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)

Human epidermoid KB cell lines resistant to high levels of adriamycin, C-A90, C-A120, C-A500, and C-A1000, were isolated in selection medium containing increasing concentrations of adriamycin, 1 microgram/ml of cepharanthine, a multidrug-resistance (MDR) reversing agent, and 100 nM of mezerein, a protein kinase C activating agent. One of the adriamycin-resistant KB cell lines, C-A500, was cross-resistant to drugs that typify the classical multidrug resistance phenotype, such as vincristine, actinomycin D, VP-16, and colchicine. The accumulation of adriamycin and vincristine was decreased in C-A500 cells and the efflux of adriamycin from C-A500 was enhanced compared with parental KB-3-1 cells. These adriamycin-resistant KB cells did not contain detectable levels of P-glycoprotein or overexpress MDR1. Multidrug-resistance-associated protein (MRP) and MRP mRNA were expressed in the adriamycin-resistant KB cells, C-A120, C-A500, and C-A1000, but not in parental KB-3-1 and revertant C-AR cells. The MRP gene was amplified in all the MDR cells that overexpressed MRP mRNA. DNA topoisomerase II levels were markedly decreased in C-A500 and C-A1000 cells but only slightly decreased in C-A120 cells. These results indicate that MRP overexpressed in the resistant cells may be responsible for the reduced accumulation of adriamycin and vincristine and that both the increased expression of MRP and decreased levels of topoisomerase II underlie the drug resistance in C-A120, C-A500, and C-A1000 cell lines.
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PMID:Non-P-glycoprotein-mediated multidrug-resistant human KB cells selected in medium containing adriamycin, cepharanthine, and mezerein. 782 64

Cross-resistance to chemotherapeutic drugs is a significant problem in the treatment of patients with cancer. The discovery that this phenomenon is associated with the overexpression of a membrane glycoprotein, P-glycoprotein, which acts as a drug efflux pump, has provided a new target for drug development. To develop a model for identifying new compounds which can block the function of P-glycoprotein, we infected P388 mouse leukemic cells with a retrovirus containing a cloned human MDR1 complementary DNA. The new cell line, P388/VMDRC.04, incorporated and overexpressed the human gene as evidenced by Southern blots, increased mRNA and protein synthesis, and recognition by the MRK16 monoclonal antibody. P388/VMDRC.04 was cross-resistant to colchicine, vincristine, and doxorubicin, and the degree of resistance correlated with a reduction in cellular drug accumulation. Unlike many cell lines selected for resistance by growth in increasing concentrations of drug for prolonged periods of time, these cells did not show alternative mechanisms of resistance such as increased synthesis of glutathione or alterations in topoisomerase II. In addition, the sensitivity of P388/VMDRC.04 cells was completely restored by cyclosporin A and trans-flupenthixol. P388/VMDRC.04 cells were subcloned and 10 clones were picked for in vivo evaluation. One subclone grew similarly to parental cells in female BALB/c x DBA/2 F1 mice and showed no responsiveness to therapeutic doses of vincristine or etoposide. The combination of vincristine with cyclosporin A significantly increased the survival of mice inoculated with P388/VMDRC.04 cells. The availability of a cell line that displays the MDR phenotype, overexpresses human P-glycoprotein, but does not contain alterations in at least two well-defined alternative mechanisms of resistance, and that can be grown in simple animal models should facilitate the development of new agents active against this form of chemotherapeutic drug resistance.
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PMID:Characteristics of P388/VMDRC.04, a simple, sensitive model for studying P-glycoprotein antagonists. 790 86

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

New adriamycin (ADR) resistant human leukemic cell lines (KY-ADR1 and KY-ADR2) have been established. KY-ADR1 was selected from a cytosine arabinoside (Ara C) resistant cell line by gradually increasing the concentration of ADR and KY-ADR2 from the parental cell line, KY-821, by the same method. The IC50s of both cell lines were 4.3 x 10(-5) and 3.6 x 10(-5) M ADR, respectively. Both lines revealed a similar cross resistance to various anticancer drugs, but KY-ADR1 was resistant to Ara C, whereas KY-ADR2 was sensitive. MDR1 gene was over-expressed and P-glycoprotein was expressed on the cytoplasmic membrane in both lines. Neither verapamil nor cyclosporin A could completely reverse ADR resistance. In addition, no significant changes in topoisomerase II and glutathione-s-transferase levels were detected. These findings indicate that ADR resistance in both cell lines is mainly mediated by P-glycoprotein and some other mechanism may be present. Interestingly, growth of both cell lines was stimulated by natural IL-1 and not affected by TNF alpha and IFN gamma, whereas growth of parental KY-821 was inhibited by these factors. These cell lines will provide new biological aspects on drug resistant leukemic cells.
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PMID:Characterization of newly established adriamycin resistant human leukemic cell lines (KY-ADR1 and KY-ADR2). 793 46

The topoisomerase II inhibitor, VP-16 (etoposide), is an important component in many chemotherapeutic regimens. To characterize resistance to this drug, the human melanoma cell line, FEM-X, was selected in multiple steps with VP-16. To prevent the development of typical multidrug resistance, an inhibitor of P-glycoprotein, the tiapamil analog, RO-11-2933, was added to the selections. The resultant clone FVP3 is 56-fold resistant to VP-16 and cross-resistant to doxorubicin (Adriamycin) (9-fold) and VM-26 (27-fold). These cells are also two- to four-fold resistant to m-AMSA, daunorubicin, and mitoxantrone. FVP3 is not resistant to the P-glycoprotein substrates vinblastine, does not express the MDR1 gene at detectable levels, and does not show reduced 3H-VP-16 accumulation. Unlike other cell lines that exhibit resistance to inhibitors of topoisomerase II, FVP3 has the same level of topoisomerase II expression and activity as FEM-X. Using live cells treated with VP-16, band depletion assays and KCI/SDS precipitation assays show that topoisomerase II from FVP3 is much less susceptible to drug-induced cleavable complex formation than is that from FEM-X. This difference in sensitivity to VP-16 is also detected using lysates from disrupted cells, but not with isolated nuclei devoid of cytoplasmic and membrane components. In addition, the topoisomerase II present in nuclear extracts from FVP3 is not resistant to the effects of VP-16 as measured by: (1) inhibition of strand passing activity during decatenation of kinetoplast DNA, (2) drug-induced linearization of plasmid DNA, and (3) immunodepletion by VP-16. These results suggest that some component of the cytoplasm or cellular membranes, or a factor depleted from nuclei during their isolation, is responsible for the resistance to VP-16 in FVP3.
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PMID:Characterization of an unusual mutant of human melanoma cells resistant to anticancer drugs that inhibit topoisomerase II. 809 46

Hoechst dye 33342 (Ho33342), like many other DNA minor groove binding ligands and its parent compound Hoechst dye 33258 (Ho33258), nonspecifically inhibits the catalytic activities of many DNA enzymes. However, both Ho33258 and Ho33342 also specifically interrupt the breakage/reunion reaction of mammalian DNA topoisomerase I by trapping reversible topoisomerase I cleavable complexes. The enhanced membrane permeability of Ho33342 over its parent compound Ho33258 has allowed studies of the cellular action of Ho33342. Our results suggest that Ho33342 also traps topoisomerase I but not topoisomerase II into reversible cleavable complexes in human KB cells. Although Ho33342 shares a similar mechanism of action with camptothecin, a prototypic topoisomerase I poison, in trapping topoisomerase I cleavable complexes, Ho33342 differs from camptothecin in its effect on drug-resistant cells. Different from camptothecin, Ho33342 was shown to be about 200-fold less cytotoxic in MDR1-overexpressing human KB V1 cells relative to parental human KB 3-1 cells. Ho33342 is only 5-fold less cytotoxic for camptothecin-resistant CPT-K5 cells, which expresses a highly camptothecin-resistant from of topoisomerase I, than for the wild type human lymphoblast RPMI 8402 cells. Our studies suggest a potential use of Hoechst 33342 as a new topoisomerase I poison in antitumor chemotherapy.
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PMID:A new mammalian DNA topoisomerase I poison Hoechst 33342: cytotoxicity and drug resistance in human cell cultures. 838 8

We investigated four mechanisms of intrinsic chemoresistance in a series of 67 human brain tumours including 31 gliomas (one grade I ganglioglioma, nine grade II and 10 grade III astrocytomas, 11 glioblastomas), 13 cerebral metastases, one medulloblastoma, one malignant teratoma, three ependymomas and 18 meningiomas. We studied four genes by northern blotting: multidrug-resistance (MDR 1), glutathione-s transferase (GST pi), dihydrofolate reductase (DHFR), and topoisomerase II (Topo II). The Topo II gene was absent in the normal adult brain (100%) and in 64% of the tumour samples tested. A second gene, GST pi, was found to be overexpressed in 38% of brain tumours. The two other chemoresistance-related genes were occasionally overexpressed in brain tumours (2% for MDR1, 9% for DHFR). Our results provide evidence that chemoresistance is intrinsic to the brain tissue and seems likely to be a multifactorial process.
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PMID:A study of the expression of four chemoresistance-related genes in human primary and metastatic brain tumours. 838 72

Selection protocols were designed to determine whether non-cytotoxic chemomodifiers can influence the evolution of the drug-resistant phenotype. To this end, the human multiple myeloma cell line RPMI 8226 (8226/S) was selected with either doxorubicin, verapamil or doxorubicin plus verapamil. Using this approach low-level multi-drug-resistant (MDR) cell lines were obtained when 8226/S was selected with doxorubicin only or doxorubicin plus verapamil but not with verapamil only. The MDR phenotypes obtained were mechanistically distinct. In doxorubicin only-selected cells (8226/dox4), drug resistance was mediated by over-expression of the MDR1 gene and its cognate protein P-glycoprotein. In contrast, the drug resistance seen in the doxorubicin plus verapamil-selected cells was mediated through decreases in topoisomerase II protein levels and catalytic activity and not by P-glycoprotein over-expression. Cells selected with verapamil alone did not become resistant to any of the drugs tested. None of the 3 selected cell lines showed any changes in MRP gene expression when compared with 8226/S. Our results indicate that the inclusion of verapamil during drug selection with doxorubicin influences the drug-resistant phenotype by preventing the selection of MDR1/P-glycoprotein-positive cells.
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PMID:Verapamil suppresses the emergence of P-glycoprotein-mediated multi-drug resistance. 863 68

Gene expression was analyzed by cDNA-PCR at the mRNA level in bone marrow samples (>80% blasts) from ALL (28 primary, 22 first relapses, 10 recurrent relapses), from AML (14 primary, 23 relapses), In peripheral blood lymphocytes from CLL (five untreated, 10 treated), in one CML in blast crisis in the course of the disease (four samples), and in bone marrow samples from healthy donors (12 specimens). We found low mean MDR1 expression in primary ALL, first relapses of ALL, and primary AML. Significantly higher mean relative MDR1 expression levels were seen in recurrent relapses of ALL, and in the group of relapsed state AML. MDR1 expression measured intermediate in bone marrow samples from healthy donors. The CLL lymphocytes showed generally relatively high MDR1 expression levels. MRP gene expression measured very similar in primary ALL, first relapses of ALL, primary AML, and normal bone marrow. Significantly increased MRP mRNA levels were observed in the groups of recurrent ALL and relapsed state AML. CLL lymphocytes also showed high MRP expression levels. A combined increase of MDRI (about 20-fold) and MRP (about four-fold) was monitored in samples obtained from the CML in blast crisis after chemotherapy. While no significant differences of the mean topoisomerase IIbeta mRNA levels were found throughout, a significantly decreased topoisomerase IIalpha gene expression was measured in first and recurrent relapses of ALL. In CLL lymphocytes either the expression of the topoisomerase IIalpha gene was not detectable by cDNA-PCR, or it measured very low. Topoisomerase IIalpha gene expression was correlated to cyclin A gene expression in the samples of acute leukemias, Indicating the link of topoisomerase IIalpha expression to the proliferative activity of these leukemic blast cells. Our results point to a potentially multifactorial emergence of multidrug resistance in particular states and types of leukemias.
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PMID:MDR1, MRP, topoisomerase IIalpha/beta, and cyclin A gene expression in acute and chronic leukemias. 865 99

Inhibitors of calcium-calmodulin-dependent processes, 1-[N,O-bis(1,5-isoquinolinesulfonyl)-N-methyl-L-tyrosyl]-4-piperazine KN-62 and trifluoperazine (TFP), at non-cytotoxic concentrations (2 and 5 microM, respectively) enhanced etoposide (VP-16) cytotoxicity in Adriamycin-resistant (HL-60/ADR0.05) cells (3- to > 50-fold). In contrast to TFP, the inhibitor KN-62 was able to reverse resistance in HL-60/ADR0.05 cells at VP-16 concentrations that produced equivalent cytotoxicity in sensitive (HL-60/S) cells. Unlike TFP, the cellular accumulation of VP-16 in the presence of KN-62 was enhanced 1.5- to 2-fold in HL-60/S (MDR1 -ve) and HL-60/ADR0.05 (MDR1 +ve) cells. To achieve equivalent cytotoxicity, levels of VP-16 in the resistant cells were > 4-fold lower in the presence of KN-62 compared with treatment with VP-16 alone. The sensitizing effects of both KN-62 and TFP were due to enhancement (2- to 4-fold) of VP-16-induced topoisomerase II (TOPO II)-mediated DNA cleavable complex formation, and depletion of the 170 kDa (alpha) TOPO II isoform. The DNA damage induced by VP-16 in the presence of KN-62 or TFP resulted in the rapid induction of apoptosis and depletion of cells in "S" phase of the cell cycle. Both 5 microM TFP and 2 microM KN-62 enhanced the phosphorylation of 170 kDa TOPO II 1.6-fold and 1.5-fold, respectively. Results suggest that the inhibitory effect of KN-62 or TFP on calcium-calmodulin-dependent processes may be mechanistically involved in sensitizing resistant cells to VP-16 by enhancing TOPO II-mediated DNA damage.
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PMID:Cellular events involved in the sensitization of etoposide-resistant cells by inhibitors of calcium-calmodulin-dependent processes. Role for effects on apoptosis, DNA cleavable complex, and phosphorylation. 895 49

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