EC:5.99.1.2 - FACTA Search

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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 number of topoisomerase II-acting drugs have been described, but few demonstrate schedule-dependent anti-tumour activity. The activity of the epipodophyllotoxins etoposide and teniposide and the acridine dye derivative amsacrine is clearly schedule-dependent, and this related not only to the observation that the activity of topoisomerase II varies throughout the cell cycle but also to the finding that these drugs are rapidly cleared from the cell following exposure, permitting DNA repair. Etoposide has been most clearly shown to be schedule dependent in clinical studies. The response rates of patients with small-cell lung cancer receiving a 24-h infusion was only 10% as compared with 89% when the same dose was given over 5 days. Pharmacokinetic studies performed in these patients demonstrated that although the total systemic exposure (area under the plasma concentration-time curve, AUC) was the same in both arms of the study, the duration of exposure to low levels of drug (> 1 microgram/ml) was doubled in the 5-day arm. Haematological toxicity was the same in both arms of the study, as was the duration of exposure to higher plasma levels (> 5 micrograms/ml), suggesting that this toxicity may be associated with higher plasma concentrations, whereas anti-tumour activity is related to prolonged exposure to low levels of drug. This was confirmed in a subsequent study, where prolongation of treatment to 8 days compared to 5 days resulted in a similar exposure to low plasma concentrations and no difference in response rates or survival. Haematological toxicity in this study was worse in the 5-day arm, which also had an increase exposure to high levels of drug (> 5 micrograms/ml). More recently, interest has focused on even more prolonged etoposide administration, typically involving small daily doses repeated for 14-21 days. Although this schedule shows high activity in relapsed small-cell lung cancer and lymphoma, it is associated with significant toxicity (around one-third of patients experience grade III/IV leukopenia or neutropenia), which may be related to the observation that the etoposide dose delivered per course in these studies is higher than that obtained with standard dosing over 3-5 days. Further randomised studies are required to determine the optimal dose and schedule of etoposide.
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PMID:Schedule-dependent topoisomerase II-inhibiting drugs. 807 33

Over the past decade, DNA topoisomerase I and II appeared to be the targets of some antitumor agents: CPT-11 and Topotecan derived from Camptothecin which interact with topoisomerase I; Actinomycin D, Adriamycin and Daunorubicin, Elliptinium Acetate, Mitoxantrone, Etoposide and Teniposide, Amsacrine which interact with topoisomerase II. The multiple functions of these enzymes are important as they play a role during replication, transcription, recombination, repair and chromatine organisation. Particularly, they relax torsional constraints which appear when intertwined DNA strands are separated while replication fork or RNA polymerases are moving. To some extent, topoisomerase I and II are structurally and functionally different. Moreover, topoisomerase I is not indispensable for a living cell whereas topoisomerase II is. Drug-topoisomerase interaction which probably leads to antitumoral effect of the compounds studied in this review is not a trivial inhibition of the enzyme but rather a poisoning due to stabilization of cleavable complexes between the enzyme and DNA. These stabilized complexes are likely to induce apoptosis-like programmed cell death, which is characterised by DNA fragmentation. However, it appears that it is the collision of the replication fork with the drug-stabilized cleavable complex that is responsible for the cytotoxicity of the drug: poisoning of topoisomerases by antitumor agents leads to a new concept of "dynamic toxicity". Although they interact with a common target, topoisomerase II poisons have differential effects on macromolecules syntheses, cell cycle and chromosome fragmentation; a few compounds may produce free radicals. Because of these differential effects in addition to quantitative and qualitative variations of stabilized cleavable complexes, in particular DNA sequences on which topoisomerase II is stabilized, these antitumor agents do not resemble each other. Cellular resistance to topoisomerases poisons results of two principal types of alteration: target and/or drug transport modification. Decreased ability to form the cleavable complex in resistant cells may be the consequence of both decreased amount of topoisomerase or altered enzyme. On the other hand, overexpression of membrane P-glycoprotein, which pumps drugs out of the cell by an energy dependent process provokes a decreased accumulation of these drugs. Cross resistances to other drugs are mainly under control of these two different mechanisms of resistance. A complete knowledge of their individual effects and mechanisms of resistance would allow a better clinical use of topoisomerases poisons, especially when administered in combination chemotherapy.
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PMID:[Poisons of DNA topoisomerases I and II]. 808 Oct 34

Etoposide (VP 16-213), the epipodophyllotoxin derivative that is widely used in the treatment of cancer, forms complexes with DNA-topoisomerase type II alpha to exert its cytotoxicity. The drug was evaluated in vivo in Swiss albino mouse bone marrow cells for its ability to induce clastogenicity and sister chromatid exchanges (SCEs). Doses of 5, 10, 15, and 20 mg/kg body weight etoposide given intraperitoneally induced a dose-dependent significant increase of clastogenicity (Trend test, alpha < or = 0.05). The aberrations induced were predominantly chromatid types. The drug shows specificity for S-phase cells: cells harvested 6 and 12 hr posttreatment showed a significantly increased number of damaged cells and aberrations per cell. Doses of 0.5, 1.0, 2.5, 5.0, and 10.0 mg etoposide/kg body weight induced a dose-dependent significant induction of SCEs (Trend test, alpha < or = 0.05). The minimal effective concentration was 0.5 mg/kg body weight. Etoposide significantly prolonged the cell cycle time at all concentrations tested: 12-13 hr in treated animals vs. 11 hr in control. The results confirm in vivo cell cycle phase specificity of the drug and further designate etoposide as a potent clastogen and a genotoxic agent in mice.
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PMID:Etoposide (VP-16): cytogenetic studies in mice. 816 93

Etoposide, a nonintercalating antitumor drug, is a potent inhibitor of topoisomerase II activity. When Trypanosoma equiperdum is treated with etoposide, cleavable complexes are stabilized between topoisomerase II and kinetoplast DNA minicircles, a component of trypanosome mitochondrial DNA (T. A. Shapiro, V. A. Klein, and P. T. Englund, J. Biol. Chem. 264:4173-4178, 1989). Etoposide also promotes the time-dependent accumulation of small minicircle catenanes. These catenanes are radiolabeled in vivo with [3H]thymidine. Dimers are most abundant, but novel structures containing up to five noncovalently closed minicircles are detectable. Analysis by two-dimensional gel electrophoresis and electron microscopy indicates that dimers joined by up to six interlocks are late replication intermediates that accumulate when topoisomerase II activity is blocked. The requirement for topoisomerase II is particularly interesting because minicircles do not share the features postulated to make this enzyme essential in other systems: for minicircles, the replication fork is unidirectional, access to the DNA is not blocked by nucleosomes, and daughter circles are extensively nicked and (or) gapped.
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PMID:Mitochondrial topoisomerase II activity is essential for kinetoplast DNA minicircle segregation. 819 10

12 patients: (7 males and 5 females) with recurrent brainstem gliomas were treated with the oral topoisomerase inhibitor VP-16 (Etoposide). Patients ranged in age from 3 to 49 years with a median age of 7 years. All patients had been previously treated with radiation therapy (conventional fractionation: 4; hyperfractionation: 8) and 5 had received prior nitrosourea-based chemotherapy at time of tumor recurrence. Tumor recurrence was documented by radiographic tumor enlargement utilizing brain MRI with gadolinium enhancement (12) and clinical neurologic deterioration (9). Two patients underwent biopsy pathologically documenting tumor recurrence. Each cycle of therapy consisted of 21 days of VP-16 (50 mg/m2/day) followed by a 14 day rest followed by an additional 21 days of VP-16 (50 mg/m2 day). Complete blood counts were followed bi-weekly and a neurologic examination and brain MRI scan with contrast were performed prior to initiation of each cycle of therapy. Treatment related complications included: partial alopecia (5); diarrhea (5); weight loss (4); neutropenia (2); and thrombocytopenia (4). No patient required transfusion or antibiotic treatment of neutropenic fever. There were no treatment related deaths. 12 patients were evaluable of whom 6 demonstrated a radiographic response (1 complete; 3 partial; 2 stable disease) with a median duration of response of 8 months. In summary; oral VP-16 is a well tolerated and relatively non-toxic chemotherapeutic agent with apparent activity in this small cohort of patients with recurrent brainstem gliomas.
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PMID:Recurrent brainstem gliomas treated with oral VP-16. 850 18

Caco-2 intestinal epithelial cells differentiate spontaneously after confluence when contact inhibition slows proliferation. We hypothesized that such reversible differentiation might be dependent on DNA synthesis and repair. We studied the effects of the topoisomerase II inhibitor etoposide on Caco-2 proliferation and on the differentiation markers alkaline phosphatase and dipeptidyl dipeptidase specific activity, as well as cell motility. Etoposide (0.3-10 microM) dose-dependently inhibited proliferation and alkaline phosphatase activity. However, etoposide (0.7-3 microM dose-dependently stimulated dipeptidyl dipeptidase activity. Above this concentration, dipeptidyl dipeptidase was also inhibited. Similar effects on enzyme activity were observed when proliferation was blocked with mitomycin C. Etoposide (1-10 microM) also dose-dependently inhibited cell motility. The selective stimulation of dipeptidyl dipeptidase activity by etoposide may offer a clue to the regulation of intestinal brush border enzyme expression at the molecular level.
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PMID:Topoisomerase II inhibition differentially modulates Caco-2 intestinal epithelial cell phenotype. 861 32

The anticancer agent saintopin induces DNA cleavage mediated by both topoisomerase (topo) I and topo II in vitro through stabilization of the reversible enzyme-DNA cleavable complex. We established saintopin-resistant cell lines (KB/STP-1 and KB/STP-2) from human epidermoid cancer KB cells by stepwise exposure to increasing doses of the drug. KB/STP-1 and KB/STP-2 cells showed 12- and 44-fold increases, respectively, in resistance to saintopin relative to that of KB cells. Both saintopin-resistant cell lines showed only small reductions in sensitivity to the topo II inhibitor etoposide but developed marked cross-resistance to the topo I-targeting camptothecin derivative CPT-11 [(4s)-4,11-diethyl-4-hydroxy-9-[(4-piperidinopiperidino)carbony loxy] dione hydrochloride trihydrate] and its active form, SN-38 (7-ethyl-10-hydroxycamptothecin). In contrast, both KB/STP-1 and KB/STP-2 cells showed increased collateral sensitivity to cisplatin, a nitrosourea derivative, mitomycin C, and UV light. The protein concentration, activity, and mRNA abundance of both topo I and topo II were similar in KB/STP-1, KB/STP-2, and the parental KB cells. There were no significant changes in the drug-stabilized topo-DNA cleavable complex formation in KB and KB/STP-2 cells. Two point mutations were detected in topo I cDNA from KB/STP-2 cells, but these were also present in KB cells. Topo I mRNA abundance decreased markedly immediately after exposure of KB/STP-2 cells to saintopin; no such effects were apparent in KB cells. In contrast, topo II mRNA was not markedly affected by saintopin in either KB or KB/STP-2 cells. Treatment with CPT-11 or SN-38 also induced a markedly greater and more persistent reduction in topo I mRNA abundance in KB/STP-2 cells than in KB cells. Etoposide had no marked effect on topo I mRNA abundance in either KB/STP-2 or KB cells. Topo I mRNA was highly unstable in KB/STP-2 cells in comparison to KB cells when incubated with saintopin. This novel regulation of topo I mRNA by topo I-targeting agents could be associated with acquirement of drug resistance to saintopin or SN-38/CPT-11 in KB/STP-2 cells.
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PMID:Drug-induced down-regulation of topoisomerase I in human epidermoid cancer cells resistant to saintopin and camptothecins. 862 10

Merbarone is a catalytic inhibitor of DNA topoisomerase (topo) II that does not stabilize DNA-topo II cleavable complexes. Although the cytotoxicity of and resistance to complex-stabilizing topo II inhibitors, such as etoposide, is thought to be mediated through stabilization of these complexes, the mechanisms of cytotoxicity and resistance to catalytic inhibitors are not well known. To investigate this issue, we established 12 merbarone-resistant cell lines from human leukemia CEM cells, designated CEM/M70-B1 through -B12. Assessed by either growth inhibition or clonogenic assay, these cell lines are 3.5- to 6.6-fold resistant to merbarone, compared to the CEM parent cells. Karyotype analysis of three of the cell lines revealed that while CEM and drug-resistant cell lines had chromosome abnormalities in common, indicating a common origin, two of the merbarone-resistant lines (B1 and B8) each had unique structural markers. These novel cell lines are cross-resistant to complex-stabilizing topo II inhibitors, etoposide, teniposide, amsacrine, and doxorubicin, but not to other catalytic inhibitors, aclarubicin or SN-22995. Of considerable interest, these cell lines are cross-resistant to SN-38, a putative topo I inhibitor, but cross-resistance to other topo I inhibitors (camptothecin and topotecan) was lower and not seen in every cell line. In all 12 cell lines, there was a high correlation among drug resistance ratios between etoposide and teniposide and between merbarone and SN-38. By contrast, there was a low correlation between merbarone and etoposide and between SN-38 and other topo I inhibitors. These results suggest that resistance to merbarone and cross-resistance to etoposide might be through different mechanisms, whereas cross-resistance to SN-38 might be through a merbarone-related mechanism. Etoposide and SN-38 stabilized fewer DNA-topoisomerase complexes in CEM/M70-B cells than in CEM cells, but camptothecin stabilized more. Merbarone inhibited complex formation induced by etoposide in drug-sensitive and -resistant cells, but the degree of inhibition was lower in CEM/M70-B cells than in the parental cells. Moreover, merbarone did not affect complex formation stabilized by SN-38 or camptothecin. Immunoblot analysis of the CEM/M70-B cells showed decreased topo IIalpha, increased topo IIbeta, and no change of topo I protein, compared to CEM cells. We propose the hypothesis that decreased topo IIalpha may play a role in the resistance to merbarone that is different from that to complex-stabilizing drugs. Cross-resistance to catalytic inhibitors may be due to reduced complex formation as a consequence of decreased topo IIalpha. We also found that DNA-protein complexes stabilized by SN-38 might be different from those stabilized by topo II inhibitors and blocked by merbarone. Judging from both the high correlation of drug sensitivities and complex-formation assays, we postulate that mechanisms of cytotoxicity and cross-resistance of SN-38 in CEM/M70-B cells might be similar to those of merbarone. We believe that the CEM/M70-B cells are the first to be selected and characterized for resistance to a catalytic inhibitor of topo II. This study provides novel cell lines with characteristics of resistances to topo II and topo I inhibitors.
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PMID:Characterization of novel human leukemic cell lines selected for resistance to merbarone, a catalytic inhibitor of DNA topoisomerase II. 865

Etoposide induces DNA damage to cells by interacting with the nuclear enzyme topoisomerase II. In this investigation the human lymphoblastic leukemia cell line (CEM) was used to study induction of DNA-strand breaks and cellular drug uptake after treatment with etoposide at a concentration of 0.5-2 micrograms/ml. High performance liquid chromatography was used for determination of etoposide concentrations. The alkaline elution assay and the DNA unwinding technique were compared for quantifying strand breaks in DNA induced by etoposide. The concentrations required to increase the level of DNA damage significantly was as follows: the DNA unwinding technique, 0.20 microgram/ml; the alkaline elution assay with proteinase K, 0.45 microgram/ml; the alkaline elution assay without proteinase K, 0.60 microgram/ml. When the half-life was adjusted, considering the efflux time of etoposide from cells, it was found to be only a few minutes. The present data show that the DNA unwinding technique is to be preferred for the screening of DNA damage. This technique is easier and quicker to perform than the alkaline elution technique.
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PMID:DNA damage induced by etoposide; a comparison of two different methods for determination of strand breaks in DNA. 869 38

Etoposide (VP-16)-resistant K562 cells (K/VP.5) were 26-fold resistant to VP-16, due in part to a reduction in DNA topoisomerase II (topoisomerase II) protein levels. Compared with parental K562 cells, VP-16-resistant K/VP.5 cells were found to be 3.4-fold more sensitive to the effects of dexrazoxane (ICRF-187), a topoisomerase II inhibitor that does not stabilize topoisomerase II-DNA covalent complexes. In contrast, K/VP.5 cells were 4.0-fold cross-resistant to merbarone and showed no cross-resistance to fostriecin, two other topoisomerase II inhibitors that do not stabilize topoisomerase II-DNA covalent complexes. Preincubation with ICRF-187 resulted in greater inhibition of subsequent VP-16-induced topoisomerase II-DNA covalent complexes in K/VP.5 cells than in K562 cells. Conversely, preincubation with merbarone resulted in less inhibition of VP-16-induced topoisomerase II-DNA covalent complexes in K/VP.5 cells than in parental K562 cells. Preincubation with forstriecin had little effect on VP-16-induced topoisomerase II-DNA covalent complex formation in either cell line. The onset rates for ICRF-187 inhibition of VP-16-induced topoisomerase II-DNA complex formation were similar in sensitive and resistant cells. In addition, ICRF-187 had a comparable concentration-dependent inhibitory effect on the topoisomerase II catalytic activities of K562 and K/VP.5 cells. Together, our results indicate that collateral sensitivity to ICRF-187 in K/VP.5 cells is due to decreased topoisomerase II protein levels rather than to an alteration in topoisomerase II activity. Furthermore, results suggest that ICRF-187, merbarone, and fostriecin have different mechanisms of action that can be studied effectively in K/VP.5 and K562 cells.
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PMID:Collateral sensitivity to the bisdioxopiperazine dexrazoxane (ICRF-187) in etoposide (VP-16)-resistant human leukemia K562 cells. 875 37

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