EC:5.99.1.2 - FACTA Search

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Query: EC:5.99.1.2 (topoisomerase)
9,166 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

DNA gyrase, an essential type II topoisomerase, mediates negative supercoiling of the bacterial chromosome, thereby affecting the processes of DNA replication, transcription, recombination and repair. The gyrB gene from the Gram-negative soil bacterium Myxococcus xanthus was sequenced. The sequence predicts a protein of 815 amino acid residues displaying significant homology to all known GyrB proteins. A 6-His-GyrB fusion protein was overexpressed in Escherichia coli and purified to near homogeneity using affinity chromatography on Ni-nitrilotriacetic acid-agarose and novobiocin-Sepharose columns. The fusion protein bound novobiocin and cross-reacted with anti-E. coli GyrB antibodies, indicating structural and functional similarities to the E. coli DNA GyrB. The gene was mapped to the region of the origin of replication (oriC) of M. xanthus.
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PMID:Molecular analysis of the DNA gyrB gene from Myxococcus xanthus. 963 35

Mutations in the WRN gene result in Werner syndrome, an autosomal recessive disease in which many characteristics of aging are accelerated. A probable role in some aspect of DNA metabolism is suggested by the primary sequence of the WRN gene product. A recombinant His-tagged WRN protein (WRNp) was overproduced in insect cells using the baculovirus system and purified to near homogeneity by several chromatographic steps. This purification scheme removes both nuclease and topoisomerase contaminants that persist following a single Ni(2+)affinity chromatography step and allows for unambiguous interpretation of WRNp enzymatic activities on DNA substrates. Purified WRNp has DNA-dependent ATPase and helicase activities consistent with its homology to the RecQ subfamily of proteins. The protein also binds with higher affinity to single-stranded DNA than to double-stranded DNA. However, WRNp has no higher affinity for various types of DNA damage, including adducts formed during 4NQO treatment, than for undamaged DNA. Our results confirm that WRNp has a role in DNA metabolism, although this role does not appear to be the specific recognition of damage in DNA.
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PMID:Enzymatic and DNA binding properties of purified WRN protein: high affinity binding to single-stranded DNA but not to DNA damage induced by 4NQO. 1044 47

To probe the mechanism of the reversible DNA phosphodiester bond cleavage and religation mechanism of the type I topoisomerase from vaccinia virus, we have synthesized DNA substrates carrying a single nonbridging Rp- or Sp-phosphorothioate (Ps) modification at the scissile phosphodiester (Pd) bond. Analysis of the stereochemical outcome of the net cleavage and rejoining reaction established that the reaction proceeds with retention of configuration, as expected for a double-displacement mechanism. Single-turnover kinetic studies on irreversible strand cleavage using 18/24 mer suicide substrates showed thio effects (k(Pd)/k(Ps)) of 340- and 30-fold for the Rp-Ps and Sp-Ps stereoisomers, respectively, but approximately 10-fold smaller thio effects for the reverse single-turnover religation reaction (Rp-Ps = 30 and Sp-Ps = 3). As compared to the smaller suicide cleavage substrates, approach-to-equilibrium cleavage studies using 32/32 mer substrates showed 7-9-fold smaller thio effects on cleavage, similar effects on religation, and the same ratio of the Rp to Sp thio effect as the suicide cleavage reaction ( approximately 10). In general, thio effects of 2.4-7.2-fold on the cleavage equilibrium are observed for the wild-type and H265A enzymes, suggesting differences in the interactions of the enzyme with the nonbridging sulfur in the noncovalent and covalent complexes. Studies of the cleavage, religation, and approach-to-equilibrium reactions catalyzed by the H265A active site mutant revealed a stereoselective, 11-fold decrease in the Rp-thio effect on cleavage and religation as compared to the wild-type enzyme. This result suggests that His-265 interacts with the nonbridging pro-Rp oxygen in the transition state for cleavage and religation, consistent with the arrangement of this conserved residue in the crystal structure of the human topoisomerase-DNA complex. In general, the greatest effect of thio substitution and the H265A mutation is to destabilize the transition state, with smaller effects on substrate binding. The interaction of His-265 with the pro-Rp nonbridging oxygen is inconsistent with the proposal that this conserved residue acts as a general acid in the strand cleavage reaction.
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PMID:Stereochemical outcome and kinetic effects of Rp- and Sp-phosphorothioate substitutions at the cleavage site of vaccinia type I DNA topoisomerase. 1082 30

Vaccinia topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at sites containing the sequence 5'-CCCTT downward arrow. The covalently bound topoisomerase can religate the CCCTT strand to a 5'-OH-terminated polynucleotide or else transfer the strand to a non-DNA nucleophile such a water or glycerol. Here, we report that vaccinia topoisomerase also catalyzes strand transfer to hydrogen peroxide. The observed alkaline pH-dependence of peroxidolysis is consistent with enzyme-mediated attack by peroxide anion on the covalent intermediate. The reaction displays apparent first-order kinetics. From a double-reciprocal plot of k(obs) versus [H(2)O(2)] at pH 10, we determined a rate constant for peroxidolysis of 6.3 x 10(-)(3) s(-)(1). This rate is slower by a factor of 200 than the rate of topoisomerase-catalyzed strand transfer to a perfectly aligned 5'-OH DNA strand but is comparable to the rate of DNA strand transfer across a 1-nucleotide gap. Strand transfer to 2% hydrogen peroxide is 300 times faster than strand transfer to 20% glycerol and approximately 2000 times faster than topoisomerase-catalyzed hydrolysis of the covalent intermediate. Hydroxylamine is also an effective nucleophile in topoisomerase-mediated strand transfer (k(obs) = 6.4 x 10(-)(4) s(-)(1)). The rates of the peroxidolysis, hydroxylaminolysis, glycerololysis, and hydrolysis reactions catalyzed by the mutant enzyme H265A were reduced by factors of 100-700, in accordance with the 100- to 400-fold rate decrements in DNA cleavage and religation by H265A. We surmise that vaccinia topoisomerase catalyzes strand transfer to DNA and non-DNA nucleophiles via a common reaction pathway in which His-265 stabilizes the scissile phosphate in the transition state rather than acting as a general acid or base.
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PMID:DNA strand transfer catalyzed by vaccinia topoisomerase: peroxidolysis and hydroxylaminolysis of the covalent protein-DNA intermediate. 1082 56

Type IB topoisomerases and tyrosine recombinases are structurally homologous strand transferases that act through DNA-(3'-phosphotyrosyl)-enzyme intermediates. A constellation of conserved amino acids (Arg-130, Lys-167, Arg-223, and His-265 in vaccinia topoisomerase) catalyzes transesterification of tyrosine to the scissile phosphodiester. We used 5'-bridging phosphorothiolate-modified DNAs to implicate Lys-167 as a general acid catalyst. The lower pKa of the 5'-S leaving group versus 5'-O restored activity to the K167A mutant, whereas there was no positive thio effect for mutants R223A and H265A. The lysine is located atop a flexible hairpin loop, and it shifts into the minor groove upon DNA binding. Coupling of conformational changes in a general acid loop to covalent catalysis of phosphoryl transfer is one of several mechanistic features shared by the topoisomerase/recombinase and protein phosphatase superfamilies.
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PMID:Catalytic mechanism of DNA topoisomerase IB. 1091 97

Clones for DNA topoisomerase IIalpha and beta (topo-IIalpha and beta) were isolated from a cDNA expression library of chicken MSB-1 cells by immunoscreening. The deduced sequences of chicken topo-IIalpha and beta were about 80% identical for the N-terminal ATPase domain and the central core domain but only 37% for the C-terminal domain. Polyclonal antibodies were raised against C-terminal polypeptides specific to topo-IIalpha and beta. Indirect immunofluorescence with these antibodies to chicken embryonic fibroblasts demonstrated that topo-IIalpha was distributed in discrete intranuclear spots, which coincided with sites of DNA replication as indicated by incorporation of 5-bromo-2'-deoxyuridine, whereas topo-IIbeta was distributed rather uniformly within a nucleus. Examination of intranuclear distribution patterns of chimeric constructs between topo-IIalpha and beta suggested that a sequence region (residues 1280-1294) in the C-terminal domain of topo-IIalpha was effective in co-localization with sites of DNA replication. This region consists of a QTxhxF motif (x, any residue; h, hydrophobic residue) followed by a KR-rich sequence, which resembles those found in several proteins known to associate with proliferating cell nuclear antigen (PCNA) or targeted to the replication factory. An in vitro pull-down assay with glutathione-S-transferase-PCNA and (His)6-tagged truncated forms of topo-IIalpha demonstrated that polypeptides containing the above region (residues 1158-1553 or 1158-1294) bound to PCNA in vitro.
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PMID:Co-localization of chicken DNA topoisomerase IIalpha, but not beta, with sites of DNA replication and possible involvement of a C-terminal region of alpha through its binding to PCNA. 1145 53

Mutations in DNA gyrase and/or topoisomerase IV genes are frequently encountered in quinolone-resistant mutants of Streptococcus pneumoniae. To investigate the mechanism of their effects at the molecular and cellular levels, we have used an Escherichia coli system to overexpress S. pneumoniae gyrase gyrA and topoisomerase IV parC genes encoding respective Ser81Phe and Ser79Phe mutations, two changes widely associated with quinolone resistance. Nickel chelate chromatography yielded highly purified mutant His-tagged proteins that, in the presence of the corresponding GyrB and ParE subunits, reconstituted gyrase and topoisomerase IV complexes with wild-type specific activities. In enzyme inhibition or DNA cleavage assays, these mutant enzyme complexes were at least 8- to 16-fold less responsive to both sparfloxacin and ciprofloxacin. The ciprofloxacin-resistant (Cip(r)) phenotype was silent in a sparfloxacin-resistant (Spx(r)) S. pneumoniae gyrA (Ser81Phe) strain expressing a demonstrably wild-type topoisomerase IV, whereas Spx(r) was silent in a Cip(r) parC (Ser79Phe) strain. These epistatic effects provide strong support for a model in which quinolones kill S. pneumoniae by acting not as enzyme inhibitors but as cellular poisons, with sparfloxacin killing preferentially through gyrase and ciprofloxacin through topoisomerase IV. By immunoblotting using subunit-specific antisera, intracellular GyrA/GyrB levels were a modest threefold higher than those of ParC/ParE, most likely insufficient to allow selective drug action by counterbalancing the 20- to 40-fold preference for cleavable-complex formation through topoisomerase IV observed in vitro. To reconcile these results, we suggest that drug-dependent differences in the efficiency by which ternary complexes are formed, processed, or repaired in S. pneumoniae may be key factors determining the killing pathway.
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PMID:Quinolone resistance mutations in Streptococcus pneumoniae GyrA and ParC proteins: mechanistic insights into quinolone action from enzymatic analysis, intracellular levels, and phenotypes of wild-type and mutant proteins. 1160 Mar 69

Type IB topoisomerases cleave and rejoin DNA through a DNA-(3'-phosphotyrosyl)-enzyme intermediate. A constellation of conserved amino acids (Arg-130, Lys-167, Arg-223, and His-265 in vaccinia topoisomerase) catalyzes the attack of the tyrosine nucleophile (Tyr-274) at the scissile phosphodiester. Previous studies implicated Arg-223 and His-265 in transition state stabilization and Lys-167 in proton donation to the 5'-O of the leaving DNA strand. Here we find that Arg-130 also plays a major role in leaving group expulsion. The rate of DNA cleavage by vaccinia topoisomerase mutant R130K, which was slower than wild-type topoisomerase by a factor of 10(-4.3), was stimulated 2600-fold by a 5'-bridging phosphorothiolate at the cleavage site. The catalytic defect of the R130A mutant was also rescued by the 5'-S modification (190-fold stimulation), albeit to a lesser degree than R130K. We surmise that Arg-130 plays dual roles in transition state stabilization and general acid catalysis. Whereas the R130A mutation abolishes both functions, R130K permits the transition state stabilization function (via contact of lysine with the scissile phosphate) but not the proton transfer function. Our results show that the process of general acid catalysis is complex and suggest that Lys-167 and Arg-130 comprise a proton relay from the topoisomerase to the 5'-O of the leaving DNA strand.
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PMID:Proton relay mechanism of general acid catalysis by DNA topoisomerase IB. 1175 2

Quinolones are potent antibacterial agents that specifically target bacterial DNA gyrase and topoisomerase IV. Widespread use of these agents has contributed to the rise of bacterial quinolone resistance. Previous studies have shown that quinolone resistance arises by mutations in chromosomal genes. Recently, a multiresistance plasmid was discovered that encodes transferable resistance to quinolones. We have cloned the plasmid-quinolone resistance gene, termed qnr, and found it in an integron-like environment upstream from qacE Delta 1 and sulI. The gene product Qnr was a 218-aa protein belonging to the pentapeptide repeat family and shared sequence homology with the immunity protein McbG, which is thought to protect DNA gyrase from the action of microcin B17. Qnr had pentapeptide repeat domains of 11 and 28 tandem copies, separated by a single glycine with a consensus sequence of A/C D/N L/F X X. Because the primary target of quinolones is DNA gyrase in Gram-negative strains, we tested the ability of Qnr to reverse the inhibition of gyrase activity by quinolones. Purified Qnr-His(6) protected Escherichia coli DNA gyrase from inhibition by ciprofloxacin. Gyrase protection was proportional to the concentration of Qnr-His(6) and inversely proportional to the concentration of ciprofloxacin. The protective activity of Qnr-His(6) was lost by boiling the protein and involved neither quinolone inactivation nor independent gyrase activity. Protection of topoisomerase IV, a secondary target of quinolone action in E. coli, was not evident. How Qnr protects DNA gyrase and the prevalence of this resistance mechanism in clinical isolates remains to be determined.
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PMID:Mechanism of plasmid-mediated quinolone resistance. 1194 63

NaeI endonuclease contains a 10-amino acid region with sequence similarity to the active site KXDG motif of DNA ligase except for leucine (Leu-43) in NaeI ((43)LXDG(46)). Changing Leu-43 to lysine abolishes the NaeI endonuclease activity and replaces it with topoisomerase and recombinase activities. Here we report the results of substituting Leu-43 with alanine, arginine, asparagine, glutamate, and histidine. Quantitating specific activities and DNA binding values for the mutant proteins determined the range of amino acids at position 43 that alter NaeI mechanism. Substituting alanine, asparagine, glutamate, and histidine for Leu-43 maintained endonuclease activity, but at a lower level. On the other hand, substituting positively charged arginine, like lysine at position 43, converted NaeI to a topoisomerase with no observable double-strand cleavage activity. The specific activities of NaeI-43K and NaeI-43R and their relative sensitivities to salt, the topoisomerase-inhibiting drug N-[4-(9-acridinylamino)-3-methoxyphenyl]methane-sulfonamide (amsacrine) and single-stranded DNA showed that the two activities are similar. The effect of placing a positive charge at position 43 on NaeI structure was determined by measuring (for NaeI and NaeI-43K) relative susceptibilities to proteolysis, UV, circular dichroism spectra, and temperature melting transitions. The results provide evidence that a positive charge at position 43 induces dramatic changes in NaeI structure that affect both the Endo and Topo domains of NaeI. The identification of four putative DNA ligase motifs in NaeI leads us to speculate that structural changes that superimpose these motifs on the ligase structure may account for the changes in activity.
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PMID:Amino acid substitutions at position 43 of NaeI endonuclease. Evidence for changes in NaeI structure. 1251 52

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