligase activity could not be demonstrated using an exogenous template until the complex was dissociated, suggesting that the ligase activity may be a component of the complex. The purified enzyme was free of endonuclease, exonuclease, 5'-nucleotidase, and phosphatase activities, and had a molecular weight of 105 000, as estimated by sedimentation in a glycerol gradient. The ligase requires ATP and a divalent cation for activity. The optimum of the reaction is at pH 7.8 in 50--100 mM Tris-HCl buffer and 10--20 mM MgCl2. Monovalent salts greatly stimulate ligase activity and the optimum was found at 150 mM. The reaction is very sensitive to high temperature; maximum activity was observed at 25--30 degrees C. ATP is the sole required cofactor and NAD, dATP and GTP could not replace the requirement for ATP. The Km for ATP is 60 microM. The Km for DNA is 250 microgram/ml or 1.6 nmol of terminal phosphate/ml and thus the enzyme shows relatively weak affinity for exogenous DNA. The maximum conversion of 32P into a phosphatase-resistant form is approximately 1.3% of the total, whereas T4 ligase, under the same conditions, can convert more than 25% of phosphate into a resistant form.
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PMID:Purification and properties of a DNA ligase from a soluble DNA replication complex. 735 2

Ferric nitrilotriacetate (Fe(3+)-NTA) catalyzes hydrogen peroxide-derived production of hydroxyl radicals, which are known to cause DNA damage. In the present work, Fe(3+)-NTA plus hydrogen peroxide-induced single-strand DNA breaks and repair of the DNA damage were studied in vitro by monitoring DNA damage- and DNA repair-dependent conformational changes of pUC18 plasmid DNA. Single-strand DNA breaks were induced in the pUC18 DNA by Fe(3+)-NTA plus hydrogen peroxide in a dose-dependent fashion. Induction of the DNA damage was inhibited by deferoxamine mesylate (an iron chelator) and by hydroxyl radical scavengers such as dimethyl sulfoxide (DMSO), D-mannitol and ethanol indicating that the DNA damage was caused by hydroxyl radicals which were generated by reaction of Fe(3+)-NTA with hydrogen peroxide. The oxygen radical-induced single-strand DNA breaks were repaired partly (more than 50%) by incubating the damaged DNA at 37 degrees C for 3 h with a partially purified preparation of APEX nuclease (a multifunctional DNA repair enzyme), DNA polymerase beta, four deoxyribonucleoside triphosphates, T4 DNA ligase and ATP. Analyses of the partially purified preparation of APEX nuclease revealed that a 45-kDa protein as well as APEX nuclease in the preparation were involved in the repair of the single-strand DNA breaks. APEX nuclease was suggested to initiate the repair by removing 3' termini blocked by the nucleotide fragments and also by incising the 5' side of AP sites. The 45-kDa protein was suggested to be required for removal of the 5' tags such as 5'-terminal deoxyribose phosphate residues produced by the action of APEX nuclease on AP sites.
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PMID:Oxygen radical-induced single-strand DNA breaks and repair of the damage in a cell-free system. 756 64

Pronuclear injection is currently the most often used method to make transgenic animals, but in some animal species it is temporally restrictive due to difficulty in visualizing pronuclei. However, the injection of construct DNA into the cytoplasm does not result in transgenesis. The production of transgenic mice by a cytoplasmic microinjection technique of polylysine complexed DNA into pronuclear stage zygotes is described. Transgenic mice were produced from cytoplasmic microinjection of mixtures of a 5.3 kb linearized DNA and poly-L-lysine (degree of polymerization = 51). Effects on transgenic frequency of both the lysine to phosphate ratio of polylysine to DNA and DNA concentration were studied. About 12.8% of the pups born from zygotes cytoplasmically microinjected with a polylysine/DNA mixture having a lysine to phosphate ratio (L:P) of 1:1 at a DNA concentration of 50 micrograms ml-1 were transgenic. The transgenic frequency for the pronuclear microinjection positive control of DNA alone was 21.7%. No transgenic pups were born from microinjection of DNA alone into the cytoplasm. Complexes of polylysine/DNA were detected using agarose gel electrophoresis at the conditions which produced transgenic mice. The presence of polylysine with construct DNA altered the in vitro activities of restriction endonuclease and DNA ligase on the construct DNA. The production of transgenic animals using DNA and polylysine in the absence of any other signal protein suggests that a DNA/polylysine complex but not DNA alone can act as a substrate for transgenesis from the cytoplasm.
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PMID:Transgenesis in mice by cytoplasmic injection of polylysine/DNA mixtures. 758 16

We have used 1H NMR spectroscopy to determine the structural changes induced in the DNA oligomer d(5'-GCGTACGC-3')2 upon conversion of the 4'-hydroxy-methyl-4,5',8-trimethylpsoralen-DNA furan-side monoadduct (MAf) to the interstrand cross-link (XL). The MAf is a photochemical intermediate on the path to interstrand XL and has the psoralen intercalated into the helix. The local DNA structure is distorted in both adducts, but it returns to normal within three base pairs. The formation of XL requires displacement of the psoralen toward the initially unmodified strand, accompanied by a change in the hybridization of the thymine C-5 and C-6 carbons and a change in the local helix twist. The MAf is intercalated in the helix. There is no significant bend in the helix axis of either the MAf or XL. There are significant changes in the local helix dynamics upon photoadduct formation that may be recognized by cellular DNA repair enzyme systems. We hypothesize that the repair enzymes target lesions by detecting the conformational flexibility of the sugar-phosphate backbone induced by DNA-damaging agents.
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PMID:DNA structural reorganization upon conversion of a psoralen furan-side monoadduct to an interstrand cross-link: implications for DNA repair. 789 69

DNA topoisomerase I (topo I) is a member of a group of essential nuclear enzymes which control and modify the topological state of DNA and is recognized as the target for anticancer drugs. During the course of the catalytic activity of topo I, a covalent bond is formed between a tyrosine group at the active site of the enzyme and a 3' phosphate group along the DNA backbone. This chemical reaction resembles the protein kinase-mediated tyrosine phosphorylation process. We assumed, therefore, that tyrphostins, potent and selective blockers of protein tyrosine kinases, might affect topo I activity. We found that of three derivatives of tyrphostins (AG-555, AG-18, and AG-213) that inhibited topo I activity in an in vitro assay, AG-555 was the most active. Examination of the mechanism by which these compounds act as topo I inhibitors revealed that AG-555 blocked the binding of this enzyme to the DNA due to its interaction with the topo I enzyme. We showed that its mode of action differed from that observed for camptothecin, a known topo I inhibitor. However, AG-555 did not affect the activity of other major DNA binding enzymes (i.e., DNA ligase, DNA polymerase I, and reverse transcriptase). This study suggests that tyrphostins may serve as a new class of topo I inhibitors, and these results also present additional explanations for their antiproliferative effect.
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PMID:Inhibition of topoisomerase I activity by tyrphostin derivatives, protein tyrosine kinase blockers: mechanism of action. 792 31

Deinococcus radiodurans is the most radioresistant bacterium discovered to date. Recently it has been demonstrated that this organism contains the DNA repair enzyme uracil-DNA glycosylase and an apurinic/apyrimidinic (AP) endonuclease that may function as part of a DNA base excision repair pathway. We demonstrate here that a DNA deoxyribophosphodiesterase activity that acts on incised AP sites in DNA to remove deoxyribose-phosphate groups is found in lysates prepared from D. radiodurans cells. The partially purified activity was found to be smaller in size than the E. coli dRpase activity, with an estimated molecular weight of 25-30 kDa. In addition, an activity that recognizes and cleaves DNA containing thymine glycols was also detected, with a molecular weight of approximately 30 kDa. This enzyme may be analogous to the thymine glycol glycosylase/AP lyase endonuclease III of E. coli.
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PMID:DNA deoxyribophosphodiesterase and an activity that cleaves DNA containing thymine glycol adducts in Deinococcus radiodurans. 818 99

Treatment of plasmid pBR322 with Fe2-(HPTB)(OH)(NO3)4(HPTB = N,N,N',N'-tetrakis(2-benzimidazolylmethyl)-2-hydroxy-1,3-diaminopr opane) and H2O2 or O2 and a reductant (dithiothreitol or ascorbate) results in double-stranded cleavage of the plasmid. The linearization of supercoiled pBR322 by this complex is not inhibited by hydroxyl radical scavengers. On the other hand, the linearized pBR322 is efficiently religated by T4 DNA ligase, and the presence of 3'-OH and 5'-OPO3 ends is corroborated by 3'- and 5'-end-labeling studies. These observations indicate that cleavage results from hydrolysis of the DNA-phosphate backbone, which is proposed to occur by nucleophilic attack of the bound peroxide on the phosphodiester. Double-stranded cleavage by the Fe2(HPTB)(OH)(NO3)4/H2O2 adduct preferentially occurs between bp 3489 and 3485 of pBR322.
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PMID:Double-stranded cleavage of pBR322 by a diiron complex via a "hydrolytic" mechanism. 829 May 64

During the development of a procedure for the isolation of total genomic DNA from filamentous fungi (Rodriguez, R. J., and Yoder, O.C., Exp. Mycol. 15, 232-242, 1991) a cell fraction was isolated which inhibited the digestion of DNA by restriction enzymes. After elimination of DNA, RNA, proteins, and lipids, the active compound was purified by gel filtration to yield a single fraction capable of complete inhibition of restriction enzyme activity. The inhibitor did not absorb uv light above 220 nm, and was resistant to alkali and acid at 25 degrees C and to temperatures as high as 100 degrees C. More extensive analyses demonstrated that the inhibitor was also capable of inhibiting T4 DNA ligase and TaqI DNA polymerase, but not DNase or RNase. Chemical analyses indicated that the inhibitor was devoid of carbohydrates, proteins, lipids, and nucleic acids but rich in phosphorus. A combination of nuclear magnetic resonance, metachromatic shift of toluidine blue, and gel filtration indicated that the inhibitor was a polyphosphate (polyP) containing approximately 60 phosphate molecules. The mechanism of inhibition appeared to involve complexing of polyP to the enzymatic proteins. All species of Colletotrichum analyzed produced polyP equivalent in chain length and concentration. A modification to the original DNA extraction procedure is described which eliminates polyP and reduces the time necessary to obtain DNA of sufficient purity for restriction enzyme digestion and TaqI polymerase amplification.
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PMID:Polyphosphate present in DNA preparations from filamentous fungal species of Colletotrichum inhibits restriction endonucleases and other enzymes. 838 89

Vaccinia DNA ligase and mammalian DNA ligases II and III comprise a distinct subgroup of structurally homologous enzymes within the eukaryotic DNA ligase family. The specificity and fidelity of the viral enzyme were investigated using purified recombinant ligase and synthetic duplex DNA substrates containing a single strand discontinuity. Vaccinia ligase catalyzed efficient strand joining on nicked DNAs in the presence of magnesium and ATP (Km = 95 microM). dATP, ITP, AMPPCP, 3'dATP, and ATP alpha S could not substitute for ATP; of these, 3'dATP and ATP alpha S were inhibitors of ligation. The vaccinia enzyme was unable to seal strands across a 1 nt (nucleotide) or 2 nt gap. Ligase action at a 1 nt gap resulted in accumulation of high levels of the normally undetectable DNA-adenylate reaction intermediate. In contrast, no DNA-adenylate was formed at a 2 nt gap. A native gel mobility shift assay showed that vaccinia DNA ligase was capable of discriminating between nicked and gapped DNAs at the substrate binding step. The ligase was fairly tolerant of mismatches at a nick involving the 5' phosphate donor terminus but was inhibited strongly by mismatches at the 3' OH acceptor terminus, especially by purine.-purine mispairs. These findings underscore the importance of a proper 3' OH terminus in substrate recognition and reaction chemistry but also raise the possibility that ligase may generate mutations during DNA repair by sealing DNA molecules with mispaired ends. Ligase was inhibited by several DNA binding drugs, including, in order of decreasing potency, distamycin, ethidium bromide, and actinomycin. Strand joining by purified ligase was not affected by etoposide, a drug that inhibits vaccinia virus replication in vivo and which depends on the presence of vaccinia ligase for its antiviral action.
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PMID:Vaccinia virus DNA ligase: specificity, fidelity, and inhibition. 851 71

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