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)

Among the different mechanisms of multidrug resistance, the overexpression of the mdr1 gene has been actively investigated during the last 5 years. This gene encodes a 170 kDa protein, named P-gp, a member of a transporter superfamily, the ABC (ATP Binding Cassette) proteins. P-gp actively expels out of the tumoral cell different drugs like anthracyclins, vinca alkaloids, epipodophyllotoxins. The involvement of mdr1 gene in clinical drug resistance is now demonstrated, and several trials using P-gp modulators and chemotherapy are going on in resisting tumors. Other intrinsic drug resistance mechanisms, such as increase of intracellular glutathione content or decrease of topoisomerase activity, could be involved in clinical drug resistance.
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PMID:[Drug resistance genes]. 135 69

The cytoxicity of both intercalating (m-AMSA) and non-intercalating (VP16, VM26) topoisomerase II-targeting drugs is thought to occur via trapping DNA topoisomerase II on DNA in the form of cleavable complexes. First, analysis of cleavable complexes (detected as DNA double-strand breaks) by pulsed-field gel electrophoresis confirmed the correlation between cleavable complex formation and cytotoxicity of three topoisomerase-targeting drugs in HeLa S3 cells (the order of effects being VM26 > m-AMSA > VP16). In contrast to many antineoplastic agents, hyperthermic treatments were found to protect cells against the toxicity of all three topoisomerase II drugs. Hyperthermia treatment does not alter drug accumulation but reduces the ability of the drug-topoisomerase II complex to form the cleavable complexes. Nuclear protein aggregation induced by heat at the sites of topoisomerase II-DNA interaction may explain such an effect. In thermotolerant cells, the toxic effects of VP16 but not m-AMSA were reduced. For both drugs, however, the status of thermotolerance did not affect cleavable complex formation by the drugs. Thus, protection against VP-16 toxicity seems not to be associated with heat-induced activation of the P-gp 170 pump or altered topoisomerase II-DNA interactions. Rather, a protective (heat shock protein mediated?) mechanism against non-intercalating topoisomerase II drugs seems to occur at a stage after DNA-drug interaction. Finally, heat treatment before topoisomerase II drug treatment reduced toxicity and cleavable complex formation in thermotolerant cells to about the same extent as in non-tolerant cells, consistent with the presumption of nuclear protein aggregation being responsible for this effect.
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PMID:Hyperthermia, thermotolerance and topoisomerase II inhibitors. 764 Feb 14

The acquisition of the multidrug resistance phenotype in human tumours is associated with an overexpression of the 170 kDa P-glycoprotein encoded by the multidrug resistance 1 (MDR1) gene, and also with a 190 kDa membrane ATP-binding protein encoded by a multidrug resistance-associated protein (MRP) gene. Human bladder cancer is a highly malignant neoplasm which is refractory to anti-cancer chemotherapy. In order to understand the mechanism underlying multidrug resistance in bladder cancer, we established three doxorubicin-resistant cell lines, T24/ADM-1, T24/ADM-2 and KK47/ADM, and one vincristine-resistant cell line, T24/VCR, from human bladder cancer T24 and KK47 cells respectively. Both T24/ADM-1 and T24/ADM-2 cells which had elevated MRP mRNA levels showed both a cross-resistance to etoposide and a decreased intracellular accumulation of etoposide. T24/VCR cells which had elevated levels of MDR1 mRNA and P-glycoprotein but not of MRP mRNA, showed cross-resistance to doxorubicin. On the other hand, KK47/ADM cells, which had elevated levels of both MRP and MDR1 mRNA and a decreased level of topoisomerase II mRNA, were found to be cross-resistant to etoposide, vincristine and a camptothecin derivative, CPT-11. Our present study demonstrates a concomitant induction of increased levels of MRP mRNA, decreased levels of topoisomerase II mRNA and decreased drug accumulation during development of multidrug resistance in human bladder cancer cells. The enhanced expression of the MRP gene is herein discussed in a possible correlation with the decreased expression of the topoisomerase II gene.
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PMID:Expression of multidrug resistance-associated protein (MRP), MDR1 and DNA topoisomerase II in human multidrug-resistant bladder cancer cell lines. 773 14

Nuclear morphological alterations associated with multidrug resistance (MDR) were evaluated by image cytometry in various human leukemic cell sub-lines: 3 cell lines with P-gp-mediated resistance (CEM-VLB, HL60/Vinc, K562-Dox), the non-Pgp-mediated MDR HL60/AR leukemic cell line with over-expression of MRP, and the at-MDR CEM-VMI leukemic cell line with alteration of topoisomerase II. All these MDR cell sub-lines were obtained by drug selection and were compared with their sensitive counterparts and with the hamster LR73-R cell line obtained by transfection of mouse mdrl cDNA. All MDR cell sub-lines obtained by drug selection displayed decreased DNA Feulgen stainability as compared with their respective sensitive parental cell line, a phenomenon not observed in the transfected LR73-R cells. Nuclear texture analysis on G0/G1-selected cell nuclei revealed 2 types of textural phenotype. The first phenotype was characterized by chromatin decondensation with small but compact chromatin clumps, and was observed in drug-selected P-gp-mediated MDR cells (CEM-VLB, HL60-Vinc, K562-Dox) and in the non-P-gp-mediated MDR HL60/AR cell line. The second phenotype was characterized by a condensed and homogeneous chromatin pattern, and was observed in the at-MDR CEM-VMI cell line. LR73-R cells transfected with mdrl cDNA did not display any significant changes in textural phenotype as compared with sensitive LR73 cells, suggesting that P-gp over-expression alone cannot account for the cytological modifications observed in MDR cells. These data suggest that multidrug resistance could be associated with specific nuclear morphological changes which appeared to be a consequence of alterations occurring during selection by cytotoxic drugs rather than of P-gp over-expression.
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PMID:Nuclear DNA content and chromatin texture in multidrug-resistant human leukemic cell lines. 781 42

A human breast cancer cell line (MCF7/WT) was selected for resistance to etoposide (VP-16) by stepwise exposure to 2-fold increasing concentrations of this agent. The resulting cell line (MCF7/VP) was 28-, 21-, and 9-fold resistant to VP-16, VM-26, and doxorubicin, respectively. MCF7/VP cells also exhibited low-level cross-resistance to 4'-(9-acridinylamino)-methanesulfon-m-anisidide, mitoxantrone, and vincristine and no cross-resistance to genistein and camptothecin. Furthermore, these cells were collaterally sensitive to the alkylating agents melphalan and chlorambucil. DNA topoisomerase II levels were similar in both wild-type MCF7/WT and drug-resistant MCF7/VP cells. In contrast, topoisomerase II from MCF7/VP cells appeared to be 7-fold less sensitive to drug-induced cleavable complex formation in whole cells and 3-fold less sensitive in nuclear extracts than topoisomerase II from MCF7/WT cells. Although this suggested that the resistant cells may contain a qualitatively altered topoisomerase II, no mutations were detected in either the ATP-binding nor the putative breakage/resealing regions of either DNA topoisomerase II alpha or II beta. In addition, the steady-state intracellular VP-16 concentration was reduced by 2-fold in the resistant cells, in the absence of detectable mdr1/P-gp expression and without any change in drug efflux. In contrast, expression of the gene encoding the MRP was increased at least 10-fold in resistant MCF7/VP cells as compared to sensitive MCF7/WT cells. These results suggest that resistance to epipodophyllotoxins in MCF7/VP cells is multifactorial, involving a reduction in intracellular drug concentration, possibly as a consequence of MRP overexpression, and an altered DNA topoisomerase II drug sensitivity.
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PMID:Multidrug resistance-associated protein gene overexpression and reduced drug sensitivity of topoisomerase II in a human breast carcinoma MCF7 cell line selected for etoposide resistance. 790 2

One of the main problems in clinical oncology is an acquired cellular drug resistance. Special attention deserves the multidrug resistance phenomenon (MDR) involving tumors which become resistant to a wide spectrum of non-related drugs to which they have never been exposed. Several mechanisms responsible for this phenomenon have been described. Among them is the increased expression of the MDR1 gene which encodes the plasma membrane glycoprotein P-gp. This glycoprotein is an energy-dependant multidrug efflux pump of wide specificity. It seems to have a normal physiological function but in some tumors resistant to chemotherapy its expression is increased. In cell lines the increased expression of P-gp is correlated with a decreased accumulation and retention of drugs inside the cells. In addition to P-gp, at least two other mechanisms of multidrug resistance have been described: a decreased expression and changes in the catalytic activity of topoisomerase II enzyme, and changes in glutathione transferase levels. Through biochemical and molecular methods researchers continue to look for a correlation between non-responding tumors and changes in the known drug-resistance mechanisms. These studies suggest that several factors are involved in the cellular drug resistance observed in human tumors, and probably are interacting between them. In clinical practice, the need of controlling MDR phenomena has led to the creation of alternate therapeutic strategies.
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PMID:[Multiple drug resistance: a problem in cancer chemotherapy]. 790 10

Peripheral blood samples from 18 patients with chronic lymphocytic leukemias (CLL) who were either untreated but who were later sensitive to chlorambucil (CLL S) or resistant to a combination containing doxorubicin, vincristine, cyclophosphamide and prednisone (CLL R) were studied for glutathione system, P-glycoprotein, PCNA and topoisomerase II expression. P-glycoprotein expression detected by an immunocytochemical technique using MRK 16 antibody was present at the same level in CLL S and CLL R. The percentage of cells positive for P-gp was below 5% in all samples tested. Topoisomerase IIalpha level was quantified by Western blot analysis. None of the 18 CLL samples had detectable topoisomerase IIalpha protein. In addition, 12 CLL were tested for PCNA staining and no samples had more than 1% of positive cells at immunocytochemical detection indicating that CLL cells were not engaged in the cell cycle. Some differences were found between CLL S and CLL R in the glutathione system. Glutathione concentration (GSH) and GST activity was the same in CLL S and CLL R. The glutathione-S-transferase (GST) isoenzyme profile was different in the two CLL groups. The mean GST-pi and GST-alpha quantitation were twice as high as in CLL R compared to CLL S, but this difference did not reach statistical significance because of large variations between CLL samples. A significant correlation was observed between GST-pi expression and GST activity using CDNB as the substrate. GST-mu was detected in only one of seven CLL before therapy and in six of 11 resistant to chemotherapy. No correlation was found between P-glycoprotein expression, GST activity and the different GST isoenzymes studied. These results suggest that the glutathione system could play a role in the resistance of anticancer agents in chronic lymphocytic leukemia. The role of the other drug resistance mechanisms (P-glycoprotein and topoisomerase IIalpha) seems to be of limited importance.
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PMID:Drug resistance mechanisms in chronic lymphocytic leukemia. 894 35

The thioether phospholipid ilmofosine (BM 41 440) is a new anti-cancer drug presently undergoing phase II clinical trials. Because resistance to anti-tumour drugs is a major problem in cancer treatment, we investigated the resistance of different cell lines to this compound. Here we report that the multidrug-resistant cell lines MCF7/ADR, CCRFNCR1000, CCRF/ADR500, CEM/VLB100 and HeLa cell lines transfected with a wild-type and mutated (gly/val185) multidrug resistance 1 gene (MDR1) are cross-resistant to ilmofosine compared with the sensitive parental cell lines. In CEMNM-1 cells, in which the resistance is associated with an altered topoisomerase II gene, no cross-resistance to ilmofosine was observed. Ilmofosine is not capable of modulating multidrug resistance and neither does it reduce the labelling of the P-glycoprotein (P-gp) by azidopine nor alter ATPase activity significantly. The resistance to ilmofosine in multidrug-resistant CCRF/VCR1000 cells cannot be reversed by the potent multidrug resistance modifier dexniguldipine-HCI (B8509-035). A tenfold excess of ilmofosine does not prevent the MDR-modulating effect of dexniguldipine-HCl. Treatment of cells with ilmofosine does not alter the levels of MDR1 mRNA. Long-term treatment of an ilmofosine-resistant Meth A subline with the drug does not induce multidrug resistance, indicating that ilmofosine does not increase the level of P-gp. Determination of the MDR2 mRNA levels in the cells revealed that the resistance pattern to ilmofosine is not correlated with the expression of this gene. It is concluded, therefore, that multidrug-resistant cells are cross-resistant to ilmofosine and that the compound is not a substrate of Pgp. No association between the expression of the MDR2-encoded P-gp and resistance to ilmofosine was observed. It is supposed that MDR1-associated alterations in membrane lipids cause resistance to ilmofosine.
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PMID:Resistance to the new anti-cancer phospholipid ilmofosine (BM 41 440). 932 44

The antineoplastic action and development of drug resistance are reviewed for chemotherapeutic agents used in the treatment of sarcoma, including alkylating agents (cyclophosphamide, ifosphamide, dacarbazine), platinum compounds (cisplatin, carboplatin), the anthracycline compound doxorubicin, the topoisomerase II inhibitor etoposide, and the taxanes (paclitaxel, taxotere). Drug resistance mechanisms discussed include changes in intracellular glutathione and metallothione levels, increased aldehyde dehydrogenase levels, enhanced DNA repair and protection from apoptosis (for alkylating agents); increased 0-6 alkyltranferase levels (for dacarbazine); multidrug resistance 1- and multidrug resistance associated protein-mediated drug export from cells (anthracyclines, taxanes); and structural alteration of microtubules (taxanes).
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PMID:Drug resistance in the treatment of sarcomas. 934 25

The efficacy of cancer treatment is limited by either intrinsic or acquired resistance to various chemotherapeutic agents. To evaluate the clinically important factors related to prognosis in primary breast cancer retrospectively, we investigated the expression of the following genes involving acquirement of drug resistance: multidrug resistance 1 (MDRl), multidrug resistance-associated protein (MRP), and topoisomerase (Topo) I, II alpha, and II beta. Using an RT-PCR method, we semiquantified the gene expression level in untreated stage II breast cancer tissue (n = 27) and noncancerous breast tissue (n = 10). Among the 27 cancer patients, who were all treated by adjuvant chemoendocrine therapy after surgery, 10 patients showed relapse within the following 10 years whereas 17 patients did not. The gene expression levels of MDRl, MRP, and Topo I, II alpha, and II beta were normalized to the level of the beta 2-microglobulin RT-PCR product. MRP mRNA expression was detected in 70% of the breast cancer tissues and its expression levels were significantly increased in the cancer group compared with the noncancerous breast tissues. Furthermore, the MRP level was much higher in the relapsed patient group. On the other hand, there were no significant differences in the MDRl mRNA levels between the noncancerous and cancer groups. Although Topo II alpha mRNA was not detected in noncancerous breast tissues, it was detected in 52% of the breast cancer tissues. In cancer patients, no significant difference in Topo II alpha mRNA levels was observed between the relapsed and nonrelapsed groups. These findings suggest that MRP might be used as one of the markers for poor prognosis in patients with breast cancer.
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PMID:Clinical significance of the increased multidrug resistance-associated protein (MRP) gene expression in patients with primary breast cancer. 966 17


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