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)

Resistance of noncycling cells to amsacrine (m-AMSA) has been widely reported and may limit the activity of this drug against solid tumors. The biochemical mechanism(s) for this resistance have been investigated using spontaneously transformed Chinese hamster fibroblasts (AA8 cells, a subline of Chinese hamster ovary-cells) in log- and plateau-phase spinner cultures. In early plateau phase most cells entered a growth-arrested state with a G1-G0 DNA content and showed a marked decrease in sensitivity to cytotoxicity induced by a 1-h exposure to m-AMSA or to its solid tumor-active analogue, CI-921. Studies with radiolabeled m-AMSA established that similar levels of drug were accumulated by log- and plateau-phase cells and that there was no significant drug metabolism in either of these cultures after 1 h. However, marked differences in sensitivity to m-AMSA-induced DNA breakage were observed using a fluorescence assay for DNA unwinding (Kanter P.M., and Schwartz, H.S., Mol. Pharmacol., 22: 145-151, 1982). Changes in sensitivity to DNA breakage occurred in parallel with changes in sensitivity to m-AMSA-induced cell killing. DNA breaks disappeared rapidly after drug removal (half-time approximately 4 min), suggesting that these lesions were probably mediated by DNA topoisomerase II. Resistance to m-AMSA may therefore be associated with changes in topoisomerase II activity in noncycling cells.
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PMID:Mechanism of resistance of noncycling mammalian cells to 4'-(9-acridinylamino)methanesulfon-m-anisidide: comparison of uptake, metabolism, and DNA breakage in log- and plateau-phase Chinese hamster fibroblast cell cultures. 282 71

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

We have compared the effects of a number of inhibitors including aphidicolin, 2,4-dinitrophenol (DNP) and novobiocin on the in vitro cytotoxicity of several topoisomerase II (topo II)-directed agents, using cultured murine Lewis lung carcinoma cells. These agents comprised amsacrine, CI-921 (9-[(2-methoxy-4-methylsulfonylamino)phenylamino]-N,5-dimethyl-4- acridinecarboxamide isethionate, isethionate, a derivative of amsacrine), DACA (N-[2-(dimethylamino)ethyl]acridine-4-carboxamide dihydrochloride, a new DNA intercalator with high solid tumor activity), daunorubicin, doxorubicin, epirubicin, etoposide, mitoxantrone, and teniposide. Novobiocin, an antibiotic that affects topo II action, reduced the cytotoxic effect of DACA as well as that of amsacrine and doxorubicin, and reduced the extent of G2-phase arrest by DACA. DNP, an uncoupler of mitochondrial respiration, inhibited drug action in a manner similar to that of novobiocin but to a smaller extent. Aphidicolin, a specific inhibitor of DNA polymerase-alpha, reduced the cytotoxic effect of amsacrine, CI-921, etoposide, and teniposide but not that of DACA, daunorubicin, doxorubicin, epirubicin, or mitoxantrone. The immediate effect of each topo II-directed agent on the incorporation of thymidine into DNA was also measured at a drug concentration (D10) that killed 90% of cells. Susceptibility to aphidicolin reversal was strongly correlated with inhibition of thymidine incorporation (r = 0.91; p < or = 0.001). The results suggest that the involvement of DNA replication in the cytotoxic action of topo II-directed agents differs according to the agent used.
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PMID:A comparison of the effects of aphidicolin and other inhibitors on topoisomerase II-directed cytotoxic drugs. 826 Jul 50

A series of mitomycin C (MMC) analogues, namely cyclopentanthraquinone derivatives, were synthesized via Diels-Alder cyclization of naphthoquinone with 1-vinylcyclopent-1-enes. These new compounds are planar structures, like MMC, and bear an aziridine ring and a methyl carbamate side chain. After bioreduction, they are anticipated to be capable of intercalating into double-stranded DNA and bind covalently. Structure-activity relationships were studied. Of these compounds, 2,3-aziridino-4-[[(methylamino)carbonyl]methyl] cyclopent[alpha]anthracene-6,11-dione (4) was shown to have inhibitory activity against several leukemic and solid tumor cell lines. Mice (BDF1) bearing Lewis lung adenocarcinoma were treated with 4 and MMC (i.p., QD x 5). At a dose of 30.0 mg/kg, compound 4 was as effective as MMC (0.8 mg/kg). Compound 4 appears to be less toxic than MMC. DNA unwinding assay indicated that 4 is able to intercalate into DNA double strands and is also a topoisomerase II inhibitor.
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PMID:Cyclopent[a]anthraquinones as DNA intercalating agents with covalent bond formation potential: synthesis and biological activity. 870 11

The feasibility of combined studies on a cell-line panel and primary cultures of patient tumor cells in the preclinical evaluation of new anticancer drugs was evaluated in a study of the activity and cross-resistance pattern in vitro of the new semi-synthetic vinca alkaloid vinorelbine (Vrb). The activity of Vrb was investigated in ten cell lines representing different resistance mechanisms and in a total of 256 fresh human tumor samples, using the fluorometric microculture cytotoxicity assay (FMCA). Resistance to Vrb in the cell lines was associated with expression of the multidrug resistance-mediating P-glycoprotein and the multidrug resistance-associated protein (MRP) and by a recently described tubulin-associated mechanism, while the cell lines with topoisomerase II- and glutathion-associated resistance did not show decreased sensitivity to the drug. Cross-resistance to vincristine (Vcr) and other tubulin-active agents was high in cell lines as well as in patient cells. As with most commonly used anti-cancer drugs, Vrb was more active in hematological than in solid tumor samples. Among the solid tumors investigated, the highest in vitro response rates were observed in ovarian cancer (27%), sarcoma (25%), non-small cell lung cancer (21%) and bladder cancer (20%), while no response was observed in renal or colorectal cancer. Compared to Vcr, Vrb appeared to be slightly more active in solid tumors and slightly less active in hematological tumors. The results show that although Vrb displays a high degree of cross-resistance to Vcr and other tubulin-active drugs, some difference in the activity spectrum could be detected and that the drug is sensitive to multiple mechanisms of resistance. The results also suggest that leukemias, ovarian cancer, sarcoma and bladder cancer are possible further targets for Vrb. The combination of studies on a cell-line panel and patient tumor cells from a broad spectrum of diagnoses to evaluate a new drug seems feasible and may give information on the mechanism of action and target diagnoses for phase II trials.
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PMID:In vitro evaluation of new anticancer drugs, exemplified by vinorelbine, using the fluorometric microculture cytotoxicity assay on human tumor cell lines and patient biopsy cells. 941 16

S16020-2 (NSC-659687) is a new olivacine derivative that is highly cytotoxic in vitro and displays remarkable antitumor activity against various experimental tumors, especially some solid tumor models. Its antitumor activity is notably higher than that of 2-methyl-9-hydroxy-ellipticinium (NMHE) and comparable to that of doxorubicin HCl, although with a different tumor specificity. S16020-2 is being tested in phase I clinical trials. A study of the interaction of S16020-2 with DNA showed that it binds through intercalation between adjacent DNA base pairs, inducing an unwinding of 10 degrees of the double helix. Its DNA affinity is approximately equal to that of NMHE and decreases as a function of the salt concentration, indicating a significant electrostatic contribution to the overall binding free energy. S16020-2 did not interfere with the catalytic cycle of DNA topoisomerase I but stimulated DNA topoisomerase II-mediated DNA cleavage via a strictly ATP-dependent mechanism. The interactions of S16020-2 and NMHE with DNA topoisomerase II in vitro are very similar. Both drugs have the same DNA sequence specificity of cleavage and the same biphasic dose-effect response, and neither drug inhibited the rate of DNA religation. In contrast with these observations, in in vivo experiments, S16020-2 was able to induce topoisomerase II-mediated DNA strand breaks at concentrations 500-fold lower than NMHE. We conclude that DNA topoisomerase II most likely is the cellular target involved in the mechanism of cytotoxicity of S16020-2. Its higher biological activity and potency to induce cellular DNA cleavage suggest the involvement of as-yet-unidentified cellular factors.
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PMID:S16020-2, a new highly cytotoxic antitumor olivacine derivative: DNA interaction and DNA topoisomerase II inhibition. 946 78

Pyrazoloacridine (PA), an acridine congener with an unknown mechanism of action, has shown selective activity against solid tumor cells, cytotoxicity in noncycling and hypoxic cells, and promising antitumor activity in Phase I clinical trials. In the present study, the effect of PA on topoisomerase (topo) activity was evaluated using yeast strains lacking functional topo I or II, mammalian cell nuclear extracts, purified samples of mammalian topo I and topo II, and intact mammalian tissue culture cells. Clonogenic assays revealed that PA cytotoxicity in yeast strains was unaffected by selective loss of topo I or topo II activity. On the other hand, enzyme assays revealed that 2-4 microM PA abolished the catalytic activity of both topo I and topo II in vitro. In contrast to topotecan and etoposide, PA did not stabilize covalent topo-DNA complexes. Instead, PA inhibited topotecan-induced stabilization of covalent topo I-DNA complexes and etoposide-induced stabilization of topo II-DNA complexes in vitro and in intact cells. Consistent with these results, colony-forming assays indicated that short-term PA exposure inhibited the cytotoxicity of topotecan and etoposide, whereas prolonged PA exposure was itself toxic to these cells. Accumulation studies revealed that PA was concentrated as much as 250-fold in drug-treated cells, resulting in intranuclear concentrations that far exceeded those required to inhibit topo I and topo II. Collectively, these results not only suggest that PA can target both topo I and topo II at clinically achievable concentrations but also indicate that its mechanism is distinct from topo I and topo II poisons presently licensed for clinical use.
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PMID:Effect of pyrazoloacridine (NSC 366140) on DNA topoisomerases I and II. 953 38

The bacterial topoisomerase II (DNA gyrase) and the mammalian topoisomerase II represent the cellular targets for quinolone antibacterials and a wide variety of anticancer drugs, respectively. In view of the mechanistic similarities and sequence homologies exhibited by the two enzymes, tentative efforts to selectively shift from an antibacterial to an antitumoral activity was made by synthesizing a series of modified tricyclic quinolones, in which the essential 3-carboxylic function is surrogated by phenolic OH and the classic C-6 fluorine atom is replaced by a NH2 group. The resulting 7-amino-9-acridone derivatives were assayed for their antibacterial as well as cytotoxic activities. No antibacterial activity was found. On the other hand, many derivatives showed significant cytotoxic activity against both HL-60 and P388 leukemias and a wide panel of human and rodent solid tumor cells, derivatives 25 and 26 displaying the best overall antiproliferative activity. Against the LoVo cell line, derivative 25 exhibited higher cytotoxic effects than etoposide.
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PMID:Design and synthesis of modified quinolones as antitumoral acridones. 1037 19

XK469 (NSC 697887) is a synthetic quinoxaline phenoxypropionic acid derivative that possesses unusual solid tumor selectivity and activity against multidrug-resistant cancer cells. We report here that XK469 and its S(-) and R(+)-isomers induce reversible protein-DNA crosslinks in mammalian cells. Under protein denaturing conditions, the protein-DNA crosslinks are rendered irreversible and stable to DNA banding by CsCl gradient ultracentrifugation. Several lines of evidence indicate that the primary target of XK469 is topoisomerase IIbeta. Preferential targeting of topoisomerase IIbeta may explain the solid tumor selectivity of XK469 and its analogs because solid tumors, unlike leukemias, often have large populations of cells in the G(1)/G(0) phases of the cell cycle in which topoisomerase IIbeta is high whereas topoisomerase IIalpha, the primary target of many leukemia selective drugs, is low.
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PMID:XK469, a selective topoisomerase IIbeta poison. 1051 94

Pyrazoloacridine (PZA) is the first of a new class of rationally synthesized acridine derivatives to undergo clinical testing as an anticancer agent. Recent studies suggest that PZA might be a dual inhibitor of DNA topoisomerase I and DNA topoisomerase II that exerts its effects by diminishing the formation of topoisomerase-DNA adducts. Consistent with this unique mechanism of action, PZA exhibits broad spectrum antitumor activity in preclinical models in vivo. In addition, this agent displays several unique properties including solid tumor selectivity, activity against hypoxic cells, and cytotoxicity in noncycling cells. PZA also retains full activity against cells that are resistant to other agents on the basis of overexpression of P-glycoprotein or the multidrug resistance-associated protein (MRP). PZA has been studied in phase I trials in adults and children, and is currently undergoing broad phase II trials in a number of tumor types. No significant anti-tumor activity has been seen in gastrointestinal malignancies and prostate cancer. Results from ongoing or recently completed trials are awaited before the utility of this agent in our current armamentarium can be defined. Because of its unique properties, combination studies with other antineoplastic agents are warranted.
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PMID:Current status of pyrazoloacridine as an anticancer agent. 1055 21

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