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Query: EC:3.1.30.2 (endonuclease)
 18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The Escherichia coli UvrB and UvrC proteins play key roles in DNA damage processing and incisions during nucleotide excision repair. To study the DNA structural requirements and protein-DNA intermediates formed during these processes, benzo[a]pyrene diol epoxide-damaged and structure-specific 50-base pair substrates were constructed. DNA fragments containing a preexisting 3' incision were rapidly and efficiently incised 5' to the adduct. Gel mobility shift assays indicated that this substrate supported UvrA dissociation from the UvrB-DNA complex, which led to efficient incision. Experiments with a DNA fragment containing an internal noncomplementary 11-base region surrounding the benzo[a]pyrene diol epoxide adduct indicated that UvrABC nuclease does not require fully duplexed DNA for binding and incision. In the absence of UvrA, UvrB (UvrC) bound to an 11-base noncomplementary region containing a 3' nick (Y substrate), forming a stable protein-DNA complex (Kd approximately 5-10 nM). Formation of this complex was absolutely dependent upon UvrC. Addition to this complex of ATP, but not adenosine 5'-(beta,gamma-iminotriphosphate) or adenosine 5'-(beta, gamma-methylene)triphosphate, caused incision three or four nucleotides 5' to the double strand-single strand junction. The ATPase activity of native UvrB is activated upon interaction with UvrC and enhanced further by the addition of Y substrate. Incision of this Y structure occurs even without DNA damage. Thus the UvrBC complex is a structure-specific, ATP-dependent endonuclease.
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PMID:Formation of DNA repair intermediates and incision by the ATP-dependent UvrB-UvrC endonuclease. 903 May 38

Holliday junctions in DNA are generated as a product of homologous recombination events. To test the hypothesis that human p53 may bind to Holliday junctions, synthetic junctions with four approximately 75-base pair (Hol75) or approximately 565-base pair (Hol565) arms were generated. As seen by electron microscopy, under conditions in which 50-61% of the Hol565 DNAs were bound by p53, 80-96% of the p53 was located specifically at the junction with, in the latter case, only 4% of the p53 visualized at the DNA ends or along the arms. Given the large number of potential binding sites, this represents very high specificity for the junctions. Gel retardation assays using the Hol75 DNA confirm these observations, and indicate that the tight junction complexes have a half-life of greater than 4 h. The binding of p53 to three-way junctions is severalfold less than to four-way junctions. Addition of p53 greatly increases the rate of resolution of the Hol75 DNA by T4 endonuclease VII and T7 endonuclease I, two enzymes known to cleave such junctions. This latter finding further confirms the interaction of p53 with Holliday junctions and suggests that p53 binding facilitates their resolution in vivo.
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PMID:Human p53 binds Holliday junctions strongly and facilitates their cleavage. 905 58

Restriction endonuclease EcoRV has been reported to be unable to distinguish its specific DNA site, GATATC, from non-specific DNA sites in the absence of the catalytic cofactor Mg2+, and thus to exercise sequence specificity solely in the catalytic step. In contrast, we show here that under appropriate conditions of pH and salt concentration, specific complexes with oligonucleotides containing the GATATC site can be detected by either filter-binding or gel-retardation. Equilibrium binding constants (K(A)) are easily measured by both direct equilibrium and equilibrium-competition methods. The preference for "specific" over "non-specific" binding at pH 7 in the absence of divalent cations is about 1000-fold (per mole of oligonucleotide) or 12,000-fold (per mole of binding sites). Ethylation-interference footprinting shows that the "specific" complex includes strong contacts to the phosphate groups GpApTpApTC. Specific DNA binding is strongly pH-dependent, decreasing about 15-fold for each increase of one pH unit above pH 6, but non-specific binding is not; thus, binding specificity decreases with increasing pH. Gel retardation and filter-binding at pH < or = 7 yield essentially identical values of K(A) for specific-site binding, but at pH > 7 gel retardation significantly underestimates K(A). Specific-site binding is stimulated about 700-fold by Ca2+ (not a cofactor for cleavage), but with non-cleavable 3'-phosphorothiolate and 4'-thiodeoxyribose derivatives whose response to Ca2+ is similar to that of the parent oligonucleotide, Mg2+ stimulates binding only fourfold and twofold, respectively. Thus, binding specificity is not dramatically enhanced by Mg2+. Taking into account discrimination in binding and in the first-order rate constant for phosphodiester bond scission, the overall discrimination exercised against the incorrect site GTTATC is about 10(7)-fold. EcoRV endonuclease is thus not a "new paradigm" for site-specific interaction without binding specificity, but like other type II restriction endonucleases achieves sequence specificity by discriminating both in DNA binding and in catalysis.
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PMID:Specific binding by EcoRV endonuclease to its DNA recognition site GATATC. 919 2

Endonuclease I is a DNA junction-selective resolving enzyme from bacteriophage T7. Using a nuclease-defective mutant that retains normal binding to DNA we show that the protein binds to four-way DNA junctions as a dimer, in common with other junction-resolving enzymes studied. Gel filtration and chemical crosslinking indicate that endonuclease I also exists in free solution as a dimer together with a tetramer and higher molecular mass aggregates. However, in marked contrast with other junction-resolving enzymes, there is no detectable subunit exchange under normal conditions. Only by exposure to 6 M urea could we induce subunit exchange, and this was used to generate heterodimeric species containing one active and one inactive subunit. Using a supercoil-stabilised cruciform substrate we demonstrate that an active subunit of endonuclease I can act as a junction-specific nuclease in a heterodimeric combination with an inactive subunit. However, the two subunits of a fully active homodimeric enzyme each cleave the phosphodiester backbone of a cruciform within the lifetime of the DNA-protein complex.
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PMID:The junction-resolving enzyme T7 endonuclease I: quaternary structure and interaction with DNA. 923 19

Gel shift analysis reveals [Lagunavicius, A., & Siksnys, V. (1997) Biochemistry 36 (preceding paper in this issue)] that at pH 8.3 in the absence of Mg2+, MunI restriction endonuclease exhibits little DNA binding specificity, as compared with the D83A and E98A mutants of MunI. This suggests that charged carboxylate residue(s) influence the DNA binding specificity of MunI. In our efforts to establish the determinants of MunI binding specificity, we investigated the possible role of the ionic milieu, and we found that lowering pH or elevating Ca2+ levels per se induces specific DNA recognition by WT MunI. In contrast to the binding experiments at pH 8.3, gel shift analysis at pH 6.5 indicated tight sequence-specific binding of WT MunI in the absence of Mg2+, suggesting that protonation of active site carboxylate residue(s) which manifest anomalously high pKa value(s) control binding specificity. Interestingly, Ca2+ ion concentrations, which did not support DNA cleavage by MunI also induced DNA binding specificity in WT MunI at pH 8.3. To explore possible structural changes upon DNA binding, we then used a limited proteolysis technique. Trypsin cleavage of MunI-DNA complexes indicated that in the presence of cognate DNA the MunI restriction endonuclease became resistant to proteolytic cleavage, suggesting that binding of specific DNA induced a structural change. CD measurements confirmed this observation, suggesting minor secondary structural differences between complexes of MunI with cognate and noncognate DNA. These results therefore suggest that binding of MunI to its recognition sequence triggers a conformational transition that correctly juxtaposes active site carboxylate residues, which then chelate Mg2+ ions. In the absence of Mg2+ ions, at pH 8.3, conditions in which carboxylate groups would be expected to be completely ionized, electrostatic repulsion between charged carboxylates and phosphate oxygens is enhanced such as to interfere with specific DNA binding. Elimination of such repulsive constraints by replacement of carboxylate residues, by lowering pH, or by metal ion binding, then promotes MunI binding specificity.
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PMID:DNA binding specificity of MunI restriction endonuclease is controlled by pH and calcium ions: involvement of active site carboxylate residues. 928 52

Reactive oxygen species have been shown to generate mutagenic lesions in DNA. One of the most abundant lesions in both nuclear and mitochondrial DNA is 7,8-dihydro-8-oxoguanine (8-oxoG). We report here the partial purification and characterization of a mitochondrial oxidative damage endonuclease (mtODE) from rat liver that recognizes and incises at 8-oxoG and abasic sites in duplex DNA. Rat liver mitochondria were purified by differential and Percoll gradient centrifugation, and mtODE was extracted from Triton X-100-solubilized mitochondria. Incision activity was measured using a radiolabeled double-stranded DNA oligonucleotide containing a unique 8-oxoG, and reaction products were separated by polyacrylamide gel electrophoresis. Gel filtration chromatography predicts mtODE's molecular mass to be between 25 and 30 kDa. mtODE has a monovalent cation optimum between 50 and 100 mM KCl and a pH optimum between 7.5 and 8. mtODE does not require any co-factors and is active in the presence of 5 mM EDTA. It is specific for 8-oxoG and preferentially incises at 8-oxoG:C base pairs. mtODE is a putative 8-oxoG glycosylase/lyase enzyme, because it can be covalently linked to the 8-oxoG oligonucleotide by sodium borohydride reduction. Comparison of mtODE's activity with other known 8-oxoG glycosylases/lyases and mitochondrial enzymes reveals that this may be a novel protein.
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PMID:An oxidative damage-specific endonuclease from rat liver mitochondria. 934 Nov 84

McrBC is a GTP-dependent restriction endonuclease of E. coli K12, selectively directed against DNA containing modified cytosine residues. McrB, one of its components, is responsible for the binding and, together with McrC, for the cleavage of DNAs containing two 5'-Pu(m)C sites separated by 40-80 base pairs. Gel retardation assays with wild-type and mutant McrB reveal that (i) single 5'-Pu(m)C sites in DNA can be sufficient to elicite binding by McrB. Binding to such substrates is, however, weak and strongly dependent on the sequence context of Pu(m)C sites. (ii) Strong DNA binding (K(ass) approximately 10(7)M[-1]) is dependent on the presence of at least two Pu(m)C sites, even if they are separated by less than 40 bp, and is modulated by the sequence context (-A(m)CCGGT- --> -A(m)CT(C/G)AGT- --> -AGG(m)CCT- --> -AAG(m)CTT-). (iii) DNA binding by McrB is accompanied by formation of distinct multiple complexes whose distribution is modulated by GTP. (iv) McrC, which cannot bind DNA by itself, moderately stimulates the DNA binding of McrB and converts McrB-DNA complexes to large aggregates. (v) Deletion of the C-terminal half of McrB, which harbors the three consensus sequences characteristic for guanine nucleotide binding proteins, leads to protein inactive in GTP binding and/or hydrolysis and in McrC-assisted DNA cleavage; the protein, however, remains fully competent in DNA binding. (vi) Mutations in McrB which lead to a reduction in GTP binding and/or hydrolysis can affect DNA binding, suggesting that the two activities are coupled in the full-length protein.
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PMID:The recognition of methylated DNA by the GTP-dependent restriction endonuclease McrBC resides in the N-terminal domain of McrB. 934 6

Bursts of free radicals produced by ionization of water in close vicinity to DNA can produce clusters of opposed DNA lesions and these are termed multiply damaged sites (MDS). How MDS are processed by the Escherichia coli DNA glycosylases, endonuclease (endo) III and endo VIII, which recognize oxidized pyrimidines, is the subject of this study. Oligonucleotide substrates were constructed containing a site of pyrimidine damage or an abasic (AP) site in close proximity to a single nucleotide gap, which simulates a free radical-induced single-strand break. The gap was placed in the opposite strand 1, 3 or 6 nt 5' or 3' of the AP site or base lesion. Endos III and VIII were able to cleave an AP site in the MDS, no matter what the position of the opposed strand break, although cleavage at position one 5' or 3' was reduced compared with cleavage at positions three or six 5' or 3'. Neither endo III nor endo VIII was able to remove the base lesion when the gap was positioned 1 nt 5' or 3' in the opposite strand. Cleavage of the modified pyrimidine by endo III increased as the distance increased between the base lesion and the opposed strand break. With endo VIII, however, DNA breakage at the site of the base lesion was equivalent to or less when the gap was positioned 6 nt 3' of the lesion than when the gap was 3 nt 3' of the lesion. Gel mobility shift analysis of the binding of endo VIII to an oligonucleotide containing a reduced AP (rAP) site in close opposition to a single nucleotide gap correlated with cleavage of MDS substrates by endo VIII. If the strand break in the MDS was replaced by an oxidized purine, 7,8-dihydro-8-oxoguanine (8-oxoG), neither endo VIII cleavage nor binding were perturbed. These data show that processing of oxidized pyrimidines by endos III and VIII was strongly influenced by the position and type of lesion in the opposite strand, which could have a significant effect on the biological outcome of the MDS lesion.
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PMID:Multiply damaged sites in DNA: interactions with Escherichia coli endonucleases III and VIII. 946 50

Our previous study demonstrated that an antibody against single-stranded DNA could detect apoptotic cells [Naruse et al. (1994) Histochemistry 101, 73-78]. In this paper we describe the development of an improved method for the production of the antibody and investigations into the antigenic determinants of the antibody so that it could be of practical use for detecting apoptotic cells. Rabbits, hyperimmunized with complexes of alkaline-denatured calf thymus DNA and methylated bovine serum albumin, produced an IgG antibody to single-stranded DNA. Analysis by sandwich ELISA using various naturally occurring nucleic acids revealed that the antibody was specific to single-stranded DNA. Furthermore, using synthetic polymers in the assay, it was found that the antibody could recognize single-stranded DNA with various base sequences. Gel electrophoresis retardation assays, with synthetic oligodeoxynucleotides with differing lengths of single-stranded DNA, indicated that a hexadeoxynucleotide constituted the minimum size of the antigenic determinants, and suggested that the antibody probably consists of several antibodies which recognize hexadeoxynucleotides with various base sequences. Western blot analysis demonstrated that the antibody can recognize both a DNA ladder and oligonucleosomes prepared from rat liver nuclei with endogenous endonuclease. The present findings demonstrate that this antibody is a useful tool for detecting apoptotic cells.
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PMID:Antibody against single-stranded DNA useful for detecting apoptotic cells recognizes hexadeoxynucleotides with various base sequences. 953 33

The inhibition of restriction endonuclease cleavage by a series of bisquaternary ammonium derivatives (BQA-derivatives) which bind to the minor groove of DNA has been studied. The derivatives considered included six sequence-selective binders (SN 6570, SN 6999, SN 6050, SN 6132, SN 6131 and SN 18071) and four non-specific binders (SN 6113, SN 5754, SN 6324 and SN 4094) and can be distinguished by their activity on restriction endonucleases. Digestion experiments with pUC19 DNA were monitored electrophoretically using the transition of the covalently closed circular (ccc) DNA into the linear double stranded (lds) one. Only the sequence-specific binders inhibit the cleavage activity of restriction endonucleases EcoRI, SspI and DraI with four and six dAdT-base pairs within their restriction sites, while the activity of SalI and BamHI with less than four dAdT-sequences was unaffected. In contrast, the non-specific binding ligands were incapable of suppressing enzyme digestion. The inhibition of the restriction endonuclease PvuII indicates that ligand binding in close vicinity to the cleavage sites is also involved in the enzyme inhibition. The dAdT-content in proximity to the palindromic sequences of three DraI cutting sites in pUC19 DNA explains why the derivative SN 6053 protects these sequences in different manners. Gel shift experiments indicated that BQA-derivatives inhibit the DNA-enzyme complex formation if the ligand was added to the DNA before the enzyme. In contrast, complex formation between DNA and enzyme remained unchanged when the enzyme was added first.
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PMID:Sequence specific modulation of DNA restriction enzyme cleavage by minor groove binders. 962 46


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