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)

After twenty years, understanding the mechanisms of tumor cells kill by anthracyclines still remains an active area of research. Of many mechanisms described for this class of drugs, efforts in the last year have focused on defining the role of free radical formation, topoisomerase II-induced DNA breakage, and P-170-dependent cellular accumulation of anthracyclines in tumor cell kill and resistance. First, in a number of tumor cell lines, the formation of free radical species from anthracyclines has been implicated in the cell killing. Modulation of detoxification pathways in a drug-resistant cell line e.g depletion of GSH, a substrate for peroxidase and transferase, enhanced both the formation of oxy-radicals and adriamycin cytotoxicity. It should be noted, however, that these findings are not true for every cell line examined, and free radical-mediated tumor kill may be cell- or tissue-specific. Second, anthracyclines-mediated topo II-dependent DNA cleavage was observed in most cell lines and reduced breaks were found in resistant cells. The decrease in single-strand breaks, however, neither correlated with the degree of resistance nor with differences in the relative topo II activity, which was in most cases only two-fold less in resistant cells than in sensitive cells. Finally, the reduced accumulation of the drug does not appear to be the only contributing factor in multidrug resistant cells and P-170 is not the only protein overexpressed in certain cells, e.g., an 85,000 Da protein may also be linked to adriamycin resistance. Although GST protein is overexpressed in most adriamycin resistant cells along with mdr1 gene, current evidence suggests that this protein may not be directly involved in adriamycin resistance. Taken together, both the mechanism of action and resistance to this class of drug likely vary among cell lines. Clinical studies in the past year have brought about interesting refinements in anthracycline-containing chemotherapy; ICRF-187 (by itself also cytotoxic) seems to offer protection against cardiac toxicity, while implicating iron in the mediation of cardiac damage. Out of a large number of newer anthracycline derivatives, clinical evidence indicates only a modest increase in therapeutic index with a few analogs, perhaps idarubicin and epirubicin. It is not yet clear that being able to receive more milligrams (or more cycles) of anthracycline eventually translates into a significantly better response rate or in a survival advantage. Much less clear is whether patients refractory to adriamycin may derive any benefit from newer anthracyclines.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Anthracyclines. 222 2

Over the past ten years several laboratories have explored the use of perfluorochemical emulsions (PFCE) and carbogen (95% O2/5% CO2; C) or oxygen breathing as an adjuvant to radiation therapy and/or chemotherapy in solid tumor model systems. The rationale for the use of PFCE and C or oxygen breathing in this therapeutic setting is that solid tumor masses contain areas of hypoxia which are therapeutically resistant. Since x-rays and many chemotherapeutic agents require oxygen to be maximally cytotoxic and most normal tissues are well-oxygenated, the additional oxygen put in circulation by the PFCE/C should not increase the normal tissue toxicities produced by the various therapies. Several anticancer agents are dependent on oxygen to be cytotoxic, these drugs such as the iron-chelating peptide bleomycin are enhanced in antitumor activity by the co-administration of a PFCE/C. The antitumor alkylating agents especially cyclophosphamide, BCNU and melphalan show increased tumor cell killing without a concomitant increase in bone marrow toxicity when administered with PFCE/C. Enhanced activity was also observed when topoisomerase II inhibitors such as adriamycin and etoposide were co-administered with PFCE/C. Positive effects, although smaller, were observed when antimetabolites such as 5-fluorouracil and methotrexate were co-administered with PFCE/C.
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PMID:Combination of perfluorochemical emulsions and carbogen breathing with cancer chemotherapy. 784 13

Probucol [(4,4'-(-(isopropylidenedithio) bis (2,6-di-t-butylphenol)], a hypolipidemic drug, was evaluated for its effects on the clastogenic activity of ADM in Swiss albino mice. Male mice were treated i.p. with different doses (25, 50 and 100 mg/kg, body weight/day) of probucol for 7 days. Some of the mice in each dose group of probucol and those in the positive control group were injected i.p. with Adriamycin (ADM, 8 mg/kg, body weight) and killed after 24 hr. Femoral cells of mice were collected and studied for the frequency of micronuclei and the ratio of polychromatic erythrocytes to Normochromatic erythrocytes. Furthermore, proteins, DNA, RNA, Malondialdehyde (MDA) and non-protein sulfhydryl (NP-SH) levels were determined in the hepatic cells. Probucol treatment failed to induce any significant clastogenic, cytotoxic and biochemical changes. However, pre-treatment with probucol was found to reduce the ADM-induced micronuclei without any alteration in its cytotoxicity. The DNA, RNA, proteins and NP-SH levels in the hepatic cells of these animals were increased and the MDA concentrations were reduced. The inhibition of ADM-induced clastogenicity by probucol may be attributed to its lipids lowering, iron chelating, free radical scavenging and topoisomerase-II-depleting action.
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PMID:Effect of probucol on the cytological and biochemical changes induced by adriamycin in Swiss albino mice. 902 75

Histologic and biochemical studies were carried out to compare the protective activity of various bisdiketopiperazines against the cardiac and renal toxicity induced by doxorubicin in spontaneously hypertensive rats (SHR), a well-established animal model of this disorder, with: (1) the rates of hydrolysis of these agents to form the iron-chelating derivatives (which are considered to cause a decrease in the formation of reactive oxygen intermediates) and (2) the ability of these derivatives to bind iron. SHR were given 12 weekly injections of doxorubicin, 1 mg/kg i.v. either alone or 30 min after the administration of ICRF-154, ICRF-187, ICRF-192, ICRF-197, ICRF-198, ICRF-239 and ADR-559. Semiquantitative grading of the severity of the resulting cardiac and renal lesions showed that ICRF-187, ICRF-154 and ADR-559 were the most protective, whereas ICRF-197 and ICRF-239 provided intermediate degrees of protection, and ICRF-192 and ICRF-198 were not protective. Quantitative measurements in vitro revealed only relatively small differences in the rates of opening of the two diketopiperazine rings of the various agents to form the corresponding iron-chelating diacid diamide derivatives, and in the ability of these various derivatives to remove iron from the iron-doxorubicin complex. Such differences showed no relationship with cardioprotective activity. Some bisdiketopiperazines (including ICRF-154 and ICRF-187) with cardioprotective activity also are inhibitors of DNA topoisomerase II; however, the significance of this relationship remains uncertain, since ADR-925, the open-ring derivative of ICRF-187, does not inhibit DNA topoisomerase II.
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PMID:Comparison of the protective effects against chronic doxorubicin cardiotoxicity and the rates of iron (III) displacement reactions of ICRF-187 and other bisdiketopiperazines. 927 16

A review is presented of the various types of cardiotoxicity associated with the clinical use of doxorubicin, a highly effective antineoplastic agent of the anthracycline family. Acute toxicity is related to rapid intravenous administration of the drug and is manifested by vasodilatation, hypotension and cardiac arrhythmias. Subacute toxicity is very uncommon. It develops early in the course of therapy and is characterized by myocarditis and pericarditis. Chronic toxicity is the most common form of doxorubicin-induced cardiac toxicity. It is manifested by chronic dilated cardiomyopathy, which develops late in the course of therapy or shortly after its termination. Morphologic changes are characteristic and consist of myofibrillar loss and cytoplasmic vacuolization (which is due to dilatation of the sarcoplasmic reticulum) of the myocytes. The damaging effects of reactive oxygen species, generated by the interaction of doxorubicin with iron, play a critically important role in the pathogenesis of the chronic cardiotoxicity. Other factors related to this toxicity include inhibition of DNA topoisomerase II, stimulation of certain immune responses and a diversity of other biochemical effects on various cellular organelles. Doxorubicin induces apoptosis in a variety of cell types, but not in cardiac myocytes. The chronic cardiotoxicity of doxorubicin is significantly attenuated by chelation of iron by ICRF-187 (dexrazoxane). A greatly delayed type of doxorubicin cardiotoxicity has been recently found to occur in survivors of childhood cancers who were treated with doxorubicin without any immediate adverse effects, but develop chronic cardiomyopathy at periods of time ranging up to 15 years later. The pathogenesis of this type of toxicity remains to be determined.
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PMID:Pathogenesis and prevention of doxorubicin cardiomyopathy. 950 40

Anthracycline-derivatives are frequently used chemotherapeutics in treatment of numerous human malignancies. Anthracyclines are known for their complex cytotoxic mechanism involving i) inhibition of enzymes such as topoisomerase II, RNA polymerase, cytochrome c oxidase and others; ii) intercalation into DNA; iii) chelation of iron and generation of reactive oxygen species (ROS); iv) induction of apoptosis. Here, mechanistic aspects for successful cytostasis and for side effects, e.g. cardiomyopathy, are discussed. We emphasize recent developments in anthracycline-mediated apoptosis and focus on a well known representative, doxorubicin (adriamycin, adriblastin). We reflect on the role of oxidative stress and interactions with intracellular signaling pathways.
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PMID:Anthracycline-derived chemotherapeutics in apoptosis and free radical cytotoxicity (Review). 985 55

1. Dexrazoxane (ICRF-187) is the only clinically approved drug for use in cancer patients to prevent anthracycline mediated cardiotoxicity. 2. The mode of action appears to be mainly due to the potential of the drug to remove iron from iron/anthracycline complexes and thus reduce free radical formation by these complexes. 3. Dexrazoxane also influences cell biology by its ability to inhibit topoisomerase II and its effects on the regulation of cellular iron homeostasis. 4. Although the cardioprotective effect of dexrazoxane in cancer patients undergoing chemotherapy with anthracyclines is well documented, the potential of this drug to modulate topoisomerase II activity and cellular iron metabolism may hold the key for future applications of dexrazoxane in cancer therapy, immunology, or infectious diseases.
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PMID:Dexrazoxane (ICRF-187). 988 68

Piroxantrone and losoxantrone are new DNA topoisomerase II-targeting anthrapyrazole antitumor agents that display cardiotoxicity both clinically and in animal models. A study was undertaken to see whether dexrazoxane or its hydrolysis product ADR-925 could remove iron(III) from its complexes with piroxantrone or losoxantrone. Their cardiotoxicity may result from the formation of iron(III) complexes of losoxantrone and piroxantrone. Subsequent reductive activation of their iron(III) complexes likely results in oxygen-free radical-mediated cardiotoxicity. Dexrazoxane is in clinical use as a doxorubicin cardioprotective agent. Dexrazoxane presumably acts through its hydrolyzed metal ion binding form ADR-925 by removing iron(III) from its complex with doxorubicin, or by scavenging free iron(III), thus preventing oxygen-free radical-based oxidative damage to the heart tissue. ADR-925 was able to remove iron(III) from its complexes with piroxantrone and losoxantrone, though not as efficiently or as quickly as it could from its complexes with doxorubicin and other anthracyclines. This study provides a basis for utilizing dexrazoxane for the clinical prevention of anthrapyrazole cardiotoxicity.
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PMID:The displacement of iron(III) from its complexes with the anticancer drugs piroxantrone and losoxantrone by the hydrolyzed form of the cardioprotective agent dexrazoxane. 1064 63

Dexrazoxane is a bidentate chelator of divalent cations. Pretreatment with short infusions of dexrazoxane prior to bolus doxorubicin has been shown to lessen the incidence and severity of anthracycline-associated cardiac toxicity. However, because of rapid, diffusion-mediated cellular uptake and the short plasma half-life of dexrazoxane, combined with prolonged cellular retention of doxorubicin, dexrazoxane may be more effective when administered as a continuous infusion. Thus, a Phase I pharmacokinetic trial of a 96-h infusion of dexrazoxane was performed. Dexrazoxane doses were escalated in cohorts of 3 to 6 patients per dose level. All patients received granulocyte-colony stimulating factor at a dose of 5 microg/kg/day starting 24 h after completion of the dexrazoxane infusion. Plasma samples were collected and analyzed for dexrazoxane by high-performance liquid chromatography. Urine collections were performed at baseline and during the infusion to determine the renal clearance of dexrazoxane and the excretion rate of divalent cations. Twenty-two patients were enrolled at doses ranging from 125 to 250 mg/m(2)/day. Grade 3 and 4 toxicities included grade 4 thrombocytopenia in 2 patients treated at 250 mg/m(2)/day, grade 3 thrombocytopenia and grade 4 nausea and vomiting in 1 patient treated at 221 mg/m(2)/day, grade 4 diarrhea and grade 3 nausea and vomiting in 1 patient treated at 221 mg/m(2)/day, and grade 3 hypertension in 1 patient treated at 166.25 mg/m(2)/day. Steady-state dexrazoxane levels ranged from 496 microg/l (2.2 microM) to 1639 microg/l (7.4 microM). Dexrazoxane plasma CL(ss) and elimination t(1/2) were 7.2 +/- 1.6 l/h/m(2) and 2.0 +/- 0.8 h, respectively. The mean percentage of administered dexrazoxane recovered in the urine at steady state was 30% (range, 10-66%). Urinary iron and zinc excretion during the dexrazoxane infusion increased in 12 of 18 and 19 of 19 patients by a median of 3.7- and 2.4-fold, respectively. These results suggest that dexrazoxane as a 96-h infusion can be safely administered with granulocyte-colony stimulating factor at doses that achieve plasma levels that have been demonstrated previously to inhibit topoisomerase II activity and to induce apoptosis in vitro. Additional studies will be required to determine whether the combination of continuous infusions of dexrazoxane and doxorubicin would provide enhanced cardioprotection compared with the currently recommended bolus or short infusion schedules.
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PMID:Phase I trial of 96-hour continuous infusion of dexrazoxane in patients with advanced malignancies. 1141 Apr 92

Anthracyclines are a class of antitumor drugs widely used for the treatment of a variety of malignancy, including leukemias, lymphomas, sarcomas, and carcinomas. Different mechanisms have been proposed for anthracycline antitumor effects including free-radical generation, DNA intercalation/binding, activation of signaling pathways, inhibition of topoisomerase II and apoptosis. A life-threatening form of cardiomyopathy hampers the clinical use of anthracyclines. According to the prevailing hypothesis, anthracyclines injure the heart by generating damaging free radicals through iron-catalyzed redox cycling. Although the "iron and free-radical hypothesis" can explain some aspects of anthracycline acute toxicity, it is nonetheless disappointing when referred to chronic cardiomyopathy. An alternative hypothesis implicates C-13 alcohol metabolites of anthracyclines as mediators of myocardial contractile dysfunction ("metabolite hypothesis"). Hydroxy metabolites are formed upon two-electron reduction of the C-13 carbonyl group in the side chain of anthracyclines by cytosolic NADPH-dependent reductases. Anthracycline alcohol metabolites can affect myocardial energy metabolism, ionic gradients, and Ca2+ movements, ultimately impairing cardiac contraction and relaxation. In addition, alcohol metabolites can impair cardiac intracellular iron handling and homeostasis, by delocalizing iron from the [4Fe-4S] cluster of cytoplasmic aconitase. Chronic cardiotoxicity induced by C-13 alcohol metabolite might be primed by oxidative stress generated by anthracycline redox cycling ("unifying hypothesis"). Putative cardioprotective strategies should be aimed at decreasing C-13 alcohol metabolite production by means of efficient inhibitors of anthracycline reductases, as short-chain coenzyme Q analogs and chalcones that compete with anthracyclines for the enzyme active site, or by developing novel anthracyclines less susceptible to reductive metabolism.
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PMID:Human heart cytosolic reductases and anthracycline cardiotoxicity. 1179

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