EC:5.99.1.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:5.99.1.3 (topoisomerase)
9,911 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The nuclear enzymes topoisomerase I and II are critical for DNA function and cell survival, and recent studies have identified these enzymes as cellular targets for several clinically active anticancer drugs. Topoisomerase II inhibitors (anthracyclines, epipodophyllotoxins, etc.) are active against several types of tumours. However, treatment with these drugs often results in the development of the multi-drug resistance. Because topoisomerase II-active drugs have several different modes of action, different mechanisms of resistance, including decreased activation and increased detoxification by glutathione-dependent enzymes, have also been implicated. Unlike topoisomerase II, topoisomerase I is not a cell cycle-dependent enzyme and, therefore, it is a more desirable cellular target for anticancer drug development. Topoisomerase I inhibitors, such as camptothecin and its derivatives, have shown significant activity against a broad range of tumours and, in general, are not substrates for either the multi-drug-resistance P-170 glycoprotein or the multi-drug-resistance-associated protein. Because of manageable toxicity and encouraging activity against solid tumours, topoisomerase I-active drugs offer promise in the clinical management of human tumours.
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PMID:Topoisomerase inhibitors. A review of their therapeutic potential in cancer. 770 11

Resistance to chemotherapy in brain tumors is complex and may involve multiple mechanisms. For commonly used drugs, such as nitrosoureas and platinum compounds, major mechanisms may involve increaded DNA repair or removal of the drug-DNA adducts. For water soluble nitrosoureas and also for platinum compounds, other mechanisms, such as alteration in drug transport, may be important. Another major mechanism may involve glutathione and glutathione-S-transferase pathways. For vinca alkaloids and epipodophyllotoxins p-glycoprotein mediated MDR appears to be the major feature in drug resistance. In addition, alteration of tubulin and topoisomerase II have been described in resistance to vinca alkaloids and epipodophyllotoxins respectively. Recently, increased multidrug resistance associated protein gene expression has been found in glioma cells and brain tumor samples; its clinical significance requires further investigation.
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PMID:Drug resistance in brain tumors. 780 93

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

Etoposide has demonstrated highly significant clinical activity against a wide variety of neoplasms, including germ-cell malignancies, small-cell lung cancer, non-Hodgkin's lymphomas, leukemias, Kaposi's sarcoma, neuroblastoma, and soft-tissue sarcomas. It is also one of the important agents in the preparatory regimens given prior to bone marrow and peripheral stem-cell rescue. Despite its high degree of efficacy in a number of malignancies, the optimal dose, schedule, and dosing form remain to be defined. It is possible that continuous or prolonged inhibition of the substrate, i. e., topoisomerase II, may be the key factor for the cytotoxic effects of etoposide. Clinical studies have shown the activity of etoposide to be schedule-dependent, with prolonged dosing, best accomplished by the oral dosing form, offering a therapeutic advantage. This benefit awaits validation by prospective randomized studies, some of which are in progress. Recent clinical investigations have focused on the use of etoposide in combination with (a) cytokines to ameliorate myelosuppression, the dose-limiting toxicity of etoposide; (b) agents such as cyclosporin A and verapamil to alter the p-glycoprotein (mdr1) function; and (c) topoisomerase I inhibitors to modulate the substrate upon which it acts. There is continued interest in the development of etoposide to its maximal clinical dimensions and in the examination of alternative biochemical and mechanistic approaches to further our understanding of this highly active agent.
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PMID:Etoposide: current status and future perspectives in the management of malignant neoplasms. 807 20

Cells from V79 multicell spheroids must be exposed to approximately 50 times more etoposide than exponentially growing monolayers in order to produce the same amount of cell killing. A part of this difference in sensitivity is readily explained by the decrease in growth fraction of large spheroids, and by the protection afforded by nutrient deprivation which also reduces cellular ATP. However, cells composing the outer 10% of large (approximately 600 microns diameter) V79 spheroids, although actively cycling, were still ten times more resistant to etoposide than exponentially growing monolayers, regardless of whether cells were exposed in situ in spheroids or dispersed by trypsin immediately prior to exposure to the drug. Four cell doublings (48 h) as monolayers were required before the outer cells of spheroids regained drug sensitivity equivalent to that of exponentially growing monolayers. No differences in uptake/efflux of 3H-etoposide or in levels of p-glycoprotein were observed between monolayers and the outer cells of spheroids. In addition, topoisomerase II protein measured by immunoblotting and topoisomerase II activity measured by decatenation of kinetoplast DNA were not reduced in the outer cells of spheroids compared to monolayers. DNA strand breakage measured in individual cells using the DNA precipitation and comet assays correlated well with cell killing with one exception: DNA damage was not affected when cells were incubated with etoposide in phosphate-buffered saline, although the etoposide concentration required to produce a given amount of cell killing was increased approximately 7-fold compared to cells incubated with the drug in complete medium. These results indicate that etoposide toxicity towards V79 spheroids is influenced not only by proliferative status of the cells but also by factors which may include DNA packaging and the growth environment of the cell prior to and during treatment.
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PMID:Cell killing and DNA damage by etoposide in Chinese hamster V79 monolayers and spheroids: influence of growth kinetics, growth environment and DNA packaging. 838 10

DNA topoisomerase II (topo II) is an essential nuclear enzyme which catalyzes the interconversions of various forms of DNA. As predicted from the human topo II cDNA, the enzyme contains a potential leucine zipper protein dimerization motif. We therefore tested whether topo II could enter protein-protein interactions with other better characterized leucine zipper-containing proteins and determined if these interactions could modify topo II enzymatic activity in vitro. By far Western analyses, a large C-terminal fragment of human topo II was shown to interact with the DNA binding and dimerization regions of either cAMP response element binding protein (CREB) or the activating transcription factor-2. The C-terminal topo II fragment also interacted with full-length c-Jun, but not with full-length c-Fos. Using CREB as a prototype, the effect of this interaction on various topo II catalytic activities was assessed in vitro. CREB, at a 1- to 10-fold molar excess relative to topo II, inhibited site-specific DNA cleavage activity on a 242-base pair fragment of the human alpha-glycoprotein hormone subunit gene promoter. Very high CREB concentrations (400-fold excess) apparently inhibited topo II DNA relaxation activity, but this result was likely a direct effect of CREB on the topology of the DNA substrate. More interestingly, a 10-fold molar excess of CREB stimulated topo II decatenation activity, the essential function of this enzyme in cell division. This stimulatory effect could also be elicited by c-Jun, which interacts with topo II, but not by c-Fos, which does not bind topo II in our in vitro assay. Since similar amounts of CREB reduced the abundance of topo II DNA cleavage products from the human alpha-CG promoter yet also stimulated decatenation activity, it can be concluded that either: 1) CREB stimulated the religation rate of topo II; or 2) CREB directed topo II to a new cleavage site present on the decatenation substrate but not present on the limited alpha-CG promoter. The structural requirements for topo II protein-protein interactions were also investigated. Site-directed mutations which destroyed the putative topo II leucine zipper did not disrupt topo II protein-protein interactions. Since the putative leucine zipper in topo II does not appear to mediate protein-protein interactions, we propose that an alternate as yet uncharacterized structure is involved in the association of topo II with itself and other regulatory proteins.
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PMID:Modification of DNA topoisomerase II activity via direct interactions with the cyclic adenosine-3',5'-monophosphate response element-binding protein and related transcription factors. 838 55

We have studied the functional properties of topoisomerase II (Topo II) in a subclone of the HL-60 cell line, which is highly resistant to cytotoxic Topo II inhibitors, but does not express p-glycoprotein. The cells contain the two forms of human topo II with Mr 170 and 180 kDa in equal proportions. Two different states of both forms of the enzymes can be separated by anion-exchange chromatography and functionally discriminated on the basis of orthovanadate sensitivity. The EC50 of orthovanadate was 0.2 microM for the early eluting and 30 microM for the late eluting Topo II.
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PMID:Different functional states of topoisomerase II can be discriminated by orthovanadate sensitivity in multi-drug resistant human leukemic cells. 839 70

V511 and V513 cell lines, derived from Chinese hamster V79 cells following alkylating agent mutagenesis and subsequent selection with VP-16, showed resistance to cytotoxicity and DNA strand breaks induced by topoisomerase (topo) II inhibitors and were resistant to VP-16-induced sister chromatid exchanges. They showed no amplification of the multidrug-resistant p-glycoprotein. In a kinetoplast-DNA decatenation assay, V511 and V513 showed 51% and 49% topo II activity relative to parental V79 cells, respectively. By western-blot analysis all three logarithmically growing cell lines showed similar levels of topo II beta (M(r) 180,000), which increased as cells progressed to quiescence. In contrast, immunoreactive levels of topo II alpha (M(r) 170,000) were 6.8% in V511 and 62.4% in V513 relative to V79. V511 showed drastically decreased topo II alpha in both log growth and quiescence. In a second approach, immunoreactive topo II was analyzed in different phases of the cell cycle in logarithmically growing cells fractionated by fluorescence-activated cell sorting. All cell lines demonstrated relatively stable topo II beta throughout the cell cycle. Topo II alpha showed little cell cycle variation in V79 or V513. However, in V511, it was only detectable at low levels in G2/M phase. When cell growth parameters were measured, V511 and V513 showed a 17% increase in cell doubling time relative to V79. These studies indicate that cells with a drastic reduction in topo II alpha (V511) or mutant topo II alpha (V513) but with normal levels of topo II beta show only minor perturbations of cell growth.
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PMID:Drastic reduction of topoisomerase II alpha associated with major acquired resistance to topoisomerase II active agents but minor perturbations of cell growth. 874 4

We have established a cisplatin resistant subline, MKN/CDDP, from the MKN-45 human stomach adenocarcinoma cell line. MKN/CDDP was 10.7 fold more resistant to cisplatin, 5.4 fold resistant to carboplatin, 2.7 fold resistant to 5-fluorouracil and only 1.4 fold resistant to adriamycin. To investigate the mechanism of the cisplatin resistance in the MKN/CDDP subline, we performed the biochemical characterization of MKN-45 and MKN/CDDP. MKN/CDDP cells showed no induction in p-glycoprotein and topoisomerase II. The level of glutathione S-transferase-pi was higher in MKN/CDDP than the parent line, but a similar level of glutathione S-transferase-L isoform was observed. Superoxide dismutase activity was 1.67 fold higher in the MKN/CDDP subline than the parent line, but 60 kDa catalase was much lower in the MKN/CDDP subline. In addition to those changes. MKN/CDDP was not able to attach to the culture dish, which is probably due to the lack of fibronectin association on the cell surface. The MKN/CDDP subline revealed a variety of biochemical changes which are related to drug inactivation and to cell substratum adhesion. The significance of each modification in the development of the cisplatin resistance will be evaluated in future studies.
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PMID:Biochemical characterization of cisplatin-resistance in MKN-45 human stomach adenocarcinoma cell line. 891 23

The anthracyclines are widely used in the treatment of haematological and non-haematological malignancy and there is now more than 30 years' clinical experience with these agents but despite this, their mechanism of action is incompletely understood. The anthracyclines have been shown to intercalate with DNA and indirectly inhibit the activity of the enzyme topoisomerase II, resulting in DNA strand breaks. More recently, workers have focused on induction of apoptosis and have shown that daunorubicin stimulates production of the apoptotic mediator, ceramide and that the activity of doxorubicin can be blocked by inhibitors of CD95 (fas). One of the major problems with anthracycline therapy is the development of resistance which may be mediated by p-glycoprotein or by other mechanisms. Much recent research has concentrated on methods to modulate the drug-resistant phenotype and these include development of new analogues and use of specific reversal agents. The toxicity profile of the anthracyclines includes bone marrow suppression, severe local reaction following extravasation, radiation recall, alopecia, gastrointestinal and hepatic effects, development of secondary malignancies and significant cardiac toxicity. The risk factors for the development of anthracycline-related cardiac toxicity are well documented and several methods have been exploited in attempts at prevention. Finally, a number of drug delivery systems have been developed in order to improve therapeutic response and reduce toxicity to normal tissues, including the use of liposomal preparations.
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PMID:Anthracyclines in haematology: preclinical studies, toxicity and delivery systems. 948 50

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