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)

Mechanisms responsible for drug resistance in human esophageal cancer cell lines were investigated. Three cell lines established from human esophageal carcinoma (TE-1, SH-1, and TH) showed different sensitivities to vindesine, vincristine, cisplatin (CDDP), etoposide (VP-16), and pepleomycin. Both SH-1 and TH cell lines were twofold to sevenfold more resistant to pepleomycin, vindesine, and vincristine than TE-1 was. SH-1 showed twofold more resistance to CDDP than either TE-1 or TH did, and TH and TE-1 showed a 3-fold or 1.5-fold more resistance, respectively, to VP-16 than SH-1 did. The accumulation of tritiated vincristine in SH-1 and TH was approximately 50% that in TE-1. Two multidrug resistance reversal agents, cepharanthine and a synthetic dihydropyridine analogue (NK-252; Nikken Chemicals, Saitama, Japan), potentiated the cytocidal actions of vindesine against SH-1, TH, and TE-1 cells, with no apparent expression of P-glycoprotein in the three cell lines. The glutathione S-transferase pi gene was expressed in all three cell lines. DNA topoisomerase II levels were lowest in TE-1, followed by SH-1 and TH, although the accumulation of tritiated VP-16 was less in both TH and SH-1 than in TE-1. Differential sensitivities to anti-cancer drugs appear to be mediated through pleiotropic mechanisms.
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PMID:Different sensitivities of human esophageal cancer cells to multiple anti-cancer agents and related mechanisms. 135 26

A mitoxantrone-resistant human MCF-7 breast cancer subline (MCF/MX) which is approximately 4000-fold resistant to mitoxantrone was isolated by serial passage of the parental wild-type MCF-7 cells (MCF/WT) in stepwise increasing concentrations of drug. MCF/MX cells were also approximately 10-fold cross-resistant to doxorubicin and etoposide but were not cross-resistant to vinblastine. Intracellular accumulation of radiolabeled mitoxantrone was markedly reduced in MCF/MX cells relative to that in the drug-sensitive MCF/WT cells. This decrease in intracellular drug accumulation into MCF/MX cells was associated with enhanced drug efflux, which was reversed when cells were incubated in the presence of sodium azide and 2, 4-dinitrophenol, suggesting an energy-dependent process. Incubation of MCF/MX cells with verapamil did not affect either the accumulation of mitoxantrone or the level of resistance in these cells. Furthermore, RNase protection and Western blot analyses failed to detect the expression of the mdr1 RNA or P-glycoprotein, a drug efflux pump known to be associated with the development of multidrug resistance in vitro. However, a polyclonal antibody directed against a synthetic peptide corresponding to the putative ATP binding domain of P-glycoprotein reacted with two (M(r) 42,000 and 85,000) membrane proteins from MCF/MX cells which were not found in MCF/WT. Functional assays and Western blot analysis for topoisomerase II revealed no differences in topoisomerase II activity or protein levels in MCF/MX cells. Thus, resistance in this cell line is apparently associated with enhanced drug efflux involving a pathway distinct from the mdr1-encoded multidrug transporter P-glycoprotein.
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PMID:Reduced intracellular drug accumulation in the absence of P-glycoprotein (mdr1) overexpression in mitoxantrone-resistant human MCF-7 breast cancer cells. 135 31

The biochemical bases of the multidrug-resistant (MDR) phenotype were investigated in drug-resistant sublines derived from LoVo human colon carcinoma cell lines by doxorubicin (DOX) and teniposide (VM26) selection. In addition to P-glycoprotein-mediated drug extrusion through the plasma-membrane, LoVo MDR cells display a further drug-resistance mechanism. That is, to achieve equitoxic effects, LoVo MDR sublines require much higher intracellular drug concentrations than those required by LoVo drug-sensitive parent cell line. Involvement of mdr1, topoisomerase II and glutathione-S-transferase-pi (GST-pi) drug-resistance systems in intracellular drug resistance was investigated. Pharmacologic and biochemical data indicated that intracellular drug resistance in LoVo MDR sublines is uniquely consequent to the drug-transporting property of intracytoplasmic membrane-bound P-glycoprotein molecules which compartment drugs in vacuole-like structures.
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PMID:P-glycoprotein but not topoisomerase II and glutathione-S-transferase-pi accounts for enhanced intracellular drug-resistance in LoVo MDR human cell lines. 135 86

In an attempt to characterize and overcome tumor cell resistance to amsacrine (m-AMSA), we studied the structure-activity relationships for amsacrine and seven of its analogs. Using the human leukemic cell line, CCRF-CEM, and its derivatives that express either P-glycoprotein (Pgp)-associated multidrug resistance (MDR) (CEM/VLB100) or altered topoisomerase II-associated MDR (at-MDR) (CEM/VM-1), we assessed antitumor effects of these drugs in a 48-hr growth inhibition assay. We also measured drug-topoisomerase II interactions in an intact cell assay that permits quantitation of drug-stabilized DNA-topoisomerase II complexes. We found that among the tested compounds, amsacrine has an intermediate effect on cell growth in all three cell lines. The CEM/VM-1 cells were 8.6-fold cross-resistant to m-AMSA, and the cross-resistance to the analogs was from 3.0- to 10.5-fold. In the CEM/VLB100 cells, the resistance pattern was different: several analogs, including amsacrine, showed little or no cross-resistance (0.5- to 2.8-fold), whereas for those compounds with substituents at position 3 on the acridine ring, resistance was relatively higher (9.9- or 16.2-fold). Substituents at this position substantially decrease the lipophilicity of the two compounds examined, probably because they both contain amino groups that would be charged at physiologic pH. Compound 12489, having a 1'-NHSO2C6H4NH2 substituent, was very potent in the three cell lines, showing only a slightly higher IC50 value in the CEM/VM-1 line and a lower IC50 value in the CEM/VLB100 and in the CEM cells.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Structure-activity studies of amsacrine analogs in drug resistant human leukemia cell lines expressing either altered DNA topoisomerase II or P-glycoprotein. 136 24

Mitoxantrone (MIT) resistance has been studied in a colony selected from the CHO AA8 parental line in one step under a low degree of selective pressure (9 nM). The cells of the clonal isolate AA8/MIT C1(0) were sensitive to 9 nM MIT at low cell density but able to grow at high density. Parental AA8 cells were not able to grow under the latter condition. Decreased MIT accumulation (-20%) was observed at this step (step 0) in the absence of overexpression of mdr RNA coding for the drug efflux pump P-glycoprotein. Furthermore, AA8/MIT C1(0) did not exhibit cross resistance to vincristine, Adriamycin and etoposide at low cell density. During subsequent controlled growth for 2 months at high cell density in the presence of 9 nM drug, an additional selection occurred leading to a 4-fold MIT-resistant subline AA8/MIT C1(+). This subline was characterized at this step (step I) and after an additional 4 months of culture in the presence of 9 nM MIT (step II). Analysis of mdr gene expression and gene copy number showed an increase in mdr RNA and a pattern of mdr gene amplification which changed between step I and II. AA8/MIT C1(+)II exhibited a classical multidrug resistance phenotype with decreased accumulation of [14C]MIT and cross-resistance to vincristine, Adriamycin and etoposide. The ability to form the cleavable complex in the presence of etoposide in DNA topoisomerase II-containing nuclear extracts was identical in AA8/MIT C1(+)II and AA8 cell lines. These results demonstrate a new sequence of events in MIT resistance: low level of drug resistance at high cell density followed by mdr gene amplification.
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PMID:High cell density-dependent resistance and P-glycoprotein-mediated multidrug resistance in mitoxantrone-selected Chinese hamster cells. 137 19

Taxotere (RP 56976, NSC 628503), an analog of taxol, is an inhibitor of depolymerisation of microtubules and is currently in Phase I clinical trials. Comparisons of the cytotoxicities of Taxotere and taxol have been studied on several murine (P388, SVras) and human cell lines (Calc18, HCT116, T24, N417, KB). Taxotere was found more potent than taxol (1.3-12 fold), a result which could be explained by its higher affinity than taxol for microtubules. In agreement with its postulated mechanism of action, Taxotere is more cytotoxic on proliferating than on non proliferating N417 cells and does not inhibit cellular DNA, RNA and protein synthesis. Taxotere gives partial cross resistance on P-glycoprotein resistant P388/DOX cell line, in contrast to taxol which gives a complete cross resistance. On the other hand, no cross resistances were observed on Calc18/AM and P388/CPT5 cell lines, bearing modified activities of topoisomerase II and topoisomerase I, respectively. These results underline the higher cytotoxic activity of Taxotere compared to taxol, and the lack of cross resistance of that class of agent with the topoisomerase I and II-related multidrug resistance phenotypes.
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PMID:Effects of Taxotere on murine and human tumor cell lines. 138 86

Flow cytometry and laser scanning confocal imaging have been used to analyze the uptake of the anticancer topoisomerase II poison mitoxantrone by intact mammalian cells and the results correlated with the induction of DNA damage. Unlike Adriamycin, mitoxantrone displays only minimal levels of red fluorescence when excited at 514 wavelength. However, using these excitation and emission conditions, flow cytometry could detect low levels of fluorescence in human transformed fibroblasts exposed to high concentrations (5-20 microM) of mitoxantrone for 1 h. Over this dose range whole cell fluorescence was a function of cell size and increased with drug concentration while drug-induced DNA-protein cross-linking showed saturation. Confocal microscopy revealed the time- and dose-dependent appearance of fluorescence, interpreted here as reflecting the disposition of drug molecules, preferentially within the cytoplasm, nuclear membrane, and nucleoli. This pattern contrasted with the intense intranuclear fluorescence observed in Adriamycin-treated human cells. Loss of the nuclear membrane during mitosis resulted in an apparent increase in chromatin-associated fluorescence. Photon counting procedures revealed a predominantly cytoplasmic, possibly lysosomal, location for fluorescence from human cells exposed for 1 h to a low but cytotoxic concentration (0.1 microM, yielding approximately 90% cell kill) of mitoxantrone. At this low concentration, human cells displayed minimal levels of DNA strand cleavage or DNA-protein cross-linking. Murine cells, displaying mitoxantrone resistance as part of the P-glycoprotein-mediated multidrug resistance phenotype, showed specific extinction of mitoxantrone-associated fluorescence from inside nuclei but not from within extranuclear compartments. The study demonstrates the feasibility of high resolution studies on the intracellular distribution of mitoxantrone in intact living cells. We suggest a mechanism by which cytoplasmic sequestration of mitoxantrone may be important in determining the response of normal and multidrug-resistant cells as they attempt to progress through mitosis.
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PMID:Subcellular distribution of the anticancer drug mitoxantrone in human and drug-resistant murine cells analyzed by flow cytometry and confocal microscopy and its relationship to the induction of DNA damage. 161 77

The modulating effect on drug resistance of amiodarone (AM) and its metabolite desethylamiodarone (DEA) was studied in a P-glycoprotein-positive human colon carcinoma cell line COLO 320, and a human small-cell lung carcinoma cell line GLC4 and its adriamycin (Adr)-resistant subline GLC4-Adr (both P-glycoprotein-negative). AM, DEA and verapamil induced an increase in cytotoxicity of Adr, vincristine and etoposide (VP16) in COLO 320 cells, while in the GLC4 and GLC4-Adr cell line no effect was seen. In the COLO 320 cell line, AM caused more intracellular, and especially intranuclear, fluorescence of Adr and more Adr-induced DNA strand breaks as compared to Adr alone. Moreover, an increase in VP16-induced topoisomerase II-DNA complexes was observed when AM was added. Competition between AM and Adr for the same efflux pump was suggested in efflux studies. The colony-forming unit granulocyte macrophage (CFU-GM) assay showed no increase in cytotoxicity of Adr when AM was added. Fourteen patients with Adr-resistant tumors were treated with Adr and AM. In these patients, peak serum levels of AM plus DEA of 10 microM were reached. Patient serum (20%) obtained after the first i.v. AM infusion induced in vitro significantly more cell kill of Adr in COLO 320 cells. Apart from a transient first-degree AV block in one patient, no cardiac toxicity was observed with the combination of Adr and AM. Bone-marrow toxicity was the same as expected from Adr alone in these patients. One of the 13 evaluable patients obtained a partial remission.
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PMID:In vitro and in vivo modulation of multi-drug resistance with amiodarone. 164 80

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

Cells exhibiting decreased topoisomerase II (Topo II) activity are resistant to several drugs that require Topo II as an intermediate. These drugs are cytotoxic due to the formation of a cleavable complex between the drug, Topo II and DNA. Fostriecin belongs to a new class of drugs that inhibit Topo II without inducing the formation of this cleavable complex. We tested fostriecin in three human small-cell lung carcinoma cell lines. GLC4 is the parent line. GLC4/ADR is the P-glycoprotein-negative multidrug-resistant subline, which is resistant to several Topo II inhibitors due to its decreased Topo II activity. GLC4/cDDP is the cisplatin-resistant subline, which displays increased Topo II activity. Topo II activity proved to be 100% in GLC4, 35% in GLC4/ADR and 130% in GLC4/cDDP. The fostriecin concentration causing inhibition of the growth of 50% of the cells (IC50) in the microculture tetrazolium assay following continuous incubation was 11.2, 4.1 and 14.9 microM, respectively. After 1-h incubations, the IC50 was 117.8, 101.3 and 219.8 microM, respectively. Our results indicate a relationship between Topo II activity and fostriecin sensitivity in these closely related cell lines. At least in vitro, fostriecin displayed the capacity to kill cells showing resistance to drugs due to decreased Topo II activity. There was no relationship between this capacity and an increase in the activity of the reduced-folate carrier system, the proposed mechanism for cellular entry of fostriecin, since we found no correlation between the cytotoxicity of fostriecin and that of methotrexate.
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PMID:Lack of cross-resistance to fostriecin in a human small-cell lung carcinoma cell line showing topoisomerase II-related drug resistance. 165 25

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