Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:5.99.1.3 (topoisomerase)
9,911 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Novobiocin, a commercially available oral antibiotic, inhibits DNA topoisomerase II in a manner shown in cell culture to enhance the cytotoxicity of alkylating agents and cisplatin. Thirty-six patients were entered on a Phase II trial using high-dose cisplatin (100 mg/m2 on days 1 and 8 for four cycles) after steady-state dosing with novobiocin (1000 mg or four 250-mg capsules every 12 hours for six doses, four of which were administered before each dose of cisplatin). One patient remains on study and cannot be evaluated for response. No complete responses were seen. Three patients (8%) had partial responses and an additional patient had an unconfirmed partial response. The median survival time of all patients was just less than 7 months. These results are comparable with those of other concurrent Southwest Oncology Group (SWOG) Phase II and III trials of high-dose cisplatin in non-small cell lung cancer (NSCLC). Novobiocin plasma levels were obtained for three patients and were approximately 50% of the optimal concentration as reported in cell culture for potentiation of cytotoxicity. It was concluded that an optimum test of novobiocin as a modulator of cytotoxicity may require the availability of an intravenous preparation.
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PMID:Cisplatin and novobiocin in the treatment of non-small cell lung cancer. A Southwest Oncology Group study. 164 65

The conventional laboratory approach to study the mechanisms of drug resistance has been the selection of drug-resistant cell lines by continuous exposure to cytotoxic agents. Such lines, which are selected for resistance to a single agent, frequently display cross-resistance to a number of cytotoxic agents that are unrelated in both structure and proposed mechanism of action. Multidrug-resistant cells display reduced drug accumulation, which is the result of overexpression of a surface glycoprotein (P170). Although resistance to multiple antitumor agents is a common clinical problem in the treatment of cancer, the precise role of the P-glycoprotein-mediated mechanism in human tumors remains to be established. Many alterations in multidrug-resistant cells selected in vitro have been identified. The concomitant expression of multiple phenotypic differences, which appear to be favored by continued and prolonged drug exposure, makes analysis of critical individual resistance pathways more difficult. However, multiple factors may also be involved in the development of clinical resistance. Recent studies have identified alterations in DNA topoisomerase II activity and function as an alternative mechanism that contributes to the multidrug-resistance phenomenon or is responsible for a different type of drug resistance. The precise nature of these changes remains unclear. Available evidence supports the view that expression of the enzyme is an important determinant of cell sensitivity to DNA topoisomerase poisons, but that other changes involved in regulation of enzyme function and/or in the cellular processing of drug-induced DNA damage may be critical in determining the differential pattern of cell response to antitumor agents.
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PMID:The role of topoisomerase II in drug resistance. 164 58

Diploid human fibroblast strains were treated for 10 min with inhibitors of type I and type II DNA topoisomerases, and after removal of the inhibitors, the rate of initiation of DNA synthesis at replicon origins was determined. By alkaline elution chromatography, 4'-(9-acridinylamino)methanesulfon-m-anisidide (amsacrine), an inhibitor of DNA topoisomerase II, was shown to produce DNA strand breaks. These strand breaks are thought to reflect drug-induced stabilization of topoisomerase-DNA cleavable complexes. Removal of the drug led to a rapid resealing of the strand breaks by dissociation of the complexes. Velocity sedimentation analysis was used to quantify the effects of amsacrine treatment on DNA replication. It was demonstrated that transient exposure to low concentrations of amsacrine inhibited replicon initiation but did not substantially affect DNA chainelongation within operating replicons. Maximal inhibition of replicon initiation occurred 20 to 30 min after drug treatment, and the initiation rate recovered 30 to 90 min later. Ataxia telangiectasia cells displayed normal levels of amsacrine-induced DNA strand breaks during stabilization of cleavable complexes but failed to downregulate replicon initiation after exposure to the topoisomerase inhibitor. Thus, inhibition of replicon initiation in response to DNA damage appears to be an active process which requires a gene product which is defective or missing in ataxia telangiectasia cells. In normal human fibroblasts, the inhibition of DNA topoisomerase I by camptothecin produced reversible DNA strand breaks. Transient exposure to this drug also inhibited replicon initiation. These results suggest that the cellular response pathway which downregulates replicon initiation following genotoxic damage may respond to perturbations of chromatin structure which accompany stabilization of topoisomerase-DNA cleavable complexes.
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PMID:Inhibition of replicon initiation in human cells following stabilization of topoisomerase-DNA cleavable complexes. 164 93

To study the mechanism of illegitimate recombination in mammalian cells, we have developed a shuttle vector, pNK1, that contains three bacterial markers, amp (ApR), galK, and neo (KmR). The frequency of deletions occurring in autonomously replicating pNK1 DNA during the growth of monkey COS1 cells was measured by transfecting the plasmid into Escherichia coli cells and counting the number of galK- ApS double mutants among total KmR cells. This method allowed us to test the effects of topoisomerase inhibitors on deletion formation in mammalian cells. The DNA topoisomerase II (TopII) inhibitor, 4'-dimethylepipodophyllotoxin thenylidene-beta-D-glucoside (VM26), stimulated deletions in pNK1 DNA in monkey cells. Since VM26 does not inhibit the strand-break activity of TopII, but rather stabilizes an enzyme-DNA complex in which DNA is cleaved upon treatment with sodium dodecyl sulfate, it is implicated that TopII participates in the deletion process in mammalian cells.
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PMID:A shuttle vector for analysis of illegitimate recombination in mammalian cells: effects of DNA topoisomerase inhibitors on deletion frequency. 164 63

Various antitumor drugs stabilize DNA topoisomerase II-DNA transient covalent complexes. The complexes distribution along pBR322 DNA was shown previously to depend upon the nature of the drug (Tewey et al. (1984) Science 226, 466-468). The position in pBR322 of DNA cleavage by calf DNA topoisomerase II for 115 such sites stabilized by an ellipticine derivative and the relative frequency of cleavage at most of these sites were determined. The nucleotide sequence surrounding the 25 strongest sites was analyzed and the following ellipticine specific consensus sequence was deduced: 5'-ANCNT(A/G)T.NN(G/C)N(A/G)-3' where cleavage occurs at the indicated mark. A thymine is always present at the 3' end of at least one strand of the strong cleavage sites, and the dinucleotide AT or GT at the 3' end of the break plays a major role in the complex stabilisation. The predictive value of cleavage of the consensus was tested for two regions of SV40 DNA and cleavage was indeed detected at the majority of the sites matching the consensus. Some complexes stabilized by ellipticine are resistant to salt dissociation and this property seems to be correlated with the presence of symmetrical sequences in the cleavage site with a center of symmetry staggered relatively to the center of symmetry of cleavage.
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PMID:Sequence requirements for mammalian topoisomerase II mediated DNA cleavage stimulated by an ellipticine derivative. 164 20

Exposure of promyelocytic leukemic HL-60 cells to 3-60 nM of the DNA topoisomerase I inhibitor camptothecin (CAM) or to 30-450 nM and 0.12-1.5 microM of DNA topoisomerase II inhibitors teniposide (TN) and 4-(9-acridynylamino)-3-methanesulfon-m-anisidide (m-AMSA), respectively, resulted in two distinct kinetic effects: (1) the cells entered S phase but the rate of DNA replication was reduced in proportion to the inhibitor concentration; (2) the transition from G2 to M was impaired, approximately 1 h after addition of the inhibitor. As a consequence, the cells accumulated in the S (preferentially in early S) and in G2 phases of the cell cycle. Whereas CAM was more efficient in suppressing cell progression through S phase, TN and m-AMSA were more potent G2 blockers. At these low inhibitor concentrations no signs of immediate cytotoxicity or DNA degradation were apparent. However, above 145 nM of CAM, 900 nM of TN, or 2 microM of m-AMSA extensive DNA degradation in nuclei of S phase cells was evident within 6 h of addition of the inhibitor, resulting in the loss of S and G2 + M cells from these cultures. The data indicate that depending on concentration, mechanisms mediating the cytostatic/cytotoxic activity of both DNA topoisomerase I and II inhibitors may be quite different. Suppression of the DNA replication and the G2 to M transition, seen at low inhibitor concentrations, is compatible with the assumption that the inhibitor-induced stabilization of the topoisomerase-DNA cleavable complexes interferes with DNA replication and chromosome condensation/segregation, respectively. Above the threshold concentration for each inhibitor, an endonucleolytic activity is triggered, resulting in rapid DNA degradation in nuclei of S and G2 phase cells. The endonucleolytic effect is not only cell cycle phase-specific but is also modulated by tissue-specific factors because it cannot be observed, e.g., in the lymphocytic leukemic cell lines.
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PMID:The concentration-dependent diversity of effects of DNA topoisomerase I and II inhibitors on the cell cycle of HL-60 cells. 164 59

We have isolated two etoposide (VP16)-resistant cell lines, KB/VP-1 and KB/VP-2, from human cancer KB cells after stepwise exposure to increasing doses of VP16. KB/VP-1 and KB/VP-2 showed 30- and 50-fold higher resistance to VP16 and also 20- and 30-fold higher resistance to teniposide than the parent cell line. Furthermore, both resistant cell lines showed more than 2-fold cross-resistance to Adriamycin and daunomycin than KB cells. The levels of accumulation and outward transport of radioactive VP16 were similar in KB/VP-1, KB/VP-2, and KB. The activity of nuclear extracts of DNA topoisomerase II for both KB/VP-1 and KB/VP-2 assayed by decatenation of kinetoplast DNA was consistently similar to that of KB. However, in both immunoblot assay with specific anti-topoisomerase II antibody and Northern blot analysis with specific human DNA topoisomerase II complementary DNA, cellular levels of topoisomerase II in both resistant cell lines were less than one-tenth the level in KB. The cellular levels of DNA topoisomerase I, however, were similar between the mutants and their parent. A quantitative precipitation assay of covalent DNA-topoisomerase II complexes showed greatly reduced VP16-induced cleavages of 3'-32P-DNA by nuclear extracts of KB/VP-1 or KB/VP-2 cells in comparison with KB cells. The relative specific phosphorylation of DNA topoisomerase II was about 14- to 18-fold higher in the mutants than in the parental cells. Phosphoamino acid analysis of DNA topoisomerase II showed that serine was the phosphorylated amino acid in all three cell lines, KB, KB/VP-1, and KB/VP-2. These data suggest that reduced expression of DNA-topoisomerase II might account for the acquired VP16 resistance and reduced VP16-induced cleavages of DNA-topoisomerase II complexes in both VP16-resistant variants.
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PMID:Increased phosphorylation of DNA topoisomerase II in etoposide-resistant mutants of human cancer KB cells. 164 96

New details of the molecular interactions of quinolones with their target DNA gyrase and DNA have come from the nucleotide sequences of the gyrA genes from resistant mutants of Escherichia coli and wild-type strains of other bacteria and studies of gyrase A tryptic fragments, all suggesting the importance of an amino-terminal domain in quinolone action. Alterations in DNA supertwisting were also associated with altered quinolone susceptibility, possibly by indirect effects on DNA gyrase expression. Specific binding of relevant concentrations of norfloxacin to a complex of DNA gyrase and DNA in the presence of ATP, the cooperativity of DNA binding, and the crystalline structure of nalidixic acid have led to a model in which quinolones bind cooperatively to a pocket of single-strand DNA created by DNA gyrase. Quinolones vary in their relative activity against DNA gyrase and its eukaryotic homolog topoisomerase II, and in some assays increased action against the eukaryotic enzyme was associated with genotoxicity. Inhibition of bacterial DNA synthesis by quinolones may correlate with MICs in some species, but comparisons of drug accumulation and inhibition of DNA synthesis in permeabilized cells among species have been difficult to interpret. The specific factors necessary for bacterial killing by quinolones in addition to interaction with DNA gyrase have remained elusive, but include oxygen and new protein synthesis. The coordinate expression of the SOS proteins appears not to be necessary for quinolone lethality. Two independent mutants with selective reduced killing by quinolones and beta-lactams indicate overlap in the pathways of bactericidal activity of these classes of agents with distinct targets.
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PMID:Mode of action of the new quinolones: new data. 165 Jun 98

In the presence of a molar excess of eukaryotic DNA topoisomerase II and an appropriate concentration of dextran sulfate, relaxed closed circular DNA is converted to a negatively supercoiled form. The reaction is dependent on ATP. Neither adenosine 5'-[beta,gamma-imido]-triphosphate nor adenosine 5'-[gamma-thio]triphosphate can substitute for ATP. The negative supercoils formed are relaxed by subsequent addition of DNA topoisomerase I to the supercoiling reaction mixture. Covalent closure of a nicked circular DNA in the presence of DNA topoisomerase II and dextran sulfate but in the absence of ATP causes a small decrease in the linking number. These results suggest that when an appropriate concentration of dextran sulfate is present, the binding of a molar excess of eukaryotic DNA topoisomerase II constrains a small number of negative supercoils in DNA, which in turn generate unconstrained negative supercoils at the expense of ATP.
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PMID:Negative supercoiling of DNA by eukaryotic DNA topoisomerase II and dextran sulfate. 165 Jul 78

CPT-11, a derivative of camptothecin, has drawn attention to cancer chemotherapy because of the specific mode of action, and the clinical study is now under progress. Liu et al. proved that camptothecin was a DNA topoisomerase I inhibitor, and some kinds of antitumor agents have been recognized as DNA topoisomerase II inhibitors. Based on these findings, DNA topoisomerases have emerged as target enzymes of antitumor agents in cancer chemotherapy. This paper dealt with investigation on the cytotoxic effects induced by combined use of DNA topoisomerase targeting antitumor agents, especially using CPT-11 as a core antitumor agent. Synchronous administration of CPT-11 with other antitumor agents induced cytotoxic effects less than metachronous administration of CPT-11 with other antitumor agents, especially preceding use of CPT-11. Dose of antitumor agents was not necessarily correlated to the cytotoxic effects. In some instances, small doses of the agents showed better therapeutic effects than large doses. The cytotoxic effects of vincristine, vindesine, and hydroxyurea were reduced by combination with CPT-11. On the other hand, non-cytotoxic agents such as aphidicolin, novobiocin, propentofylline, pentoxifylline, norfloxacin, and tosufloxacin enhanced the cytotoxic effects of CPT-11. Hypothetical consideration of cell killing and acquisition of drug resistance was proposed.
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PMID:[Combination cancer chemotherapy using a DNA topoisomerase inhibitor CPT-11, as a core agent--the in vitro evaluation]. 165 82


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