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)

CPT-11, a recently developed topoisomerase I (Topo I) inhibitor, attracts the attention not only of basic researchers but also of clinicians because of its high antitumor activity. The CPT-11 resistant human lung cancer cell line, PC-7/CPT, showed 10-fold resistance compared to parental cell line, PC-7. The total activity of Topo I in the resistant cell line was one fourth that of the parental sensitive cell line. The Topo I from the resistant cells was also 5-fold more resistant to the inhibitory effect of CPT-11 than that of the parental cells. We speculated that the alteration of the Topo I gene may be responsible for the change in topoisomerase activity of the CPT-11 resistant cell line. Therefore, we analyzed the mutation of Topo I gene using the method of single strand conformation polymorphism of polymerase chain reaction and the reverse transcriptase. We divided Topo I cDNA into ten fragments which overlapped each other and covered whole coding sequences of the Topo I cDNA. We observed mobility shift of two fragments in the PC-7/CPT, suggesting the presence of some mutations in these fragments. We performed the direct-sequencing of these portions by the dideoxy chain termination method and observed an altered sequence having a G to A base change in PC-7/CPT. This base substitution results in replacement of the conserved threonine at 729 position with alanine. These results suggest that the point mutation of Topo I gene is related to the decreases of Topo I activity and the sensitivity to Topo I inhibitor in PC-7/CPT cells.
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PMID:Detection of topoisomerase I gene point mutation in CPT-11 resistant lung cancer cell line. 133 3

Analysis of 100K-defective temperature-sensitive adenovirus mutants confirmed the multifunctional character of the nonstructural, virus-coded 100K protein. In addition to its function in hexon trimerization (altered in H5ts1), and its possible direct or indirect role in hexon transport to nucleus (mutated in H2ts118), genetic and biochemical evidence was presented that 100K play some critical role in the scaffolding process of adenovirus capsid. This function appeared to be defective in H2ts107 and to map between coordinates 69.0 and 69.9, leftward from the H5ts1 lesion (70-73 map units; Arrand, 1978). This corresponded to the central domain of the 100K protein, between amino acid 300 and 400 from the N end. DNA sequencing of cloned fragments of H2ts107 DNA overlapping the mutation revealed two point mutations on the same codon at nucleotide 25,082 and 25,083 (GAC----GCA), corresponding to a nonconservative amino acid change (aspartic acid----alanine) at position 324 in the 100K sequence. 100K of adenovirus 2 wild type (WT) was found to bind in significant amounts to novobiocin-affinity column, and to be coeluted with hexon, penton, IIIa, and cellular topoisomerase II activity, by novobiocin- or ATP-Mg2+-containing buffers. H2ts107 100K also bound to novobiocin column, but the elution pattern differed from that of WT, suggesting some alteration in the affinity of the mutated 100K for novobiocin. The same behavior on affinity column as H2ts107 100K was observed for 90K, a cleavage product of the 100K, found in great abundance in H2ts107 at 39.5 degrees and corresponding to the C-terminal moiety of the 100K molecule. This implied that the "novobiocin-binding" domain of the 100K was not confined at its N terminus, and was altered in the H2ts107 mutant.
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PMID:Hexon trimerization occurring in an assembly-defective, 100K temperature-sensitive mutant of adenovirus 2. 352 Oct 69

To investigate the involvement of proteases in apoptosis, rat thymocytes were treated with the glucocorticoid hormone methylprednisolone or the topoisomerase II inhibitor etoposide in the presence of selective substrate inhibitors of either interleukin-1 beta-converting enzyme (ICE), (Z-Val-Ala-Asp-chloromethylketone, VADcmk) or Ca(2+)-regulated serine protease (Suc-Ala-Ala-Pro-Phe-chloromethylketone, AAPFcmk). VADcmk protected from lamin proteolysis, chromatin fragmentation, cell shrinkage, and formation of apoptotic nuclei in both methylprednisolone- and etoposide-treated thymocytes when present during the initiation of the apoptotic process. AAPFcmk prevented lamin breakdown, chromatin fragmentation, and apoptotic morphological changes in thymocytes treated with methylprednisolone, but not with etoposide. Both MPS- and etoposide-treated thymocytes exhibited enhanced ICE-like protease activity which was maximal 1 h after treatment. This increase in proteolytic activity was blocked by VADcmk, but not AAPFcmk. Our findings suggest that ICE-like protease activity is critically involved in the early phase of both methylprednisolone- and etoposide-induced apoptosis in thymocytes, whereas the Ca(2+)-regulated serine protease is an obligatory component of the proteolytic cascade in methylprednisolone-induced apoptosis.
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PMID:Multiple proteases are involved in thymocyte apoptosis. 749 40

Anthracenyl-amino acid/dipeptides are novel topoisomerase (topo) inhibitors which can be actively cytotoxic in the low microM range. The present studies have been performed to determine whether cells treated with the topo II catalytic inhibitor NU/ICRF 500 (serine derivative) would manifest cytogenetic lesions consistent with its proposed mechanism of enzyme inhibition. Three other compounds were included for comparison: NU/ICRF 505 (tyrosine) which stabilises topo I cleavable complexes, NU/ICRF 602 (gly-gly) a non-cytotoxic catalytic inhibitor of topo I and II and NU/ICRF 502 (alanine) a non-cytotoxic non-topo inhibitor. Chromosomal damage was measured using the micronucleus test. NU/ICRF 500 (7.5-30 microM) induced an increase in CREST negative micronuclei (11-15 per 500 cells) in human lymphocytes (HL) and blocked the traverse of HL through the cell cycle, with cells accumulating in G2/M at 15 microM drug and G1/S at 30 microM drug. NU/ICRF 502 was without effect in the micronucleus test. NU/ICRF 500 and 602 (90-150 microM) caused no block in passage of synchronised metaphase Chinese hamster ovary cells through mitosis whereas NU/ICRF 505 produced a significant delay. DNA measurements of post-mitotic cells revealed that after NU/ICRF 500 treatment nuclei had a 4C DNA content, indicative of a lack of chromosomal segregation. Normal (2C) DNA content was observed with NU/ICRF 505 and 602. Overall, the data for NU/ICRF 500 are consistent with the cytogenetic modifications expected after catalytic inhibition of topo II and suggest that cell death may be mediated, at least in part, through this mechanism.
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PMID:Cytogenetic evaluation of the mechanism of cell death induced by the novel anthracenyl-amino acid topoisomerase II catalytic inhibitor NU/ICRF 500. 756 93

In prokaryotic type II topoisomerases (DNA gyrases), mutations that result in resistance to quinolones frequently occur at Ser83 or Ser84 of the gyrA subunit. Mutations to Trp, Ala, and Leu have been identified, all of which confer high levels of quinolone resistance. Extensive segments of DNA gyrase are homologous to eukaryotic topoisomerase II, and Ser741 of yeast TOP2 is homologous to Ser83 of prokaryotic DNA gyrA. Introduction of the Ser741-->Trp mutation into yeast TOP2 confers resistance to 6,8-difluoro-7-(4'-hydroxyphenyl)-1-cyclopropyl- 4-quinolone-3-carboxylic acid (CP-115,953), a fluoroquinolone with substantial activity against eukaryotic topoisomerase II, whereas changing Ser741 to either Leu or Ala does not change sensitivity to quinolones. Interestingly, Ser741-->Trp in the yeast TOP2 also confers hypersensitivity to etoposide. Sensitivity to intercalating anti-topoisomerase II agents such as amsacrine is not changed by any of the three mutations. The topoisomerase II protein carrying the Ser741-->Trp mutation was overexpressed and purified. The purified mutant enzyme had enhanced levels of etoposide stabilized covalent complex as compared with the wild type enzyme and reduced cleavage with CP-115,953. Unlike the wild type enzyme, etoposide-stabilized cleavage is not readily reversible by heat. We suggest that Ser741 is near a binding site for both quinolones and etoposide and that the Ser741-->Trp mutation leads to a more stable ternary complex between etoposide, DNA, and the mutant enzyme.
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PMID:A mutation in yeast TOP2 homologous to a quinolone-resistant mutation in bacteria. Mutation of the amino acid homologous to Ser83 of Escherichia coli gyrA alters sensitivity to eukaryotic topoisomerase inhibitors. 765 8

The cytotoxic plant alkaloid camptothecin promotes DNA topoisomerase I-linked nicks in DNA by stabilizing a covalently bound enzyme-DNA complex. In the yeast Saccharomyces cerevisiae, substitution of Arg and Ala for the amino acid residues immediately N-terminal to the active site tyrosine in the yeast and human DNA topoisomerase I mutants, top1 vac, results in camptothecin resistance. To examine the mechanism of drug resistance, we assessed the sensitivity of these enzymes to several classes of DNA topoisomerase poisons. Yeast cells expressing the camptothecin-resistant top1 vac mutants were resistant to all of the camptothecin derivatives cytotoxic to wild-type TOP1-expressing cells. This correlated with a significant reduction in drug-induced DNA cleavage in vitro. However, the yeast and human mutant enzymes differed in their responses to the minor groove binding ligand netropsin and to saintopin, a DNA intercalator that targets both DNA topoisomerase I and II. The yeast mutant enzyme demonstrated enhanced sensitivity to the action of saintopin but was resistant to the inhibitory effects of netropsin. In contrast, the human Top1 vac enzyme was resistant to saintopin and indistinguishable from the wild-type enzyme in its response to the netropsin. These results are discussed in terms of enzyme function and the different modes of action of these DNA topoisomerase poisons.
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PMID:A camptothecin-resistant DNA topoisomerase I mutant exhibits altered sensitivities to other DNA topoisomerase poisons. 789 Jul 48

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

The TraI protein of plasmid RP4 (IncP alpha) catalyzes a site- and strand-specific cleaving-joining reaction on form I or single-stranded DNA. Thus, TraI is one of the key components involved in the initiation and termination of horizontal DNA transfer by bacterial conjugation. Amino acid sequence comparison revealed three motifs in the TraI sequence conserved in relaxases from different origins. Site-directed mutagenesis of the traI structural gene and application of purified mutant TraI proteins for in vitro assays served to evaluate the functional importance of conserved amino acid residues. Two regions of TraI designated as motifs I and III are involved in catalyzing the cleaving-joining reaction. Motif I carries the tyrosine residue (Tyr-22), which covalently attaches TraI in a transesterification reaction to the 5' terminus of the cleaved DNA. Motif III contains one histidine residue (His-116) essential for relaxase activity and therefore proposed to activate the aromatic hydroxyl group of tyrosine 22 by proton abstraction. Exchange of a serine residue (Ser-74), located in motif II, against alanine prevents formation of stable relaxosomes but strongly enhances topoisomerase activity of the combination TraI/TraJ on form I oriT DNA. Motif II therefore might represent the DNA recognition domain of TraI. Our studies allowed us to establish a model of the interplay of three motifs located in the N-terminal region (amino acid positions 19-124) of TraI.
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PMID:Concerted action of three distinct domains in the DNA cleaving-joining reaction catalyzed by relaxase (TraI) of conjugative plasmid RP4. 830 Jun 11

Mutations in the flqA (formerly ofx/cfx) resistance locus of Staphylococcus aureus were previously shown to be common after first-step selections for resistance to ciprofloxacin and ofloxacin and to map on the S. aureus chromosome distinctly from gyrA, gyrB, and norA.grlA and grlB, the genes for the topoisomerase IV of S. aureus, were identified from a genomic lambda library on a common KpnI fragment, and grlB hybridized specifically with the chromosomal SmaI A fragment, which contains the flqA locus. Amplification of grlA sequences (codons 1 to 251) by PCRs from nine independent single-step flqA mutants, one multistep mutant, and the parent strain identified mutations encoding a change from Ser to Phe at position 80 in four mutants, a novel change from Ala to either Glu or Pro at position 116 in three mutants, and no change in three mutants. In the multistep mutant, another resistance locus, flqC, was mapped by transformation to the chromosomal SmaI G fragment by linkage to omega(ch::Tn551)1051 (58%) and nov (97.9%), which encodes resistance to novobiocin. This fragment contains the gyrA gene, and flqC mutants had a mutation in gyrA encoding a change from Ser to Leu at position 84, a change previously found in resistant clinical isolates. In genetic outcrosses, the flqC (gyrA) mutation expressed resistance only in flqA mutants, including those with both types of grla mutations. The silent mutant allele of gyrA was present in a flqA background and expressed resistance only upon introduction of a grlA mutation. At fourfold the MIC of ciprofloxacin, the bactericidal activity of ciprofloxacin was reduced in a grlA mutant and was abolished in gyrA grlA double mutants. These findings provide direct genetic evidence that topoisomerase IV is the primary target of current fluoroquinolones in S. aureus and that this effect may result from the greater sensitivity of topoisomerase IV relative to that of DNA gyrase to these agents. Furthermore, resistance from an altered DNA gyrase requires resistant topoisomerase IV for its expression.
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PMID:Quinolone resistance mutations in topoisomerase IV: relationship to the flqA locus and genetic evidence that topoisomerase IV is the primary target and DNA gyrase is the secondary target of fluoroquinolones in Staphylococcus aureus. 884 98

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


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