Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:5.99.1.2 (topoisomerase)
 9,166 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The eukaryotic family of type I DNA topoisomerases includes the nuclear type I enzymes and the enzymes encoded by vaccinia and other poxviruses. The small size of the vaccinia topoisomerase (314 amino acids as compared to 765-972 amino acids for the cellular enzymes) makes it likely that this protein constitutes the minimal functional unit of a eukaryotic type I enzyme and provides an opportunity for a comprehensive structure-function analysis through mutagenesis. Two protein subregions were targeted for mutagenesis in the present study. The role of the Ser-Lys-X-X-Tyr sequence present at the active site of all family members was examined by replacing each conserved residue with alanine. Alanine substitution at the active site Tyr abrogated topoisomerase activity. In contrast, mutations at Ser-270 and Lys-271 had no effect on enzyme activity. The region of the vaccinia topoisomerase from amino acids 126-142 (MFFIRFGKMKYLKENET) is highly conserved and contains a residue, Gly-132, shown previously to be essential. Twenty-nine different mutations were generated in this region, with at least one substitution at each position. Point mutations were identified at three positions, Arg-130, Tyr-136, and Leu-137, which either abrogated or severely reduced DNA relaxation. The effects on activity could be attributed to a defect in formation of the covalent intermediate. Alterations of 13 other amino acids, including conserved residues, had little or no effect on topoisomerase activity.
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PMID:Mutational analysis of vaccinia DNA topoisomerase defines amino acid residues essential for covalent catalysis. 796 97

Anti-topoisomerase II agents represent a major class of anticancer therapeutic agents. Resistance to this class of agents can be mediated by several possible mechanisms. One mechanism may involve mutations in the structural gene(s) for topoisomerases, altering the drug sensitivity of the enzymes. Several mutations have been described in mammalian cell lines that were selected for resistance to topoisomerase II-targeting drugs such as Adriamycin, etoposide, or amsacrine. The difficulty of performing genetic analysis in mammalian cell lines has complicated the determination of whether the observed mutations are responsible for drug resistance. We have reconstructed, in the yeast topoisomerase II gene, the arginine to glutamine mutation at position 450 of human topoisomerase II alpha that was originally identified by Bugg et al. [Proc. Natl. Acad. Sci. USA 88:7654-7658 (1991)]. Mutation of Lys439, the equivalent amino acid in the yeast protein, to either glutamine or glutamic acid confers resistance to etoposide and amsacrine. Interestingly, in diploid yeast cells the heterozygous mutation can still confer partial drug resistance, compared with a diploid strain that is homozygous for wild-type topoisomerase II. Because mutations in the topoisomerase II gene that can confer dominant resistance to anti-topoisomerase II agents are relatively rare, mutations in the gyrB region may be important in the development of clinical drug resistance.
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PMID:Mutations in the gyrB domain of eukaryotic topoisomerase II can lead to partially dominant resistance to etoposide and amsacrine. 796 59

Topoisomerase II (Top II) is the target enzyme for many antineoplastic drugs such as epipodophyllotoxins, anthracyclines, and acridines. Cell lines with alterations in Top II are resistant to drugs that interact with the enzyme. Studies of the Top II from a Chinese hamster ovary line, VpmR-5, that is resistant to VP-16 and VM-26, demonstrated that it is very similar, qualitatively and quantitatively, to its normal counterpart except that DNA cleavage by the VpmR-5 enzyme is not stimulated by VP-16 or VM-26. To understand the basis for the drug-resistant phenotype, the Top II cDNAs were isolated from both Chinese hamster ovary (CHO) and VpmR-5 cells by cDNA cloning with lambda gt22, and the entire cDNAs were sequenced. A mutation of G-->A at nucleotide 1478 was the only alteration observed in the VpmR-5 Top II cDNA compared with the wild-type gene. The mutation in VpmR-5 was confirmed by sequencing DNA fragments amplified from the genomic DNA by the polymerase chain reaction. Southern blot hybridization analysis of genomic DNA demonstrated loss of a Top II allele in VpmR-5 probably occurred during the development of resistance to etoposide. The mutation in VpmR-5 changes amino acid 493 from arginine to glutamine and is located adjacent to a putative ATP binding site of Top II. Mutations in an analogous region have been identified in two human leukemia cell lines by amplification of segments of Top II cDNA with Taq DNA polymerase. Taken together, these observations suggest that mutations in this region of the gyrase B domain of mammalian topoisomerase II may be capable of conferring resistance to antineoplastic agents that interact with this enzyme.
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PMID:Molecular cloning and identification of a point mutation in the topoisomerase II cDNA from an etoposide-resistant Chinese hamster ovary cell line. 838 May 92

DNA topoisomerase II is the target of a variety of important antitumor agents, including etoposide, adriamycin, and amsacrine. We have constructed a system for analyzing the action of anti-topoisomerase II agents using the yeast Saccharomyces cerevisiae and have constructed vectors for expressing human topoisomerase II functionally in yeast. We have demonstrated that temperature-conditional yeast TOP2 mutants can be complemented by expression of wild-type human topoisomerase II alpha. Furthermore, expression of human topoisomerase II in yeast results in a quantitatively unique pattern of sensitivity to amsacrine. We also have constructed mutations in human TOP2 based on previously identified mutations from a human cell line selected for resistance to teniposide. Our experiments demonstrate that mutation of either arginine 450 or proline 803 of human topoisomerase II can result in an enzyme that has altered sensitivity to anti-topoisomerase II agents, and that a human enzyme carrying both mutations confers a higher level of drug resistance than enzymes carrying either single mutation.
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PMID:Functional expression of human topoisomerase II alpha in yeast: mutations at amino acids 450 or 803 of topoisomerase II alpha result in enzymes that can confer resistance to anti-topoisomerase II agents. 854 81

Reverse transcription-PCR-single-strand conformation polymorphism analysis was performed to detect topoisomerase IIalpha mutations using total RNA from 19 bronchial biopsy specimens obtained from 13 patients with small cell lung cancer. An abnormally migrating single-strand conformation polymorphism band was observed in one tumor sample from a patient treated with etoposide-containing chemotherapy. DNA sequence analysis of this tumor showed two transversions at codons 486 (G to A) and 494 (A to G), resulting in two missense mutations (Arg to Lys and Glu to Gly, respectively). The codon 486 mutation was identical to that previously found in two cell lines selected for amsacrine resistance. These results demonstrate that mutations of topoisomerase IIalpha occur in patients with small cell lung cancer. The significance of these mutations in the development of resistance to etoposide needs further investigation.
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PMID:Point mutations of the topoisomerase IIalpha gene in patients with small cell lung cancer treated with etoposide. 864 Aug 4

Fifteen strains of Escherichia coli with MICs of ciprofloxacin (CIP) between 0.015 and 256 micrograms/ml were examined for the presence of mutations in the quinolone resistance-determining region of the gyrA gene and in an analogous region of the parC gene. No mutation was found in a susceptible isolate (MIC of CIP, 0.015 microgram/ml). Four moderately resistant strains (MIC of CIP 0.06 to 4 micrograms/ml) carried one gyrA mutation affecting serine 83, but in only one strain was an additional parC mutation (Gly-78 to Asp) detected. All ten highly resistant strains examined (MIC of CIP, > 4 micrograms/ml) carried two gyrA mutations affecting residues serine 83 and aspartate 87, and at least one parC mutation. These parC mutations included alterations of serine 80 to arginine or isoleucine and glutamate 84 to glycine or lysine. The parC+ and two mutant alleles (parCI-80 and parCI-80,G-84) were inserted into the mobilizable vector pBP507. Transfer of a plasmid-coded parC+ allele into parC+ strains did not alter the susceptibilities towards ciprofloxacin or nalidixic acid, while a significant increase in susceptibility was detectable for parC mutants. This increase, however, did not restore wild-type susceptibility, whereas transfer of a plasmid-coded gyrA+ allele alone or in combination with parC+ did. These data are in agreement with the view that topoisomerase IV is a secondary, less sensitive target for quinolone action in Escherichia coli and that the development of high-level fluoroquinolone resistance in E. coli requires at least one parC mutation in addition to the gyrA mutation(s).
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PMID:Genetic evidence for a role of parC mutations in development of high-level fluoroquinolone resistance in Escherichia coli. 884 44

Ciprofloxacin-resistant mutants of Streptococcus pneumoniae 7785 were generated by stepwise selection at increasing drug concentrations. Sequence analysis of PCR products from the strains was used to examine the quinolone resistance-determining regions of the GyrA and GyrB proteins of DNA gyrase and the analogous regions of the ParC and ParE subunits of DNA topoisomerase IV. First-step mutants exhibiting low-level resistance had no detectable changes in their topoisomerase quinolone resistance-determining regions, suggesting altered permeation or another novel resistance mechanism. Nine of 10 second-step mutants exhibited an alteration in ParC at Ser-79 to Tyr or Phe or at Ala-84 to Thr. Third- and fourth-step mutants displaying high-level ciprofloxacin resistance were found to have, in addition to the ParC alteration, a change in GyrA at residues equivalent to Escherichia coli GyrA resistance hot spots Ser-83 and Asp-87 or in GyrB at Asp-435 to Asn, equivalent to E. coli Asp-426, part of a highly conserved EGDSA motif in GyrB. No ParE changes were observed. Complementary analysis of two S. pneumoniae clinical isolates displaying low-level resistance to ciprofloxacin revealed a ParC change at Ser-79 to Phe or Arg-95 to Cys but no changes in GyrA, GyrB, or ParE. A highly resistant isolate, in addition to a ParC mutation, had a GyrA alteration at the residue equivalent to E. coli Asp-87. Thus, in both laboratory strains and clinical isolates, ParC mutations preceded those in GyrA, suggesting that topoisomerase IV is a primary topoisomerase target and gyrase is a secondary target for ciprofloxacin in S. pneumoniae.
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PMID:Involvement of topoisomerase IV and DNA gyrase as ciprofloxacin targets in Streptococcus pneumoniae. 889 Nov 38

Anthracenyl-amino acid and dipeptide conjugates represent new classes of topoisomerase (topo) inhibitors. To investigate the structural basis for their different selectivity against topo I and II and varying potency, the binding of six compounds to d(CGTACG) was studied by molecular modeling. Modeling data were in good agreement with physical data showing that five compounds intercalated DNA with the anthraquinone chromophore orientated in parallel to the long dimension of the d(CpG) base pairs and the amino acid placed in the minor groove. Differences in binding modes emerged which correlated to different biological properties. The amino acid chain of the topo I inhibitor (NU/ICRF 600, gly-phe) extended significantly out from the helical axis horizontal. The amino acid side chains of two topo II inhibitors (NU/ICRF 510, arginine and NU/ ICRF 512, methionine) were inserted into the minor groove, whereas the C-terminal groups (hydrazide) of two potent topo II inhibitors (NU/ICRF 500 and 506, serine) were placed into the minor groove while the amino acid side chains pointed away from the minor groove. These data provide structural information which may prove valuable in rational design of second generation analogs.
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PMID:Molecular modeling of the interaction of anthracenyl-amino acid topoisomerase inhibitors with the DNA sequence d(CGTACG). 891 31

Vaccinia DNA topoisomerase, a 314-amino acid type I enzyme, catalyzes the cleavage and rejoining of DNA strands through a DNA-(3'-phosphotyrosyl)-enzyme intermediate. To identify amino acids that participate in the transesterification reaction, we introduced alanine substitutions at 39 positions within a conserved 57amino acid segment upstream of the active-site tyrosine. Purified wild type and mutant proteins were compared with respect to their activities in relaxing supercoiled DNA. The majority of mutant proteins displayed wild type topoisomerase activity. Mutant enzymes that relaxed DNA at reduced rates were subjected to kinetic analysis of the strand cleavage and religation steps under single-turnover and equilibrium conditions. For the wild type topoisomerase, the observed single-turnover cleavage rate constant (kcl) was 0.29 s-1 and the cleavage-religation equilibrium constant (Kcl) was 0.22. The most dramatic mutational effects were seen with R223A; removal of the basic side chain reduced the rates of cleavage and religation by factors of 10(-4.3) and 10(-5.0), respectively, and shifted the cleavage-religation equilibrium in favor of the covalently bound state (Kcl = 1). Introduction of lysine at position 223 restored the rate of cleavage to 1/10 that of the wild type enzyme. We conclude that a basic residue is essential for covalent catalysis and suggest that Arg-223 is a constituent of the active site. Modest mutational effects were observed at two other positions (Lys-220 and Asn-228), at which alanine substitutions slowed the rates of strand cleavage by 1 order of magnitude and shifted the equilibrium toward the noncovalently bound state. Arg-223 and Lys-220 are conserved in all members of the eukaryotic type I topoisomerase family; Asn-228 is conserved among the poxvirus enzymes.
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PMID:Mutational analysis of 39 residues of vaccinia DNA topoisomerase identifies Lys-220, Arg-223, and Asn-228 as important for covalent catalysis. 907 46

Pronounced differences in the interactions of monomeric (lactone and carboxylate) and the J-type self-aggregated form of camptothecin (CPT), an inhibitor of DNA topoisomerase (topo) I, with human (HSA) and bovine (BSA) serum albumins were observed by using circular dichroism (CD) spectroscopy. HSA binding changes the geometry of the covalent structure of CPT due to hydrophobic contacts of the chromophore within the protein interior. The carbonyl group of the ring D of CPT (Fig. 1A) interacts with the positively charged amino acid residues of HSA. Interaction with HSA induces disaggregation of the J-type self-aggregates of CPT. On the other hand, neither heat-denatured HSA nor native BSA participated in binding of the lactone or carboxylate or self-aggregate forms of CPT. Analysis of HSA and BSA homology within the IIA and IIIA principle ligand-binding structural domains suggests that the binding site for the CPT chromophore is located in subdomain IIA. Hydrophobic contacts with Leu-203, Phe-211, and Ala-215 and electrostatic interactions with Lys-199 and/or Arg-222 of HSA may play a key role in formation of the drug-HSA complex.
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PMID:Interactions of lactone, carboxylate and self-aggregated forms of camptothecin with human and bovine serum albumins. 910 7


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