EC:5.99.1.2 - FACTA Search

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)

A series of doxorubicin-resistant variants of the human LS174T colon carcinoma cell line was generated by stepwise selection. These variants also exhibited increased resistance to vinblastine, etoposide, cis-platinum, and melphalan, suggesting that resistance was multifactorial. The parental LS174T cell line and 3 resistant variants were examined for over-expression of P-glycoprotein, changes in total cellular glutathione content, and the level of topoisomerase-II expression. Changes in all of these parameters were observed in the doxorubicin-selectants, along with a marked shift in the intracellular distribution of doxorubicin. P-glycoprotein RNA and protein levels were increased 2- to 3-fold in the resistant variants, while total glutathione levels increased 1.4- to 2.1-fold. Treatment with DL-buthionine-[S,R]-sulfoximine, an inhibitor of glutathione biosynthesis, was able to reverse resistance to cis-platinum and melphalan in these variants, but had little effect on doxorubicin resistance. Immunoblot analysis of cell extracts indicated that the level of DNA topoisomerase II (EC 5.99.1.3) in the doxorubicin-resistant LS174T cells was decreased by approximately 50% compared with the parental cell line. Doxorubicin was mainly localized to the cytoplasm in resistant cells, while in the parent line it was mostly found in the nucleus. This constellation of changes suggests that selection with doxorubicin activated several mechanisms of resistance involving drug transport, metabolism, and ability to reach nuclear target sites.
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PMID:Multifactorial resistance in LS174T human colon carcinoma cells selected with doxorubicin. 168 Aug 16

P-glycoprotein (P-gp) expression and DNA topoisomerase (Topo) II are important variables in multidrug resistant tumor cell lines. The aim of this study was to evaluate P-gp expression and Topo I and II activity in benign and malignant epithelial ovarian tumors. P-gp expression was analyzed immunohistochemically in cryostat sections of fresh tumor specimens. In the same specimens Topo I and II activity were measured by, respectively, relaxation of supercoiled plasmid pBR322 DNA and decatenation of kinetoplast DNA. P-gp expression (range, 5-100% positive staining cells) was found in 3 of 6 cystadenomas, 0 of 2 borderline tumors, 15 of 21 untreated ovarian cancers, and 8 of 13 platinum/cyclophosphamide treated ovarian cancers. Median Topo I and II activity were elevated in malignant ovarian tumors compared to benign and borderline tumors. No difference was found between median Topo I activity in untreated ovarian cancer and platinum/cyclophosphamide treated ovarian cancer. High Topo II activity (greater than or equal to 8 x 10(2) units/mg protein) was more frequent in untreated compared to platinum/cyclophosphamide treated samples. Respectively, 8- and 16-fold differences in Topo I and II activity were found in the malignant tumors. Topo II activity in malignant tumors correlated with Topo I activity (r = 0.36, P less than 0.05) and the tumor volume index (r = 0.35, P less than 0.05). However, this last weak correlation cannot explain the 16-fold differences in Topo II activity in malignant tumors. Mitotic index and P-gp expression did not correlate with Topo I or II activity. A large variability in P-gp expression and Topo I and II activity was observed in patients with ovarian cancer.
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PMID:P-glycoprotein expression and DNA topoisomerase I and II activity in benign tumors of the ovary and in malignant tumors of the ovary, before and after platinum/cyclophosphamide chemotherapy. 168 37

The mdr gene, which encodes an energy-dependent multidrug efflux pump termed P-glycoprotein, is expressed in some normal human and rodent tissues, including the adrenal gland, kidney, liver, colon, small intestine, and brain and testis capillary endothelial cells. Because of the important role played by the multidrug transporter in determining sensitivity of normal tissues and resistance of cancers to chemotherapeutic drugs, we and others have been determining the environmental factors which regulate expression of the mdr gene. In previous studies, expression of the human MDR1 gene has been shown to be regulated by heat shock, arsenite, and cadmium in a kidney carcinoma cell line, and mdr RNA is dramatically elevated in rat liver after partial hepatectomy or treatment of the animals with cytotoxic agents. We have now investigated the genetic response of the mdr gene to acute cytotoxic insults in rodent and human tissue culture cells. Following exposure to several drugs, most of which are known to be substrates for the multidrug transporter, mdr RNA levels were found to increase substantially in the rodent cells, but not the human cells. Furthermore, RNA levels for topoisomerase II, an intracellular target for these drugs, decreased in the rodent cells. These results suggest a complex pattern of regulation of mdr RNA levels, depending on animal species and cell type, and possible coordinate regulation with topoisomerase II RNA levels.
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PMID:Regulation of mdr RNA levels in response to cytotoxic drugs in rodent cells. 170 76

The cyanomorpholino derivative of doxorubicin (MRA-CN) is a DNA intercalator and alkylator that is a highly potent cytotoxin, non-cross-resistant in multidrug-resistant cells, and noncardiotoxic in comparison with doxorubicin. To further examine mechanisms of action and resistance to MRA-CN, a cell line resistant to MRA-CN, ES-2R, was established by growing a human ovarian carcinoma cell line, ES-2, in increasing concentrations of the drug. The resistant subline was 4-fold resistant to MRA-CN and cross-resistant to other DNA cross-linking agents, cisplatin (7-fold) and carmustine (3-fold), as well as to the DNA strand-breaking agents etoposide (6-fold), doxorubicin (2-fold), bleomycin (5-fold), and ionizing radiation (2-fold). In contrast, ES-2R cells were not cross-resistant to vinblastine. Several months of additional growth of ES-2R cells in MRA-CN did not yield higher, stable levels of drug resistance. A low level of P-glycoprotein was detectable in the ES-2R cells. However, the extent of intracellular accumulation of [3H]MRA-CN by this resistant cell line was identical to that of the sensitive line. The number of DNA cross-links formed by cisplatin in ES-2R was only 50% of that of the ES-2 cells and was associated with a 50% increase in the rate of repair of these cross-links in the resistant cells. Ionizing radiation induced similar amounts of single- and double-strand breaks in the ES-2 line as well as in the ES-2R cells. There was no apparent difference between the two cell lines in the rate and extent of repair of these DNA breaks. Thus, enhanced DNA repair cannot explain the phenomenon of cross-resistance to radiation. Comparisons of glutathione (GSH) content and the enzymes involved in GSH homeostasis showed significant differences. Resistant cells contained 1.5-fold more GSH, a 2.2-fold increase in gamma-glutamyltranspeptidase activity, and a 2.4-fold increase in GSH reductase compared with ES-2 cells (all P less than 0.05). Total glutathione-S-transferase (GST) activity was 2.6-fold higher (P less than 0.01) in the ES-2R line. The pi-class GST subunit by Western blotting and GST activity toward ethacrynic acid were increased 2-fold in the resistant cells. Depletion of GSH levels in ES-2R cells by buthionine sulfoximine restored the sensitivity of ES-2R to MRA-CN. These findings implicate a role for GSH metabolism in the resistance phenotype of ES-2R cells. We have previously reported that these cells have an increased generation time and decreased topoisomerase II content. Thus, the ES-2R cell line exhibits a complex phenotype of broad cross-resistance, which is likely to involve multiple mechanisms, and includes enhanced DNA repair and increased GSH content and GST activity.
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PMID:Multifactorial mechanisms associated with broad cross-resistance of ovarian carcinoma cells selected by cyanomorpholino doxorubicin. 171 40

Stable acquired resistance to etoposide (VP-16) or teniposide (VM-26) in HCT116 human colon carcinoma cells and A549 human lung adenocarcinoma cells, was previously obtained by weekly 1-h exposures to either drug (B. H. Long, Natl. Cancer Inst. Monogr., 4: 123-127, 1987). The purpose of this study was to identify possible mechanisms of resistance present in these cells by using human mdr1 and topoisomerase II DNA probes, antibodies to these gene products, and P4 phage unknotting assay for topoisomerase II activities. HCT116(VP)35 cells were 9-, 7-, and 6-fold resistant to VP-16, VM-26, and Adriamycin, respectively, and showed no cross-resistance to colchicine and actinomycin D. These cells had no differences in mdr1 gene, mdr1 mRNA, or P-glycoprotein levels but displayed decreased levels of topoisomerase II mRNA and enzyme activity without any alteration of drug sensitivity displayed by the enzyme. HCT116(VM)34 cells were 5-, 7-, and 21-fold resistant to VP-16, VM-26, and Adriamycin; were cross-resistant to colchicine (7-fold) and actinomycin D (18-fold); and possessed a 9-fold increase in mdr1 mRNA and increased P-glycoprotein without evidence of mdr1 gene amplification. No alterations in topoisomerase II gene or mRNA levels, enzyme activity, or drug sensitivity were observed. A549(VP)28 and A549(VM)28 cells were 8-fold resistant to VP-16 and VM-26 and 3-fold resistant to Adriamycin. Both lines were not cross-resistant to colchicine or actinomycin D but were hypersensitive to cis-platinum. No alterations in mdr1 gene, mdr1 mRNA, or P-glycoprotein levels, but lower topoisomerase II mRNA levels and decreased enzyme activities, were observed. Of the four acquired resistant cell lines, resistance is likely related to elevated mdr1 expression in one line and to decreased topoisomerase II expression in the other three lines.
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PMID:Mechanisms of resistance to etoposide and teniposide in acquired resistant human colon and lung carcinoma cell lines. 171 44

In a previous study we suggested that, in addition to the reduced Adriamycin accumulation, part of the resistance in an Adriamycin-resistant human small cell lung carcinoma cell line (GLC4/ADR) could be explained by supposing a changed Adriamycin-DNA-topoisomerase II (Topo II) interaction. The present study showed that the Mr 170,000 P-glycoprotein was not overexpressed in GLC4/ADR and that verapamil did not reverse the Adriamycin resistance. GLC4/ADR expressed cross-resistance to teniposide, etoposide, 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA), and mitoxantrone. Further investigations of the drug-Topo II interaction revealed that the decatenation activity of Topo II was two- to threefold reduced in both cellular and nuclear extracts from GLC4/ADR. Topo I activities appeared similar in extracts from GLC4/ADR and the parental sensitive cell line (GLC4). The slight increase in doubling time from 15 to 18 h, while the cell cycle distribution remained unchanged, could not account for the reduced Topo II activity in GLC4/ADR. Etoposide and m-AMSA-induced DNA cleavage was 5-fold reduced in cellular extracts from GLC4/ADR. Inhibition of the decatenation activity of Topo II in the presence of VP-16 and m-AMSA was increased twofold in the cellular extracts from GLC4/ADR. Therefore, these results suggest that resistance of GLC4/ADR to Adriamycin was in part due to the reduced drug-induced formation of the cleavage complex.
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PMID:Reduced DNA topoisomerase II activity and drug-induced DNA cleavage activity in an adriamycin-resistant human small cell lung carcinoma cell line. 196 22

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

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

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

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