EC:3.6.3.44 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.6.3.44 (P-glycoprotein)
13,344 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Over the past decade, DNA topoisomerase I and II appeared to be the targets of some antitumor agents: CPT-11 and Topotecan derived from Camptothecin which interact with topoisomerase I; Actinomycin D, Adriamycin and Daunorubicin, Elliptinium Acetate, Mitoxantrone, Etoposide and Teniposide, Amsacrine which interact with topoisomerase II. The multiple functions of these enzymes are important as they play a role during replication, transcription, recombination, repair and chromatine organisation. Particularly, they relax torsional constraints which appear when intertwined DNA strands are separated while replication fork or RNA polymerases are moving. To some extent, topoisomerase I and II are structurally and functionally different. Moreover, topoisomerase I is not indispensable for a living cell whereas topoisomerase II is. Drug-topoisomerase interaction which probably leads to antitumoral effect of the compounds studied in this review is not a trivial inhibition of the enzyme but rather a poisoning due to stabilization of cleavable complexes between the enzyme and DNA. These stabilized complexes are likely to induce apoptosis-like programmed cell death, which is characterised by DNA fragmentation. However, it appears that it is the collision of the replication fork with the drug-stabilized cleavable complex that is responsible for the cytotoxicity of the drug: poisoning of topoisomerases by antitumor agents leads to a new concept of "dynamic toxicity". Although they interact with a common target, topoisomerase II poisons have differential effects on macromolecules syntheses, cell cycle and chromosome fragmentation; a few compounds may produce free radicals. Because of these differential effects in addition to quantitative and qualitative variations of stabilized cleavable complexes, in particular DNA sequences on which topoisomerase II is stabilized, these antitumor agents do not resemble each other. Cellular resistance to topoisomerases poisons results of two principal types of alteration: target and/or drug transport modification. Decreased ability to form the cleavable complex in resistant cells may be the consequence of both decreased amount of topoisomerase or altered enzyme. On the other hand, overexpression of membrane P-glycoprotein, which pumps drugs out of the cell by an energy dependent process provokes a decreased accumulation of these drugs. Cross resistances to other drugs are mainly under control of these two different mechanisms of resistance. A complete knowledge of their individual effects and mechanisms of resistance would allow a better clinical use of topoisomerases poisons, especially when administered in combination chemotherapy.
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PMID:[Poisons of DNA topoisomerases I and II]. 808 Oct 34

The cytotoxic alkaloid camptothecin (CPT) and several of its analogues, including the clinically relevant topotecan (TPT), irinotecan (CPT-11), and 9-aminocamptothecin, were evaluated for differential cytotoxic effect and DNA damage induction in multidrug-sensitive (AuxB1) and multidrug-resistant (MDR) (CHRC5) Chinese hamster ovary cells. CPT, 10-hydroxycamptothecin, and 10,11-methylenedioxycamptothecin produced equivalent amounts of cell growth inhibition and/or DNA single-strand breakage in the two cell lines. TPT, SN-38 (the active metabolite of CPT-11), and 9-aminocamptothecin were 12-, 9-, and 10-fold, respectively, less toxic to the MDR than to the wild-type cells. These findings are consistent with differences in yields of DNA single-strand breaks produced in AuxB1 and CHRC5 cells by 2-hr incubations with the various compounds. In both assays, the resistance ratios of the topoisomerase I inhibitors were approximately one-tenth those of known MDR drugs such as vinblastine or amsacrine. Thus, cultured cells that overexpress P-glycoprotein have the potential to develop some level of cross-resistance to all three topoisomerase I inhibitors currently in the clinic. The chemical basis for cross-resistance of cultured MDR cell lines to certain CPT analogues is not yet understood, but is likely more complex than positive charge alone. TPT had a reasonable therapeutic effect on B6D2F1 female mice implanted with MDR sublines of P388 leukemia, compared with its effect on mice implanted with wild-type P388 cells.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:In vitro and in vivo effects of clinically important camptothecin analogues on multidrug-resistant cells. 808 68

In order to clarify the mechanism of drug resistance in human myeloma cells, we investigated the expressions of DNA topoisomerase I and topoisomerase II gene and the genes possibly related to drug resistance; multi-drug resistant gene 1 (MDR-1), glutathione S-transferase class pi gene (GST-pi), by Northern blotting. Myeloma cells in eight of 15 cases prior to chemotherapy expressed topoisomerase I mRNA considerably, while the expression of topoisomerase II mRNA was detected weakly in only one of 16 myeloma patients. There was not any correlation between expression of topoisomerase I mRNA and clinical drug resistance. Significant expression of MDR-1 mRNA and P-glycoprotein was not detected in 25 cases of multiple myeloma prior to chemotherapy and even after several courses of VAD (vincristine, adriamycin and dexamethasone) therapy by Northern blotting and immunostaining using monoclonal anti-P-glycoprotein antibody (MRK-16), respectively. On the other hand, 16 of 21 myeloma cases showed significant expression of GST-pi protein and GST-pi mRNA with the various strengths, but there was no apparent correlation between GST-pi mRNA expression and clinical response. Therefore these data suggest that expression of the genes we tested may not determine the level of drug resistance in multiple myeloma, but lower or no significant expression of topoisomerase II mRNA in most myeloma cells indicates the possibility that topoisomerase II inhibitors such as VP-16 and topoisomerase II-mediated cytotoxic drugs such as adriamycin, are not so effective for the treatment of multiple myeloma.
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PMID:Expressions of DNA topoisomerase I and II gene and the genes possibly related to drug resistance in human myeloma cells. 809 26

The nuclear enzyme topoisomerase I (topo I) has been recently recognized as the target for the anticancer drug camptothecin (CPT) and its derivatives. Two of the agents that target this enzyme--topotecan (TPT) and CPT-11--appear to be active against a broad range of human tumors. In the following presentation, we review 1) the role of topo I in normal cells, 2) the chemistry and proposed mechanism of action of CPT and its analogues, 3) the results of preclinical and clinical testing of TPT and CPT-11, and 4) mechanisms of resistance to these agents. In normal cells, topo I is thought to be involved in gene transcription and DNA replication. During the course of its normal catalytic cycle, topo I transiently forms a covalent bond with DNA. CPT and its derivatives slow the religation step of the enzyme and stabilize the covalent adduct between topo I and DNA. In S-phase cells, advancing replication forks convert these topo I-DNA adducts into double-strand breaks that appear to be responsible for the cytotoxicity of these agents. Preclinical studies demonstrate antineoplastic activity for TPT and CPT-11 in a variety of tumor models. Phase I studies have identified neutropenia as the dose-limiting toxicity for both drugs. Gastrointestinal effects might also be dose-limiting for CPT-11 administered on some schedules. CPT-11 has shown antitumor activity in phase II trials for patients with carcinomas of lung, cervix, ovary, colon, and rectum and for patients with non-Hodgkin's lymphoma. Phase II studies of TPT are in progress. Resistance to the cytotoxic effects of these agents might result from decreased production of topo I or from production of a mutated form of topo I. In addition, decreased metabolic activation of CPT-11 (which is a pro-drug) and active efflux of TPT by P-glycoprotein-mediated transport might contribute to resistance. As agents with a novel mechanism of action, tolerable toxicity, and encouraging antitumor activity in early clinical trials, TPT and CPT-11 are undergoing further clinical development. If these agents can be successfully combined with other active chemotherapy agents, the topo I-directed agents offer the potential for significant advances in the treatment of patients with a variety of malignancies.
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PMID:The current status of camptothecin analogues as antitumor agents. 838 Nov 86

We examined the expression of the genes encoding topoisomerases I and II and those associated with V(D)J [variable(diversity)joining] recombination in two human T-cell acute lymphoblastic leukemia (T.ALL) cell lines, CEM and CEM/DOX. In CEM/DOX cells, which are resistant to doxorubicin, the topoisomerase I gene was found to be 4-fold overexpressed and nuclear topoisomerase I relaxation activity was 2-fold greater in CEM/DOX than in CEM cells. Furthermore, the cleavable complex reaction induced by camptothecin, a specific topoisomerase I inhibitor, was found to be 2.5-increased in the presence of topoisomerase I extracted from CEM/DOX, in comparison to that in CEM cells. Conversely, the topoisomerase II mRNA levels, nuclear decatenation activities and (mAMSA) 4'(9-acridinylamino)methanesulfon-m-anisidide-induced cleavable complex formation in CEM/DOX were similar to those of the doxorubicin-sensitive cells. The results indicate that topoisomerase I activity is elevated in CEM/DOX cells. Nevertheless, CEM/DOX cells were 11-fold more resistant to camptothecin than were CEM cells, and cross-resistance to camptothecin was not reversed by verapamil. Furthermore, using an intact cell assay for DNA-protein complexes, we found that camptothecin-stimulated cleavable complexes formed in CEM/DOX cells were increased in correlation with the elevated topoisomerase I activity. These results suggest that camptothecin resistance in CEM/DOX cells is due to different mechanism(s) than topoisomerase- or P-glycoprotein-associated multidrug resistance. The recombination activating gene, RAG1, which is one of the components of the site-specific V(D)J recombination complex, was 20-fold overexpressed in CEM/DOX cells. In contrast, RAG2 and T160 gene transcripts, other components of the V(D)J complex, were at best poorly detected in both sensitive and resistant cells. No specific V(D)J recombinase activity was found in CEM or CEM/DOX cells when the pJH201 transfection assay was used. The results indicate that CEM/DOX cells failed to generate V(D)J recombination although RAG1 gene is overexpressed. The mechanism of the RAG1 gene activation was not gene amplification, and no rearrangement was detected in the RAG1 gene locus. RAG1 presents homology with the yeast gene HPR1, itself homologous to yeast topoisomerase I and responsible for the control of recombination in somatic cells. Since DNA topoisomerases are themselves involved in the control of DNA topology, recombination and DNA repair, the possible coactivation of RAG1 and topoisomerase I genes in CEM/DOX cells is discussed.
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PMID:Altered topoisomerase I activity and recombination activating gene expression in a human leukemia cell line resistant to doxorubicin. 839 37

For investigation of relative differences in mRNA expression levels and of correlations in the expression of genes possibly involved in multidrug resistance (MDR) of acute myelogenous leukemias (AML), a complementary DNA polymerase chain reaction (cDNA-PCR) analysis was established for the genes encoding MDR1/P-glycoprotein, the multidrug resistance-associated protein (MRP), topoisomerase II alpha, topoisomerase II beta, topoisomerase I, glutathione S-transferase pi, protein kinase C (PKC) isozymes alpha, beta 1, beta 2, epsilon, eta, theta and cyclin A. In a first descriptive study comprising samples of childhood or adult AML we calculated the mean values from primary (n=14) or relapsed (n=23) states of the diseases, respectively. We found in the latter significant increases of MDR1, MRP, gst pi, and PKC theta gene expression. MDR1 and MRP gene expression levels were generally correlated (rs= +0.4128, P<0.02, n=37), as well as topoisomerase II alpha and cyclin A gene expression levels (rs= +0.8727, P<0.0001, n=35). Within the group of relapsed state AML a significant negative correlation between the gene expression levels of MDR1 and topoisomerase II alpha (rs= -0.5500, P<0.01, n=22) was observed. Remarkably, highly significant positive correlations were found for MDR1/PKC eta (rs= +0.5560, P<0.001, n=32), MRP/PKC theta (rs= +0.6573, P<0.0001, n=34) and MRP/PKC eta (rs= +0.5241, P<0.005, n=32).
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PMID:Expression of PKC isozyme and MDR-associated genes in primary and relapsed state AML. 864 57

Characteristics of multiple-drug resistance of rat ascites hepatoma AH66, a cell line induced by dimethylaminoazobenzene and established as a transplantable tumor, were compared with those of AH66F, a drug sensitive line obtained from AH66. The AH66 cell line was resistant to vinblastine, adriamycin, SN-38 an active form of camptothesine, etoposide, and clorambucil by 10-fold or more than the AH66F cell line. The resistance of AH66 cells to vinblastine, adriamycin, and SN-38 was closely related to P-glycoprotein overexpression in the plasma membrane, because the resistance was significantly inhibited by verapamil. AH66 cells contained much glutahione and had a high activity of glutathione S-transferase P-form (GST-P), compared with AH66F cells, and resistance to clorambucil was decreased by treatment with buthionine sulfoximine, an inhibitor of glutathione synthesis. AH66 cells have a similar topoisomerase I activity, but about 6 times lower topoisomerase II activity than AH66F cells. Therefore, the resistance to etoposide and a part of the resistance to adriamycin of AH66 cells seems to depend upon this low topoisomerase II activity. These results, show that the AH66 cell line has high multiple-drug resistance compared with the AH66F cell line, by several mechanisms. Consequently, the AH66 and AH66F cell lines are useful to study naturally acquired multiple-drug resistance of hepatomas.
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PMID:Characterization of naturally acquired multiple-drug resistance of Yoshida rat ascites hepatoma AH66 cell line. 870 43

Primary and acquired resistance of tumor cells to antineoplastic drugs is a major cause of the limited efficiency of chemotherapy. Gastrointestinal (GI) tumors have proven to express cytostatic drug resistance at an unusually high rate. One major reason for this is the multidrug resistant (MDR) phenotype which is often found in carcinomas of the stomach, bile duct, pancreas, liver, and colon. MDR is due to the overexpression of a membrane-bound glycoprotein, the so called P-glycoprotein. However, this is not the only resistance mechanisms of GI tumor cells, but the intracellular compartmentalization of drugs with subsequent release to the microenvironment represents an additional potent mechanism of drug resistance. This is independent of P-glycoprotein and as yet cannot be reversed. Alterations of glutathione-S-transferase (GST) and topoisomerase I and II may be involved either. Analyses of cell lines for cross resistance against a battery of cytostatic drugs suggest even more mechanisms which may contribute to the marked resistance of gastrointestinal cancer. Only a detailed investigation of all different types of drug insensitivity, if ever possible, might offer a chance to fully understand this multifactorial orchestra of events and to develop complex strategies for overcoming drug resistance.
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PMID:Molecular mechanisms and possibilities of overcoming drug resistance in gastrointestinal tumors. 889 37

The cytotoxic activity and cross-resistance pattern of the novel topoisomerase I inhibitor topotecan (Topo) were investigated in ten cell lines, representing different mechanisms of cytotoxic drug resistance, and in 218 fresh human tumour samples using the fluorometric microculture cytotoxicity assay (FMCA). Resistance to Topo in the cell lines was associated with expression of the multidrug resistance-associated protein (MRP), whereas the cell lines with P-glycoprotein (P-gp), topoisomerase II and glutathione-associated resistance did not show decreased sensitivity to the drug. Topo was more active in haematological than in solid tumour samples, but substantial activity was observed in carcinomas of the ovary and breast, sarcoma and childhood solid tumours. Cross-resistance to standard drugs representing different mechanisms of action was generally low in patient cells. The effect of Topo was better after longer exposure, but this time-dependent effect was largely abolished when adjustment for in vitro exposure was made. Topo showed activity both in proliferative and non-proliferative cell systems. The results indicate that Topo is insensitive to major mechanisms of resistance except for MRP. Proliferation does not seem to be necessary for the effect of Topo, and no superiority for protracted dosing schedules was observed. The results also suggest that, for example, leukaemias, lymphomas, sarcomas and childhood solid tumours may be suitable targets for future phase II trials.
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PMID:Cytotoxic activity of topotecan in human tumour cell lines and primary cultures of human tumour cells from patients. 923 21

The nuclear enzymes DNA topoisomerases I and II appeared as cellular targets for several antitumor drugs: campthotecin derivatives interacting with topoisomerase I, and actinomycin D, anthracycline derivatives, elliptinium acetate, mitoxantrone, epipodophyllotoxine derivatives, amsacrine and a new olivacine derivative, NSC-6596871 (S 16020-2), which interact with topoisomerase II. The functions of these enzymes are numerous and important since they are critical for DNA functions and cell survival. Despite the fact that they share the same target, topoisomerase II inhibitors have different mechanisms of action. Two principle types of induced alterations are involved in cellular resistance to topoisomerase II drugs: qualitative or quantitative alteration of the enzyme and/or increased drug efflux due to overexpression of P-glycoprotein. S 16020-2, a new olivacine derivative with a high antitumor activity against solid tumors, shows a potent cytotoxic effect against tumor cells expressing P-glycoprotein. This observation suggests that the comprehension of the respective effects of topoisomerase inhibitors and the precise knowledge of their mechanisms of resistance would improve the use of this therapeutic class in the clinic within rational chemotherapeutic combinations.
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PMID:DNA topoisomerase targeting drugs: mechanisms of action and perspectives. 940 7

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