Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Strands of DNA that have been broken by the DNA untwisting enzyme exhibit a reduced buoyant density in alkaline CsCl due to bound protein. A covalent linkage between the DNA and the enzyme was indicated by the stability of the complex in alkali (pH greaterthan 12.7), in 7 M guanidine-HCl, and at 90 degrees in 1% Sarkosyl for 5 min. The single-strand breaks generated by the enzyme are resistant to exonuclease III, indicating that the protein is attached to one of the ends of the broken strands. The free end of the broken strand bears a 5'-hydroxyl group, indicating attachment of the protein to the 3'-phosphoryl terminus. A nucleotide-peptide linkage involving a phosphoamide bond is unlikely since the complex is resistant to 3.5 M hydroxylamine at pH 4.75.
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PMID:Strand breakage by the DNA untwisting enzyme results in covalent attachment of the enzyme to DNA. 19 5

We have developed a simple, effective genetic screen for mutant alleles of eukaryotic DNA topoisomerase I that manifest severely depressed or complete loss of enzymatic function. The screen is based on the extreme toxicity of vaccinia topoisomerase expression in the Escherichia coli lysogen strain BL21(DE3) and is notable for its ease in distinguishing nonsense mutations (that result in truncated proteins) from missense mutations. The power of the method is evinced by our observation that 100% of the candidate alleles identified in the screen were ultimately found to have single-base changes at the DNA level that result in amino acid substitutions at the protein level. By mutagenizing plasmid DNA in vitro with hydroxylamine and applying this phenotypic screen, we have isolated five distinct single amino acid substitution mutants, each of which shows a biochemical phenotype, that is, greater than or equal to 90% reduction in specific DNA relaxing activity of the mutant protein relative to wild type. The amino acids thus implicated in topoisomerase function have identical or related counterparts at homologous positions in the topoisomerases from yeast and man. The same genetic screen has been applied to the selection of temperature-sensitive alleles of the vaccinia topoisomerase, leading to the isolation of two additional single-hit mutant alleles that display a temperature-sensitive growth phenotype in E. coli BL21(DE3). By broadening our mutagenesis procedures, we expect to generate a comprehensive map of vaccinia topoisomerase function and primary protein structure that should have direct application to eukaryotic cellular enzymes. Our methodology should be applicable to the selection of missense and conditional mutant alleles in other genes whose expression in bacteria is toxic.
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PMID:Phenotypic selection and characterization of mutant alleles of a eukaryotic DNA topoisomerase I. 216 40

Conditions which result in DNA strand breakage by the rat liver DNA nicking-closing enzyme lead to the covalent attachment of the 3'-end of the broken strand to the enzyme. Treatment of this complex with pancreatic DNase leaves a residue of 17 +/- 8 nucleotide phosphates still attached to the enzyme. Subsequent nuclease P1 treatment removes all but 2 +/- 1 phosphate residues. Using nuclease P1-treated complexes which had been labeled in the DNA with 32P, the stability of the protein-DNA linkage was studied. The linkage is stable to acid, base, neutral and acidic hydroxylamine, and neutral I2. This pattern of stability rules out essentially all of the possible DNA-protein linkages except for a linkage involving a phosphodiester bond to the amino acid tyrosine. After acid hydrolysis of the 32P-labeled complexes, label was found to be associated with O4-phosphotyrosine, providing a direct demonstration that tyrosine is the amino acid to which the end of the DNA chain is attached.
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PMID:DNA is linked to the rat liver DNA nicking-closing enzyme by a phosphodiester bond to tyrosine. 626 3

Doxorubicin is a therapeutically useful anticancer drug that exerts multiple biological effects. Its antitumor and cardiotoxic properties have been ascribed to anthracycline-mediated free radical damage to DNA and membranes. Evidence for this idea comes in part from the selection by doxorubicin from stationary phase yeast cells of mutants (petites) deficient in mitochondrial respiration and therefore defective in free radical generation. However, doxorubicin also binds to DNA topoisomerase II, converting the enzyme into a DNA damaging agent through the trapping of a covalent enzyme-DNA complex termed the 'cleavable complex.' We have used yeast to determine whether stabilization of cleavable complexes plays a role in doxorubicin action and cytotoxicity. A plasmid-borne yeast TOP2 gene was mutagenized with hydroxylamine and used to transform drug-permeable yeast strain JN394t2-4, which carries a temperature-sensitive top2-4 mutation in its chromosomal TOP2 gene. Selection in growth medium at the nonpermissive temperature of 35 degrees in the presence of doxorubicin resulted in the isolation of plasmid-borne top2 mutants specifying functional doxorubicin-resistant DNA topoisomerase II. Single-point changes of Gly748 to Glu or Ala642 to Ser in yeast topoisomerase II, which lie in and adjacent to the CAP-like DNA binding domain, respectively, were identified as responsible for resistance to doxorubicin, implicating these regions in drug action. None of the mutants selected in JN394t2-4, which has a rad52 defect in double-strand DNA break repair, was respiration-deficient. We conclude that topoisomerase II is an intracellular target for doxorubicin and that the genetic background and/or cell proliferation status can determine the relative importance of topoisomerase II- versus free radical-killing.
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PMID:Identification of yeast DNA topoisomerase II mutants resistant to the antitumor drug doxorubicin: implications for the mechanisms of doxorubicin action and cytotoxicity. 938 29

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

Human cells express two isoforms of topoisomerase II, alpha and beta, that are both targeted by anticancer drugs. To investigate acridine resistance mediated by topoisomerase IIbeta, we used a forced molecular evolution approach. A library of mutated topoisomerase IIbeta cDNAs was generated by hydroxylamine mutagenesis and was transformed into the yeast JN394 top2-4. Methyl N-(4'-(9-acridinylamino)-phenyl)carbamate hydrochloride (AMCA) selection identified a resistant transformant able to grow in media containing 76 microg/ml AMCA. Topoisomerase IIbeta with a glutamic acid-to-lysine substitution at position 522 was responsible for the approximately 10-fold resistance to AMCA. The transformant was cross-resistant to methyl N-(4'-(9-acridinylamino)-3-methoxy-phenyl) methane sulfonamide (mAMSA) and mAMCA but hypersensitive to etoposide and ellipticine. In vitro, the betaE522K protein was unable to support acridine-stimulated DNA cleavage, suggesting that resistance to these acridines is caused by reduced drug-stimulated DNA cleavage. However, betaE522K showed DNA cleavage with etoposide, and the cleavable complexes formed with etoposide showed greater stability, thus accounting for the hypersensitivity to etoposide. Drug-independent cleavage of an oligonucleotide by betaE522K was reduced compared with the wild-type enzyme. Decatenation and relaxation activities were reduced to 52 and 61% of the wild-type levels, which may explain the slower growth of yeast strain JN394top2-4 expressing betaE522K at the nonpermissive temperature. This study confirms that topoisomerase IIbeta is a target for AMCA and that resistance to AMCA can be mediated by a point mutation at Glu522 in topoisomerase IIbeta. Residue 522 lies within a Rossmann fold in the B' subfragment of topoisomerase II, a region previously implicated in drug interactions.
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PMID:Mutation E522K in human DNA topoisomerase IIbeta confers resistance to methyl N-(4'-(9-acridinylamino)-phenyl)carbamate hydrochloride and methyl N-(4'-(9-acridinylamino)-3-methoxy-phenyl) methane sulfonamide but hypersensitivity to etoposide. 1532 34