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)

A new DNA precipitation assay used together with the alkali unwinding assay may provide a rapid means of detecting DNA damage in addition to strand breaks based on the relative amount of damage measured by the two assays. X-rays, Adriamycin, 4-nitroquinoline-N-oxide, N-methyl-N'-nitrosoguanidine, bleomycin, RSU 1172, and five other drugs produced the same relative amount of strand breakage by using the DNA precipitation and alkali unwinding assays. However, strand breaks produced by the bifunctional alkylating agents bis(2-chloroethyl)nitrosourea, RSU 1069, and RSU 1131 were detected with greater efficiency by the DNA precipitation assay, while the unwinding assay measured more strand breaks than the precipitation assay after damage by the topoisomerase inhibitors VP-16 and VM-26 and the DNA-condensing agents acridine orange and pyronin Y. Based on the reported mechanisms of action of these drugs, and studies with known DNA cross-linking agents, it appears that in addition to DNA strand breaks, the alkali unwinding assay is more sensitive to interstrand than to DNA-protein cross-links, while the DNA precipitation assay can be used to detect both types of cross-links. While quantification of specific lesions is not possible with this approach, the concomitant use of these two assays may provide a rapid and simple method for screening genotoxic drugs for DNA damage, and may also help to differentiate between DNA lesions which include strand breaks, interstrand and protein cross-links, DNA-phosphate adducts, and DNA-drug precipitates.
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PMID:Comparison between the DNA precipitation and alkali unwinding assays for detecting DNA strand breaks and cross-links. 318 60

4'-(9-Acridinylamino)methanesulfon-m-anisidide (m-AMSA) and other DNA intercalating agents produce protein-associated DNA strand breaks, the formation of which are mediated by topoisomerase-like chromosomal proteins. As topoisomerases would be expected to be most active during DNA replication, DNA synthesis inhibitors may alter the sensitivity of cellular DNA to intercalator-induced scission. We report that treatment of L1210 cells with 1-beta-D-arabinofuranosylcytosine (ara-C) (0.1 microM) or hydroxyurea (HU) (0.1 mM) for 18 hr resulted in a 2- to 2.4-fold enhancement of m-AMSA-induced protein-associated DNA single-strand breaks and DNA-protein cross-links as measured by alkaline elution. This enhancement was dependent on the duration of ara-C or HU treatment as well as on the concentration of ara-C or HU. Enhancement did not correlate with any alteration in cellular uptake of intercalator or with ara-C- or HU-induced alterations in the DNA synthetic rate. The DNA within nuclei isolated from ara-C- or HU-treated cells also displayed an enhanced susceptibility to m-AMSA-induced scission. There was a correlation between enhanced single-strand break formation and recruitment of cells into S-phase as well as between single-strand break formation and the production of a hypomethylated state of cellular DNA. Concurrent with the enhancement of m-AMSA-induced cellular DNA effects was a synergistic effect on m-AMSA cytotoxicity by ara-C or HU. This enhancement of intercalator effects was also found for the intercalator Adriamycin. We propose that these sublethal concentrations of ara-C and HU alter chromatin structure possibly via DNA hypomethylation and/or altered DNA-histone interactions so that intercalator-induced DNA effects are enhanced. Alternatively, the topoisomerase-like activity involved in intercalator-induced, protein-associated DNA break production may be increased in the nuclei of ara-C- or HU-treated cells.
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PMID:Enhancement of the DNA breakage and cytotoxic effects of intercalating agents by treatment with sublethal doses of 1-beta-D-arabinofuranosylcytosine or hydroxyurea in L1210 cells. 620 99

Doxorubicin, ellipticine and etoposide are antineoplastic drugs with topoisomerase II inhibitory activity. The relationship between drug-induced sister-chromatid exchanges (SCEs) or chromosomal aberrations (CAs) and cytotoxicity, or drug-induced DNA double-strand breaks (DSBs) and cytotoxicity, or drug-induced SCEs and DSBs was investigated in human ovarian cancer cells sensitive (A2780) and resistant (A2780-DX3) to topoisomerase II inhibitors. 30-min drug treatments produced SCEs, CAs and DSBs in sensitive cells, doxorubicin being more potent than etoposide at equimolar concentrations. The same treatments of resistant (A2780-DX3) cells did not produce chromosomal damage (SCEs, CAs, DSBs) and no cytotoxicity was observed. A plot of cytotoxicity versus SCEs indicated a good correlation between these two parameters for topoisomerase II inhibitors and not for mytomicin C. The plot of DSBs versus SCEs also showed a very good correlation.
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PMID:Sister-chromatid exchanges, chromosomal aberrations and cytotoxicity produced by topoisomerase II-targeted drugs in sensitive (A2780) and resistant (A2780-DX3) human ovarian cancer cells: correlations with the formation of DNA double-strand breaks. 752 71

We describe here a simple and easily manipulatable Escherichia coli-based genetic system that permits us to identify bacterial gene products that modulate the sensitivity of bacteria to tumoricidal agents, such as DMP 840, a bisnaphthalimide drug. To the extent that the action of these agents is conserved, these studies may expand our understanding agents is conserved, these studies may expand our understanding of how the agents work in mammalian cells. The approach briefly is to use a library of E. coli genes that are overexpressed in a high copy number vector to select bacterial clones that are resistant to the cytotoxic effects of drugs. AtolC bacterial mutant is used to maximize permeability of cells to hydrophobic organic molecules. By using DMP 840 to model the system, we have identified two genes, designated mdaA and mdaB, that impart resistance to DMP 840 when they are expressed at elevated levels. mdaB maps to E. coli map coordinate 66, is located between the parE and parC genes, and encodes a protein of 22 kDa. mdaA maps to E. coli map coordinate 18, is located adjacent to the glutaredoxin (grx) gene, and encodes a protein of 24 kDa. Specific and regulatable overproduction of both of these proteins correlates with DMP 840 resistance. Overproduction of the MdaB protein also imparts resistance to two mammalian topoisomerase inhibitors, Adriamycin and etoposide. In contrast, overproduction of the MdaA protein produces resistance only to Adriamycin. Based on its drug-resistance properties and its location between genes that encode the two subunits of the bacterial topoisomerase IV, we suggest that mdaB acts by modulating topoisomerase IV activity. The location of the mdaA gene adjacent to grx suggests it acts by a drug detoxification mechanism.
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PMID:A general genetic approach in Escherichia coli for determining the mechanism(s) of action of tumoricidal agents: application to DMP 840, a tumoricidal agent. 756 50

The combination of cytokines and cytotoxic drugs offers a new approach to increase the therapeutic index in the treatment of neoplastic diseases. There is no consensus on optimal strategies for combining these agents so far. The molecular mechanisms underlying the interaction, however, should be defined in order to design clinical trials based on preclinical rationales. The broad spectrum of cytotoxic drugs whose activity can be enhanced by cytokines argues for multiple levels of drug interaction in vitro: alteration in the cellular drug uptake, modulation of drug target enzymes, and changes in metabolism or disposition of a drug. In vivo interaction between cytokines and cytotoxic agents involves an additional layer of complexity because of the effects of cytokines on the host immune system and on drug-metabolizing enzymes. A major mechanism involved in the synergistic interaction of interferon (IFN) and 5-fluorouracil (5-FU) seems to be the increase of active 5-FU metabolites by IFN. Moreover, IFN can reverse resistance against 5-FU by inhibiting the overexpression of thymidylate synthase. The absence of cytokinetic effects of IFN and FU argues against the recruitment of Gs cells into the cell cycle. Topoisomerase has emerged as a critical intracellular target of cytotoxic drugs. There is convincing evidence that the synergy between tumor necrosis factor (TNF) and topoisomerase-targeted intercalative (Adriamycin, doxorubicin hydrochloride; m-AMSA, amsacrine; mitoxantrone) and nonintercalative (VM-16, etoposide; VM-26, teniposide) drugs is related to a rapid increase in specific activity of topoisomerase I and II, resulting in enhanced DNA strand breaks and cleavage complex. Furthermore, sensitivity to topoisomerase II targeted drugs can be enhanced by granulocyte colony-stimulating factor (G-CSF) through elevated enzyme activity in tumor cell response to G-CSF. The synergistic interaction between cytokines and cytotoxic agents seems to be sequence dependent. It has recently been demonstrated that newly synthesized metal compounds and IFN are synergistic only after preincubation with cytokines. Cytokines can modulate expression of adhesion receptors on tumor cell lines, thereby influencing their metastatic potential. A considerable number of phase II trials with combination of cytokines and cytotoxic drugs based on these mechanisms have demonstrated promising response rates and tolerable toxicity. Phase III trials are currently in progress to identify enhanced activity combining cytokines and cytotoxic drugs in the treatment of malignancies.
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PMID:Biochemical modulation of cytotoxic drugs by cytokines: molecular mechanisms in experimental oncology. 759 4

The expression of drug resistance-associated mdr-1, GST pi, and topoisomerase II genes was analyzed in cell cycle phase enriched populations of doxorubicin-resistant murine leukemic P388/R-84 cells. Flow cytometric analysis of bromodeoxyuridine (BrdU) incorporation and staining with anti-BrdU antibodies was used to confirm the purity of cell cycle phase enriched populations obtained by centrifugal elutriation. Doxorubicin (DOX) and daunorubicin (DNR) accumulation was significantly lower in S-phase cells, and coincubation with verapamil (VPL) or chlorpromazine (CPZ) enhanced DOX and DNR accumulation more in S-phase than in G1- and G2/M-phase cells. While the cellular content of mdr-1 and topoisomerase II mRNAs changed, GST pi mRNA content remained constant during the cell cycle. S-phase cells had about 3-fold higher mdr-1 mRNA content than G1- and G2/M-phase cells. In G1 cells, P-glycoprotein expression, as determined by C219 monoclonal antibody, was 12% less than that of S and G2/M cells. Topoisomerase II mRNA content increased with the progression of cell cycle and peaked in G2/M cells. These observations suggest that cell cycle stage related changes in expression of drug resistance markers may have a major bearing on chemosensitivity of drug-resistant cells.
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PMID:Expression of drug resistance-associated mdr-1, GST pi, and topoisomerase II genes during cell cycle traverse. 787 60

A new indolocarbazole antitumor agent, NB-506 [6-N-formylamino-12,13-dihydro-1,11-dihydroxy-13-(beta-D-glucopyranosyl) -5H- indolo[2,3-a]pyrrolo[3,4-c]carbazole-5,7(6H)-dione], enhanced the DNA cleavage catalyzed by HeLa S3 topoisomerase I at 0.01 microM but not the cleavage by topoisomerase II at 300 microM. It also caused single-strand DNA breakage in intact cells at 0.08 microM and more. Unlike the known topoisomerase I inhibitor camptothecin, NB-506 intercalated with DNA. However, the binding affinity to DNA and the inhibition against DNA polymerase alpha and RNA polymerase II were marginal compared with those of Adriamycin or actinomycin D. NB-506 inhibited the growth of various tumor cell lines at two micromoles or less, and its cytotoxicity was found to be cell line selective. This selective cytotoxicity of NB-506 was not fully explained by the differences in topoisomerase I activity in these cell lines, but there was some relationship between the amount of NB-506 accumulated in these cell lines and its cytotoxicity toward them. In conclusion, NB-506 is a potent topoisomerase I poison, acting selectively on tumor cell lines accumulating NB-506.
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PMID:Novel antitumor indolocarbazole compound 6-N-formylamino-12,13-dihydro-1,11- dihydroxy-13-(beta-D-glucopyranosyl)-5H-indolo[2,3-a]pyrrolo[3,4- c]carbazole-5,7(6H)-dione (NB-506): induction of topoisomerase I-mediated DNA cleavage and mechanisms of cell line-selective cytotoxicity. 788 28

It has previously been shown that dexniguldipine-HCl (B8509-035) is a potent chemosensitizer in multidrug resistant cells [Hofmann et al., J Cancer Res Clin Oncol 118: 361-366, 1992]. It is shown here that dexniguldipine-HCl causes a dose-dependent reduction of the labeling of the P-glycoprotein by azidopine, indicating a competition of dexniguldipine-HCl with the photoaffinity label for the multidrug resistance gene 1 (MDR-1) product. Exposure to dexniguldipine-HCl results in a dose-dependent accumulation of rhodamine 123 in MDR-1 overexpressing cells. In the presence of 1 microM dexniguldipine-HCl, rhodamine 123 accumulated in multidrug resistant cells to similar levels as in the sensitive parental cell lines. At this concentration, dexniguldipine-HCl enhances the cytotoxicities of Adriamycin and vincristine. The resistance modulating factors (RMF), i.e. IC50 drug/IC50 drug + modulator, were found to be proportional to the expression of MDR-1, ranging from 8 to 42 for Adriamycin and from 16 to 63 for vincristine. Transfection with the MDR-1 gene was found to be sufficient to sensitize cells to the modulation by dexniguldipine-HCl. The compound does not affect the expression of the MDR-1 gene. Dexniguldipine-HCl has no effect on a multidrug resistant phenotype caused by a mutation of topoisomerase II. It is concluded that dexniguldipine-HCl modulates multidrug resistance by direct interaction with the P-glycoprotein.
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PMID:Mechanism of action of dexniguldipine-HCl (B8509-035), a new potent modulator of multidrug resistance. 788 74

N-Benzyladriamycin-14-valerate (AD 198)-resistant murine J774.2 macrophage-like cells (A300) exhibited a novel mechanism of resistance in which P-glycoprotein was overexpressed without decreased AD 198 accumulation. Cross-resistance to Adriamycin (ADR), N-benzyladriamycin, and Adriamycin-14-valerate was due, at least in part, to reduced accumulation, suggesting that circumvention of P-glycoprotein-mediated transport was associated with extreme lipophilicity conferred by both substitutions. Thus, unlike multidrug resistance mediated by either P-glycoprotein, the multidrug resistance-associated protein (MRP), or decreased topoisomerase II activity, cross-resistance in A300 cells was highly structure-specific. In order to further characterize the specificity of AD 198 resistance, the cytotoxicity, accumulation, and intracellular localization of a series of 3'-morpholinyl, 3'-deamino and halogenated ADR congeners that have been reported to circumvent MDR was determined in AD 198-resistant J774.2 and P388 AD 198-resistant cells. Cross-resistance correlating with increased AD 198 resistance was observed for 2'-bromo-4'-epi-hydroxy-daunomycin (13-fold), morpholinyl doxorubicin (24-fold), and 4'-iodo-4'-deoxydoxorubicin (2.8-fold), but was attributable to decreased accumulation. Cross-resistance to 3'-hydroxy-14-O-palmitoyl-doxorubicin (6-fold) was not due to reduced accumulation. No cross-resistance was observed for the highly cytotoxic metabolite of WP474, 3'-hydroxyldoxorubicin (hydroxyrubicin; WP159), nor for the much less cytotoxic 3'-O-benzylated congeners, including 3'-O-benzyl-doxorubicin-14-valerate. These findings indicate that AD 198 resistance confers cross-resistance to compounds that, like AD 198, localize in the cytoplasm but are metabolized to highly cytotoxic, nuclear-localizing compounds.
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PMID:N-benzyladriamycin-14-valerate (AD 198)-resistant cells exhibit highly selective cross-resistance to other anthracyclines that circumvent multidrug resistance. 790 37

Etoposide (VP-16) is one of the most important anticancer agents available and is used in many chemotherapeutic regimens. To characterize resistance to this drug, we established a VP-16-resistant human ovarian cancer cell line, SKOV3/VP, by continuous stepwise exposure of SKOV3 cells to VP-16. The degree of resistance to VP-16 of SKOV3/VP was about 25 times that of the parent cell line (SKOV3), and SKOV3/VP showed cross-resistance to teniposide, adriamycin, CPT-11, and vincristine. The accumulation of [3H]-VP-16 observed in SKOV3/VP cells was about half that seen in SKOV3 cells, and the accumulation of Adriamycin by this resistant cell line was also lower than that of its parent. Overexpression of neither the multidrug resistance gene mdr-1, the multidrug-resistance-associated protein (mrp) gene, nor P-glycoprotein was detected using reverse transcriptase-polymerase chain reaction analysis and flow cytometry with MRK-16, a monoclonal antibody against P-glycoprotein. The topoisomerase II activity of nuclear extracts from SKOV3/VP cells was lower than that from the parental cells, as was the amount of DNA topoisomerase II, demonstrated by immunoblotting. These results suggest that the mechanism responsible for the multidrug resistance of this cell line may be attributable to changes on its DNA topoisomerase II and to its reduced accumulation of the drugs as compared with the parental line SKOV3.
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PMID:Characterization of an etoposide-resistant human ovarian cancer cell line. 791 42


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