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)

The cytotoxic and mutagenic effects of topoisomerase II inhibitors were measured in closely related strains of mouse lymphoma L5178Y cells differing in their sensitivity to ionizing radiation. Strain LY-S is sensitive to ionizing radiation relative to strain LY-R and is deficient in the rejoining of DNA double-strand breaks induced by this agent, whereas 2 radiation-resistant variants of strain LY-S have regained the ability to rejoin these double-strand breaks. We have found that the sensitivity of these cells to m-AMSA, VP-16, and ellipticine is correlated to their sensitivity to ionizing radiation. However, this correlation did not extend to their sensitivities to novobiocin, camptothecin, hydrogen peroxide, methyl nitrosourea and UV radiation. Thus, there appears to be a unique correlation between sensitivity to ionizing radiation and to topoisomerase II inhibitors which stabilize the cleavable complex between the enzyme and DNA. It is possible either that (1) topoisomerase II is altered in strain LY-S and that this enzyme is involved in the repair of DNA double-strand breaks or (2) strain LY-S is deficient in a reaction which is necessary for the repair of DNA double-strand breaks induced by ionizing radiation as well as the repair of DNA damage induced by these topoisomerase II inhibitors. m-AMSA, VP-16, and ellipticine were found to be highly mutagenic at the tk locus in L5178Y strains which are heterozygous for the tk gene but not in a tk hemizygous strain, indicating that these inhibitors induce multilocus lesions in DNA, as does ionizing radiation. The differences in the sensitivity of strains LY-R and LY-S to the topoisomerase II inhibitors were paralleled by differences in the induction of protein-associated DNA double-strand breaks in the 2 strains. This correlation did not extend to the radiation-resistant variants of strain LY-S, however. The variants showed resistance to the cytotoxic effects of the inhibitors relative to strain LY-S, but exhibited DNA double-strand break induction similar to that observed in strain LY-S.
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PMID:Relationship between topoisomerase II and radiosensitivity in mouse L5178Y lymphoma strains. 253 34

Several quinolones and antitumor compounds were tested as inhibitors of purified calf thymus topoisomerase II in unknotting, catenation, radiolabeled DNA cleavage, and quantitative nonradiolabeled cleavage assays. The antitumor agents VP-16 (demethylepipodophyllotoxin ethylio-beta-D-glucoside) and ellipticine demonstrated drug-enhanced topoisomerase II DNA cleavage (the concentration of drug that induced 50% of the maximal DNA cleavage in the test system [CC50]) at levels of less than or equal to 5 micrograms/ml. Nalidixic acid, norfloxacin, and oxolinic acid did not induce significant topoisomerase II DNA cleavage, whereas ciprofloxacin did induce some cleavage above background levels. CP-67,015, a new 6,8-difluoro-7-pyridyl 4-quinolone which possesses potent antibacterial activity, inhibited bacterial DNA gyrase at 0.125 micrograms/ml in a nonradioactive DNA cleavage assay. Unlike other quinolones characterized to date, CP-67,015 was shown to strongly enhance topoisomerase II-induced radiolabeled DNA cleavage with a CC50 of 33 micrograms/ml and demonstrated cleavage in a nonradiolabeled DNA cleavage assay with a CC50 of 73 micrograms/ml. The topoisomerase II-mediated cleavage of DNA by CP-67,015 is consistent with its reported clastogenic effect on DNA in cell culture and its positive mutagenic response in mouse lymphoma cells. In vitro topoisomerase II catalytic and cleavage assays are useful for gaining preliminary information concerning the possible interaction(s) of some quinolones with eucaryotic topoisomerase II which may relate directly to their safety (mutagenicity, clastogenicity, or both) in human and veterinary medicinal usage.
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PMID:Use of in vitro topoisomerase II assays for studying quinolone antibacterial agents. 255 75

The chemistry, pharmacology, pharmacokinetics, clinical efficacy, adverse effects, and pharmacodynamics of etoposide are reviewed. Etoposide, although similar in chemical structure to podophyllotoxin, has a different mechanism of cytotoxicity compared with its parent compound. Etoposide may stabilize type II topoisomerase-DNA complexes, preventing rejoining of single- and double-strand DNA breaks. Etoposide may also require cellular activation into intermediates, which then bind to DNA and disrupt cellular function. Oral etoposide has an average bioavailability of 50% (range, 17%-137%), with substantial intrapatient and interpatient variability. Etoposide is widely distributed in the body and is highly bound to plasma proteins (greater than 95%). Approximately 50% (range, 20%-81%) of an etoposide dose is recovered in the urine as parent drug or glucuronide, with the remainder of the dose being unaccounted for. The disposition of etoposide in patients with renal and hepatic dysfunction is discussed. Etoposide is effective in combination with other agents against lung cancer, and response rates of 90% in small-cell lung cancer have been observed. When etoposide is used in combination with other agents, response rates of approximately 80% have been observed in patients with testicular cancer. The activity of etoposide in treating leukemia, lymphoma, and breast and ovarian carcinomas and other tumors is discussed. The impact of etoposide on prolonging survival in lung and testicular cancer is addressed, and studies evaluating the pharmacodynamics of etoposide are described. Adverse effects associated with etoposide therapy include myelosuppression, alopecia, nausea and vomiting, mucositis, and hypotension after rapid intravenous administration. Etoposide has demonstrated considerable clinical efficacy against a broad spectrum of tumors.
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PMID:Etoposide: an update. 279 80

The N-acylanthracyclines AD32 (N-trifluoroacetyladriamycin-14-valerate) and AD143 (N-trifluoroacetyladriamycin-14-O-hemiadipate) are analogs of Adriamycin (ADR) undergoing clinical or advanced pre-clinical screening. Their principal metabolites, following the cleavage of the 14-acyl side-chain, are N-trifluoroacetyladriamycin (AD41) and its reduced form N-trifluoroacetyladriamycinol (AD92). Both these compounds are biologically active and detectable in treated patients, laboratory animals, and in tissue culture cells. Unlike ADR, AD32, as well as AD143 and metabolites, show no detectable binding to double-strand DNA. Their effects on DNA have been previously investigated in vivo and in vitro using the alkaline filter-elution assay. It has been shown that all of the compounds cause approximately equivalent amounts of protein-associated DNA breaks (PAB) and DNA-protein crosslinks in a mouse lymphoma and in tissue-culture leukemia cells. In order to establish whether the induction of PAB by the drugs requires DNA topoisomerase II mediation, cleavage mapping analysis was done with tested compounds using purified human topoisomerase II. DNA fragmentation was significantly enhanced in the presence of the enzyme and either AD41 or AD92. In contrast, no fragmentation enhancement was observed in the presence of the parental drugs AD32 or AD143. The results strongly suggest that metabolic activation of N-acylanthracyclines by nonspecific esterases is a prerequisite for their interaction with DNA topoisomerase II and for stabilization of the cleavable complex.
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PMID:Metabolic activation of N-acylanthracyclines precedes their interaction with DNA topoisomerase II. 304 Dec 37

The antitumor drug teniposide (VM-26) is a potent inducer of DNA breaks (Long et al., Cancer Res., (1985) 45, 3106), but it is only weakly mutagenic at the hprt locus in CHO cells (Singh and Gupta, Cancer Res., (1983) 43, 577). In the present study, the mutagenic and clastogenic activities of teniposide were evaluated in L5178Y/TK +/- -3.7.2C mouse lymphoma cells. Although teniposide is a weak mutagen at the hprt locus, it is a potent mutagen at the tk locus, with as little as 0.5 ng/ml producing 220 TK mutants/10(6) survivors at 96% survival (background = 100/10(6) survivors). This same dose of teniposide induced 38 aberrations per 100 metaphases (background = 7/100 cells). At 7 ng/ml, teniposide induced approximately 2700 TK mutants/10(6) survivors at approximately 10% survival. At the highest dose sampled for aberration analysis (5 ng/ml), teniposide induced 44 aberrations/100 cells. Most of the aberrations were chromosomal rather than chromatid events. As expected for a compound acting primarily by a clastogenic mechanism, most of the TK mutants were small colonies. Thus, teniposide is a potent clastogen, and it is a potent mutagen at the tk locus but not at the hprt locus. These results support the hypothesis that the location of the target gene affects the ability of the assay to detect both intragenic events and events causing functional multilocus effects. Thus, a heterozygous locus (like tk) but not a functionally hemizygous locus (like hprt) may permit the detection of mutagens that act primarily by a clastogenic mechanism. Because teniposide induces topoisomerase II-associated DNA breaks, and because there is evidence that teniposide may not interact directly with DNA, we discuss the possibility that the potent clastogenic/mutagenic activity of teniposide may be mediated by topoisomerase II.
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PMID:Mutagenicity and clastogenicity of teniposide (VM-26) in L5178Y/TK +/- -3.7.2C mouse lymphoma cells. 382 67

The human tri-thorax gene (HRX) also called ALL-1 (Acute Lymphocytic Leukemia-1) as well as MLL (Myeloid-lymphoid or Mixed-lineage Leukemia) gene, is disrupted in the majority of leukemias with chromosomal abnormalities involving 11q23. The alteration of the gene is related to leukemogenesis of various types such as acute myelogenous leukemia (AML), acute lymphoblastic leukemia (ALL), and acute mixed lineage leukemia. The gene is also rearranged in cases of secondary AML developing after exposure to chemotherapeutic agents, especially topoisomerase II inhibitors. In at least one report, genomic analysis of this recombination site showed the breakpoint to be a topoisomerase II binding site and that exposure to the inhibitor could induce the rearrangement. If exposure induces the rearrangement of the gene, secondary ALL as well as secondary AML could occur after exposure to these agents, because the type of leukemias with rearranged HRX gene is not limited to AML. We present here such a case of secondary ALL with this gene rearrangement which occurred during adjuvant chemotherapy for breast cancer. Although less cases of secondary ALL are reported in comparison with those of secondary AML, such case reports have been accumulating. The incidence of this type of leukemia should be clarified in the future.
Leuk Lymphoma 1995 May
PMID:HRX gene rearrangement in secondary acute lymphoblastic leukemia. 754 29

Cytogenetic analysis of tumor cells has revealed that recurring chromosome abnormalities are present in many tumors. In the leukemias, lymphomas, sarcomas, these abnormalities are frequently translocations or less often inversions which are closely associated with particular morphologic subtypes of these tumors. Rearrangements involving chromosome band 11q23 are common in acute leukemia, both lymphoblastic and myeloid (monoblastic), and are less common in lymphoma. Although several different genes have been cloned from 11q23 translocation breakpoints, the great majority involve the MLL (myeloid-lymphoid leukemia) gene. The MLL gene has several different names, ALL1, Htrx, HRX; the central part of the gene codes for multiple zinc fingers which show homology to the Drosophila trithorax gene. About 70% of infants with acute leukemia will have MLL rearrangements. MLL is involved in five common translocations as well as in 25 uncommon or rare translocations, insertions and deletions. The translocation breakpoints occur within an 8.3 kb region which can be detected with a 0.74 kb cDNA probe. Twenty-five percent of patients have a deletion 3' of the breakpoint which includes the zinc finger region. Patients who previously received drugs that inhibit topoisomerase II often develop acute leukemia with translocations involving 11q23. These translocations break MLL in the same 8.3 kb region. In the breakpoints cloned to date, the translocation leads to a fusion gene on the derivative 11 chromosome with a chimeric transcript, consisting of 5' MLL and the 3' segment of the other gene. The molecular dissection of these arrangements will provide insights into the biology of MLL and into the interaction of MLL with topoisomerase II inhibitors.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Chromosome translocations: good genes gone wrong. 767 46

Sensitivity to topoisomerase II inhibitors was tested at the cellular and enzyme level for two strains of mouse L5178Y lymphoma cells: resistant (LY-R) and sensitive (LY-S) to X-radiation. Differences in the susceptibility to inhibitors between LY-R and LY-S cells depended on the inhibitor used and were observed for adriamycin and VP-16, but not for mitoxantrone. On the other hand, isolated enzymes displayed the same sensitivity to all inhibitors tested regardless of the cell line. These results exclude the presence of altered topoisomerase II in LY-S cells as a possible reason for the collateral sensitivity of LY-S cells to X-radiation and topoisomerase II inhibitors.
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PMID:Sensitivity to inhibitors of type II topoisomerases from mouse L5178Y lymphoma strains that are resistant or sensitive to X-radiation. 767 89

The binding activities of the 170 kDa and the 180 kDa human topoisomerases II (topo II alpha and topo II beta) to linear DNA fragments with different degrees of curvature were characterized. In gel retardation experiments it was shown that both forms of the enzyme bind preferentially to a curved 287 bp fragment, forming a detectable stable complex. The affinity for straight DNA fragments of similar length is significantly lower. Both a commercially available topo II alpha, isolated from placenta, and topo II alpha and topo II beta purified from nuclear extracts of the Namalwa lymphoma tissue culture line gave similar results. The effects of double-stranded poly[d(A-T)], poly[d(G-C)], supercoiled plasmid DNA and linear Z-DNA on the topo II-complex with curved DNA were analyzed in competition experiments. The hierarchy of affinities of the 180 kDa topo II beta for these DNAs has the order: linear left-handed DNA > supercoiled DNA > or = curved DNA >> poly[d(A-T)] > poly[d(G-C)]. The 170 kDa topo II alpha binds with similar affinity to curved DNA and linear Z-DNA > or = supercoiled DNA >> linear B-DNA. The data imply that human topoisomerase II binding is more sensitive to DNA secondary structure than to DNA sequence per se. The ability of the enzyme to preferentially recognize a wide variety of sequences in unusual secondary structures suggests a mode of targeting the enzyme in vivo to regions of high negative supercoiling.
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PMID:Human 170 kDa and 180 kDa topoisomerases II bind preferentially to curved and left-handed linear DNA. 772 61

Three photoproducts of merocyanine 540 have been isolated, chemically characterized and synthesized. Two of these photoproducts, merocil and merodantoin, show significant antitumor activity in vitro and in vivo while demonstrating minimal toxicity to normal cells and tissues. Treatment of lymphoma cells with these compounds resulted in a rapid decline in macromolecular synthesis, DNA fragmentation inhibitable by actinomycin D and cycloheximide, and a marked rise in intracellular calcium. In vitro analysis revealed that activity of these compounds is dependent on topoisomerase II. These results are discussed in terms of the novel class of topoisomerase II-dependent compounds for potential use in chemotherapy.
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PMID:Topoisomerase II-dependent novel antitumor compounds merocil and merodantoin induce apoptosis in Daudi cells. 785 88


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