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)

HT1080/DR4 (DR4) is a doxorubicin-resistant human fibrosarcoma line that exhibits 150-fold cross-resistance to etoposide but does not overexpress P-glycoprotein (one mechanism of multiple drug resistance). We examined another possible mechanism that could explain resistance to both doxorubicin and etoposide: a quantitative or qualitative alteration in topoisomerase II, the putative nuclear target of these agents. The amount of immunoreactive topoisomerase II present in whole-cell lysates and nuclear extracts was three- to 10-fold lower in DR4 than in HT1080 cells. However, the topoisomerase II in nuclear extracts from both lines was sensitive to the effects of amsacrine (AMSA) and etoposide. Following treatment with AMSA, etoposide, and 5-iminodaunorubicin, topoisomerase II-mediated DNA cleavage in DR4 cells and nuclei was reduced compared with cleavage in HT1080 parent cells and nuclei. The difference between the HT1080 and DR4 lines in AMSA- and 5-iminodaunorubicin-induced cleavage was similar in cells and nuclei and could be due to the lower amount of DR4 topoisomerase II. By contrast, the difference between the HT1080 and DR4 lines in etoposide-induced DNA cleavage was much greater in cells than in nuclei. This finding suggested that cytosolic factors, removed from isolated nuclei, could influence the susceptibility of intact cells to the cytotoxic and DNA-cleaving actions of etoposide. The specific activities of several antioxidant enzymes, components of the cell's defense against free-radical damage that may be produced by doxorubicin or etoposide, were significantly different in HT1080 and DR4 cytosolic extracts. These differences may constitute an additional mechanism of resistance. Regardless, the magnitude of the resistance of DR4 to doxorubicin and etoposide cannot be explained solely on the basis of a topoisomerase II-related mechanism.
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PMID:HT1080/DR4: a P-glycoprotein-negative human fibrosarcoma cell line exhibiting resistance to topoisomerase II-reactive drugs despite the presence of a drug-sensitive topoisomerase II. 197 36

We established an etoposide (VP-16)-resistant human small-cell lung cancer cell line (H69/VP) by stepwise exposure to VP-16. The resistance of H69/VP to VP-16 was 9.4-fold that of the parent cell line (H69/P). H69/VP showed cross-resistance to Adriamycin (ADM), (4S)-4,11-diethyl-4-hydroxy-9-[(4-piperidinopiperidino) carbonyloxy]-1H-pyrano[3',4':6,7]indolizino [1,2-b]quinoline-3,14(4H,12H)-dionehydrochloride trihydrate (CPT-11), teniposide (VM-26), vindesine (VDS) and vincristine (VCR). The amount of DNA topoisomerase II (topo.II) was nearly the same in H69/P and H69/VP cells. The catalytic activity of topo.II in H69/VP cells was lower than that in the H69/P line. Accumulation of [3H]-VP-16 in H69/VP was 6.1-7.5 times lower than that in H69/P. According to Northern blot analysis, the mdr-1 mRNA level in H69/VP was markedly higher than that in H69/P. These findings suggest that H69/VP has a typical multidrug resistance (MDR) phenotype and that alteration of the drug accumulation mediated by P-glycoprotein may play an important role in resistance to VP-16. Reduced topo.II activity may also be associated with VP-16 resistance.
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PMID:Characterization of an etoposide-resistant human small-cell lung cancer cell line. 197 50

In an attempt to understand the underlying cellular/biochemical factors of sensitivity/resistance in human small-cell lung cancer (SCLC), 2 SCLC tumor lines were compared with respect to tumor responsiveness to drug treatment, cell sensitivity, cellular doxorubicin accumulation, and DNA topoisomerase-II-mediated DNA cleavage. The tumor lines growing in nude mice with similar growth characteristics (doubling time around 10 days) were selected since one (POCI tumor) was found to be hypersensitive and the other (POSG tumor) resistant to doxorubicin treatment. The pattern of anti-tumor drug response of the doxorubicin-resistant tumor was atypical (i.e., non-adherent to the well-characterized multi-drug-resistant phenotype), since it responded to vincristine. The markedly different in vivo tumor response reflected the intrinsic cellular sensitivity to doxorubicin. No correlation was found between cellular drug accumulation and doxorubicin sensitivity following in vitro exposure to the drug. In agreement with this observation, the expression of mdr-I gene was undetectable in these tumors. Thus, in the POSG tumor, resistance to doxorubicin occurred without expression of the P-glycoprotein and reduction of cellular drug accumulation. In contrast, the extent of DNA cleavage produced by doxorubicin was markedly higher in the doxorubicin-hypersensitive than in the doxorubicin-resistant tumor. These results, taken together with previous observations in SCLC cell lines, support the important role of DNA topoisomerase-mediated effects in the sensitivity of SCLC to doxorubicin.
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PMID:Relationships among tumor responsiveness, cell sensitivity, doxorubicin cellular pharmacokinetics and drug-induced DNA alterations in two human small-cell lung cancer xenografts. 197

Strategies to circumvent different forms of multidrug resistance (MDR) in tumor cells will be discussed. The form of MDR associated with overexpression of P-glycoprotein. Pgp-MDR, is well-understood, and its features are briefly described. Many clinically useful lipophilic organic bases have been shown to interfere with drug efflux mediated by Pgp, consequently circumventing or overcoming this form of MDR. Based on these empiric observations, screening and molecular modeling efforts are being employed to develop new modulators of Pgp-MDR. However, because inhibition of normal tissue Pgp can cause unacceptable toxicities, new strategies to circumvent Pgp-MDR in tumors must be sought. Possibilities range from pharmacokinetic modeling to the development of tissue-specific inhibitory antibodies or antisense oligonucleotides. Tumor cells expressing altered DNA topoisomerase II express a more restricted form of MDR, termed at-MDR, that will be discussed briefly and compared with Pgp-MDR. Modulators of Pgp-MDR are without effect in cells expressing only at-MDR. However, some analogs of anthracyclines appear to act via a topo II-independent pathway and can circumvent this form of resistance. Also, alterations in topoisomerase II may have consequences for other cellular functions, as at-MDR cells appear to have defects in DNA repair pathways, suggesting other areas for therapeutic exploitation.
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PMID:Strategies to circumvent multidrug resistance due to P-glycoprotein or to altered DNA topoisomerase II. 198 Apr 25

Multidrug resistance (MDR) associated with overexpression of P-glycoprotein (Pgp) is a well-described experimental phenomenon that appears to have clinical correlates. However, recent descriptions of non-P-glycoprotein forms of MDR have complicated efforts to detect and circumvent MDR in the tumors of patients. One major form of natural product MDR appears to be due to alterations in the amount of activity of DNA topoisomerase II. Compared to Pgp-MDR cells, cells expressing this form of MDR (at-MDR) do not overexpress the mdr1 gene or its product, Pgp, are unaltered in drug accumulation and retention, are unaffected by such 'modulators' of Pgp-MDR as verapamil, and express this phenotype recessively. Recently, other MDR cell lines have been described with some characteristics of Pgp-MDR (decreased drug accumulation and retention, increased drug cytotoxicity by modulators of MDR), but not others (no expression of the mdr1 gene or Pgp). Whether any non-Pgp forms of MDR occur in patients' tumors remains to be determined.
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PMID:Mechanisms of multidrug resistance in human tumor cells. The roles of P-glycoprotein, DNA topoisomerase II, and other factors. 198 39

NC-190, a benzophenazine derivative (N-beta-dimethylaminoethyl 9-carboxy-5-hydroxy-10-methoxy-benzo[a]phenazine-6-carboxamide), was effective against multidrug-resistant human and mouse tumor cells in vitro and in vivo. When vincristine (VCR)-resistant P388 leukemia-bearing mice were treated with an optimal dose of NC-190, four of six mice were cured, whereas treatment of mice with VCR resulted in only a marginal increase in life span. The compound also showed chemotherapeutic effect against Adriamycin-resistant P388 leukemia-bearing mice and was effective against various multidrug-resistant human and murine tumor cells in vitro. Its cytotoxicity to multidrug-resistant K562 cells was not enhanced by the addition of verapamil. The accumulation of NC-190 in multidrug-resistant K562 cells was slightly lower than that observed in sensitive K562 cells; the compound did not efficiently inhibit the binding of VCR to the plasma membrane of resistant cells, indicating that NC-190 has little affinity for P-glycoprotein. NC-190 inhibited the activity of DNA topoisomerase II. These observations suggest that NC-190 (1) is not transported out of resistant cells by P-glycoprotein and (2) inhibits DNA topoisomerase II activity in the cells, resulting in its likely effectiveness against various multidrug-resistant tumor cells.
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PMID:A benzophenazine derivative, N-beta-dimethylaminoethyl 9-carboxy-5-hydroxy-10-methoxy-benzo[a]phenazine-6-carboxamide, as a new antitumor agent against multidrug-resistant and sensitive tumors. 216 Dec 96

Recent progress in the understanding of drug resistance has led to the discovery of new targets for chemotherapy. By attacking the molecules that make cancer cells insensitive to chemotherapy, it is hoped that drug-resistant disease will respond to treatment. This review describes some of the latest advances in understanding of the biochemistry of drug resistance. Following a general introduction four areas of topical interest are discussed: (1) multidrug resistance and P-glycoprotein, (2) glutathione and its related enzymes, (3) topoisomerase II and (4) DNA repair.
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PMID:Biochemical basis of resistance to chemotherapy. 228 41

Our human T-cell leukemia line, CEM/VM-1, selected for resistance to VM-26 (teniposide), is cross-resistant to several drugs that interact with topoisomerase II, including VP-16 (etoposide), 4'-(9-acridinylamino)methanesulphon-m-anisidide, daunorubicin, and mitoxantrone. However, in contrast to cell lines exhibiting multidrug resistance (MDR) associated with overexpression of P-glycoprotein, this line is not cross-resistant to the Vinca alkaloids, is not impaired in drug accumulation, and does not overexpress the mdrl gene (Cancer Res., 47: 1297, 5455, 1987). More recently we found that nuclear extracts of these cells exhibit decreased topoisomerase II catalytic and cleavage activity, compared to the drug-sensitive line (Biochemistry, 1988). These results suggest that an alteration in topoisomerase II or a modulator of this enzyme may be responsible for this altered topoisomerase II-form of multidrug resistance (at-MDR). In the present work, we studied the somatic cell genetics of at-MDR. We produced hybrid cell lines by polyethylene glycol-mediated fusion of the CEM/VM-1 line with a hypoxanthine-guanine phosphoribosyl transferase-deficient, ouabain-resistant CEM line (CEM.AG1.OU1.5) that exhibits VM-26 sensitivity. Ten of the hybrid lines that grew in selective medium were randomly chosen for expansion and four were analyzed for both DNA content by flow cytometry and VM-26 sensitivity in a 72-h growth inhibition assay. The hybrid lines all contained approximately 2x DNA compared to unfused controls, indicating that the fusions were successful. The IC50 for VM-26 in 3 of the 4 lines was the same as that of the sensitive controls, ranging from 4.7 to 7.4 x 10(-8) M, and another was 76 x 10(-8) M. These data indicate that drug sensitivity was reconstituted by the hybridization procedure. By comparison, the VM-26 IC50 values in the CEM/VM-1 cells and CEM/VM-1 x CEM/VM-1 control "fusions" were 360 and 750 x 10(-8) M, respectively. To determine whether a topoisomerase II-mediated function was reconstituted in the hybrids, we measured drug-stimulated DNA cleavage ("cleavable complex formation"). Using 32P-labeled pBR322 DNA as substrate with nuclear extracts from drug sensitive cells, 100 microM VM-26 maximally stimulated DNA cleavage by approximately 11-fold compared to no-drug controls.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Genetic characterization of the multidrug-resistant phenotype of VM-26-resistant human leukemic cells. 253 2

Cells selected for resistance to doxorubicin (DOX) express the multidrug resistance (MDR) phenotype, and resistance has been suggested to be due primarily to enhanced cellular efflux of drug. A progressively DOX-resistant (10- and 40-fold) L1210 mouse leukemia model system, which does not exhibit enhanced DOX efflux as a primary mechanism of resistance, was found to display the MDR phenotype, based on overexpression of P-glycoprotein in western blots and cross-resistance to vinca alkaloids. Cross-resistance to another topoisomerase II inhibitor, etoposide (VP-16), was similar to that of DOX (10- and 40-fold), whereas resistance to N-[4-(9-acridinylamino)-3-methoxyphenyl]methanesulfonamide (m-AMSA) was 5-fold lower. In contrast, no cross-resistance to camptothecin, an inhibitor of topoisomerase I, was observed. Topoisomerase II decatenation activity in nuclear extracts from 10- and 40-fold DOX-resistant cells was 2- and 4-fold lower, respectively, when compared to sensitive cells. In these cells, however, marked reductions in m-AMSA- and VP-16-induced topoisomerase II mediated DNA cleavage were found to exceed decreases in the catalytic activity of the enzyme. Results from this study demonstrated that, in progressively DOX-resistant L1210 mouse leukemia cells with the MDR phenotype, a better relation existed between the degree of resistance and reduced VP-16- and m-AMSA-induced topoisomerase II mediated DNA cleavage, than between increases in P-glycoprotein and concomitant reduction in DOX accumulation.
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PMID:Progressive resistance to doxorubicin in mouse leukemia L1210 cells with multidrug resistance phenotype: reductions in drug-induced topoisomerase II-mediated DNA cleavage. 257 73

Interest in DNA-intercalating ligands as anti-cancer drugs has developed greatly since the clinical success of doxorubicin. However, despite a great deal of 'rational design' of synthetic DNA-intercalators, only a few such compounds have proved clinically useful. This review briefly surveys the history of DNA-intercalators as clinically-used anti-cancer drugs, summarizes the known structure-experimental activity relationships and modes of action, and concludes that a factor in the slow progress is that much of the work on these compounds has been carried out by chemists, who were generally more interested in ligand/DNA interactions than drug development. Future development of the class rests on a careful consideration of the biochemical reasons behind the common limitations of the present drugs. The most important are: the inherent resistance of non-cycling cells, the rapid development (even by cycling cells) of resistance by the expression of both P-glycoprotein and altered topoisomerase II, limitations on drug distribution to and transport into tumours, low extravascular pH in tumours and the cardiotoxic side-effects of quinonoid chromophores. These considerations provide a set of constraints on physicochemical properties which must be considered in future design. However, within these constraints, there are useful future avenues for the development of DNA-intercalators as anti-cancer drugs. These include: (i) the production of improved topoisomerase inhibitors (by consideration of drug/protein as well as drug/DNA interactions); (ii) the development of reductively-activated chromophores as hypoxia-selective agents; and (iii) the use of DNA-intercalators of known DNA binding orientation as 'carriers' for the delivery of other reactive functionality specifically (sequence-, regio- and site-specifically) to DNA.
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PMID:DNA-intercalating ligands as anti-cancer drugs: prospects for future design. 269 99

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