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)

DNA was prepared from normal tissue and 19 lung cancer cell lines. Using probes which detect restriction fragment length polymorphisms at both the topoisomerase II alpha and beta loci, heterozygosity was detected at a frequency of 0.17 and 0.37 for the alpha and beta loci, respectively. Southern blot analysis of DNA extracted from lung cancer cell lines detected amplification of both the topoisomerase II alpha and ERBB2 genes in the adenocarcinoma line Calu3. These results indicate that topoisomerase II alpha and ERBB2 may be closely linked on chromosome 17 and coamplified during adenocarcinoma progression. Since topoisomerase II is a target for several anticancer drugs, it will be of interest to study alterations to topoisomerase II genes during tumour development, as these may in part determine the response of the tumour to chemotherapy.
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PMID:Amplification of the topoisomerase II alpha gene in a non-small cell lung cancer cell line and characterisation of polymorphisms at the human topoisomerase II alpha and beta loci in normal tissue. 137 18

Resistance to 0.8 microM 4'-(9-acridinylamino)methanesulphon-m-anisidide (m-AMSA) was induced by stepwise increases of drug concentration in the human tumor cell line CALc18 originating from a breast adenocarcinoma. The resistant cell line CALc18/AMSA exhibited a resistance index of 10 and a cross-resistance to other topoisomerase II inhibitors. A 3-fold decrease in the levels of topoisomerase II decatenating activity was found in CALc18/AMSA cells. By contrast, topoisomerase I activity was increased by about 3-fold in resistant cells. Interestingly this line was hypersensitive to camptothecin, a specific inhibitor of topoisomerase I. Restriction endonuclease patterns of the topoisomerase I and topoisomerase II loci were found to be identical in CALc18/AMSA and CALc18 with no evidence of gene amplification and rearrangements. Alkaline elution of m-AMSA-treated cells showed that DNA single strand breaks and DNA-protein crosslinks were decreased in CALc18/AMSA. The DNA lesions also obtained in m-AMSA-treated nuclei indicated that no drug uptake modification occurred in both cells. Moreover, the in vitro m-AMSA-induced DNA cleavage per unit of decatenating activity and the inhibitory effects of antitumoral drugs on decatenation were not found to be different with topoisomerase II from sensitive or resistant cells. However the specific cleavage induced by m-AMSA/per mg of crude protein from resistant cells was 2 to 3 times decreased. Multidrug resistance gene transcripts were not detected while levels of acidic glutathione S transferase mRNA were found to be 8 to 10-fold greater in resistant than in sensitive cell line with no amplification of the gene. In conclusion, the diminution of topoisomerase II activity and the increase of both topoisomerase I and acidic glutathione S transferase transcripts could contribute to the resistant phenotype of these breast cancer cells.
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PMID:Study of molecular markers of resistance to m-AMSA in a human breast cancer cell line. Decrease of topoisomerase II and increase of both topoisomerase I and acidic glutathione S transferase. 164 55

CI-921 (NSC 343499; 9-[[2-methoxy-4-[(methylsulphonyl)amino]phenyl]amino] -N,5-dimethyl- 4-acridinecarboxamide) is a topoisomerase II poison with high experimental antitumour activity. It was administered by 15 min infusion to 16 evaluable patients with non-small cell lung cancer (NSCLC) (7 with no prior treatment, 9 patients in relapse following surgery/radiotherapy) at a dose (648 mg/m2 divided over 3 days, repeated every 3 weeks) determined by phase I trial. Patients had a median performance status of 1 (WHO), and median age of 61 years. The histology comprised squamous carcinoma (11), adenocarcinoma (1), mixed histology (2), bronchio-alveolar carcinoma (1) and large cell undifferentiated carcinoma (1). Neutropenia grade greater than or equal to 3 was seen in 15 patients, infections with recovery in 3, and grand mal seizures in 1 patient. Grade less than or equal to 2 nausea and vomiting occurred in 66% courses and phlebitis in the infusion arm in 37%. 1 patient with squamous cell carcinoma achieved a partial response lasting 5 months. Further testing in this and other tumour types using multiple daily schedules is warranted.
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PMID:Phase II study of the amsacrine analogue CI-921 (NSC 343499) in non-small cell lung cancer. 166 18

Stable acquired resistance to etoposide (VP-16) or teniposide (VM-26) in HCT116 human colon carcinoma cells and A549 human lung adenocarcinoma cells, was previously obtained by weekly 1-h exposures to either drug (B. H. Long, Natl. Cancer Inst. Monogr., 4: 123-127, 1987). The purpose of this study was to identify possible mechanisms of resistance present in these cells by using human mdr1 and topoisomerase II DNA probes, antibodies to these gene products, and P4 phage unknotting assay for topoisomerase II activities. HCT116(VP)35 cells were 9-, 7-, and 6-fold resistant to VP-16, VM-26, and Adriamycin, respectively, and showed no cross-resistance to colchicine and actinomycin D. These cells had no differences in mdr1 gene, mdr1 mRNA, or P-glycoprotein levels but displayed decreased levels of topoisomerase II mRNA and enzyme activity without any alteration of drug sensitivity displayed by the enzyme. HCT116(VM)34 cells were 5-, 7-, and 21-fold resistant to VP-16, VM-26, and Adriamycin; were cross-resistant to colchicine (7-fold) and actinomycin D (18-fold); and possessed a 9-fold increase in mdr1 mRNA and increased P-glycoprotein without evidence of mdr1 gene amplification. No alterations in topoisomerase II gene or mRNA levels, enzyme activity, or drug sensitivity were observed. A549(VP)28 and A549(VM)28 cells were 8-fold resistant to VP-16 and VM-26 and 3-fold resistant to Adriamycin. Both lines were not cross-resistant to colchicine or actinomycin D but were hypersensitive to cis-platinum. No alterations in mdr1 gene, mdr1 mRNA, or P-glycoprotein levels, but lower topoisomerase II mRNA levels and decreased enzyme activities, were observed. Of the four acquired resistant cell lines, resistance is likely related to elevated mdr1 expression in one line and to decreased topoisomerase II expression in the other three lines.
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PMID:Mechanisms of resistance to etoposide and teniposide in acquired resistant human colon and lung carcinoma cell lines. 171 44

The in vitro effects of the 2-(arylmethylamino)-1,3-propanediols (AMAPs) on macromolecular synthesis have been examined using the murine leukemia, P388, and the human mammary adenocarcinoma, MCF-7, under conditions of short-term drug exposure. AMAPs that were observed to inhibit macromolecular synthesis produced nearly equipotent inhibition of DNA and RNA synthesis. Equivalent inhibition of protein synthesis generally required significantly greater concentrations of AMAP. There is a general correlation between inhibition of polynucleotide synthesis and in vivo antitumor activity. The effects of four clinical candidate AMAPs (crisnatol, 773U82, 502U83, and 7U85) on macromolecular synthesis were further compared with those of actinomycin D, doxorubicin, mitoxantrone, etoposide, amsacrine, and cisplatin in MCF-7 cells. The pattern of AMAP action was most similar to that observed for doxorubicin and mitoxantrone. Finally, the effects of these four AMAPs on the size, specific activity, and rate of incorporation of [3H]-dTTP into DNA of MCF-7 cells synchronized by pretreatment with hydroxyurea was determined. It was found that DNA synthesis was inhibited by AMAPs independent of inhibition of the uptake, phosphorylation, or retention of the metabolic precursors. These results support the theory that antitumor AMAPs interfere with the normal functioning of enzymes, such as topoisomerase II or DNA and RNA polymerases, which interact with DNA.
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PMID:Effects of isomeric 2-(arylmethylamino)-1,3-propanediols (AMAPs) and clinically established agents on macromolecular synthesis in P388 and MCF-7 cells. 187 97

Tumor necrosis factor alpha (TNF) exhibits cytotoxic activity on some solid tumors and has been reported to be synergistic with topoisomerase-II-targeted antineoplastic agents. A wide range of TNF concentrations (from 10 to 10,000 U/ml) was tested in 9 human lung cancer cell lines (5 small-cell and 4 non-small-cell carcinomas) using a semi-automated MTT assay. TNF was not cytotoxic in 8 cell lines, while an adenocarcinoma cell line was marginally sensitive to the cytokine. Using 125I-TNF we were able to show the presence of specific binding sites for TNF in 4/9 human lung cancer cell lines. Scatchard analysis of the marginally sensitive cell line showed high-affinity, saturable binding. With 5 cell lines we also tested whether TNF affected the cytotoxicity of doxorubicin and etoposide, 2 topoisomerase II-targeted drugs which are widely used in the therapy of lung cancer. No significant increase in cytotoxicity was seen when TNF was added to the 2 anti-neoplastic agents. In contrast to certain other human and mouse lines, human lung cancer cell lines appear to be resistant to TNF, despite the presence of the receptor in some of them; moreover, no synergistic effect of TNF and 2 topoisomerase-II-targeted drugs was evident in these human cell lines.
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PMID:Effects of tumor necrosis factor, alone or in combination with topoisomerase-II-targeted drugs, on human lung cancer cell lines. 216 14

Drug-induced DNA hypermethylation was observed to constitute one component of the response of human tumor cells to toxic concentrations of commonly used cancer chemotherapy agents. In both human lung adenocarcinoma cells (HTB-54) and human rhabdomyosarcoma cells (CCl-136), pulse exposures to the topoisomerase II inhibitors etoposide and nalidixic acid; to the antibiotic doxorubicin; to the microtubule inhibitors vincristine, vinblastine, and colchicine; to the DNA cross-linking agent cisplatinum; to hydroxyurea; and to the antimetabolites 1-beta-D-arabinofuranosylcytosine, 5-fluorouracil, 5-fluorodeoxyuridine, and methotrexate were associated with profound drug-induced DNA hypermethylation. Exposure of human T-lymphocytes (MOLT-4) to toxic pulse doses of 3'-azidodideoxythymidine was associated with similar drug-induced DNA hypermethylation. In every case, drug-induced DNA hypermethylation was observed only when the degree of DNA synthesis inhibition caused by the drug exceeded 90% and when drug levels or duration of exposure was sufficient to kill 90-100% of exposed cells. Drug-induced DNA hypermethylation was shown not to represent a tissue culture phenomenon, since it occurred in vivo during high-dose 1-beta-D-arabinofuranosylcytosine and hydroxyurea treatments in two leukemic patients. Drug-induced alterations in DNA methylation were frequently biphasic, with hypomethylation occurring at drug concentrations which produced mild DNA synthesis inhibition and which killed less than 50% of exposed cells. Exposure to the alkylating agents 1,3-bis(2-chloroethyl)-1-nitrosourea and cyclophosphamide and to the antimetabolites 5-azadeoxycytidine and 6-thioguanine was associated with DNA hypomethylation at all studied concentrations in HTB-54 cells. Drug-induced DNA hypermethylation could be blocked by preexposure to hypomethylating agents administered at nontoxic to mildly toxic concentrations. Drug-induced DNA hypermethylation may be capable of creating drug-resistant phenotypes by inactivating genes the products of which are required for drug cytotoxicity. Perhaps paradoxically, drug-induced DNA hypermethylation may also produce a second class of drug-resistant tumor cells, characterized by overexpression of particular gene products, by potentiating the process of gene amplification.
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PMID:Drug-induced DNA hypermethylation and drug resistance in human tumors. 279 Jul 94

The cardiac glycoside ouabain, which is a specific inhibitor of the Na+,K+-pump, confers dramatic protection from the cytotoxic effects of doxorubicin (Adriamycin). This effect was documented in cultured A549 cells (human lung adenocarcinoma). CCL210 cells (human fibroblasts), and V79 cells (hamster fibroblasts). Maximum protection from doxorubicin cytotoxicity was achieved using 1 microM ouabain for A549 and CCL210 cells and 300 microM ouabain for V79 cells. These concentrations correlated well with the concentrations of ouabain required to induce Na+,K+-pump blockade, which was assessed using the K+ analogue 86Rb+. This suggests that protection is mediated by pump blockade. Addition of ouabain at the same time as doxorubicin was just as protective as preincubation with ouabain for an hour, demonstrating that the ouabain acts rapidly. Ouabain treatment affected neither influx nor efflux of doxorubicin. Ouabain also had no effect on verapamil-induced inhibition of doxorubicin efflux. However, ouabain partially blocked the verapamil-induced potentiation of the cytotoxic effects of doxorubicin. Therefore, ouabain does not protect by affecting intracellular doxorubicin levels. Fluorescence microscopy showed that the ability of doxorubicin to reach the nucleus was not influenced by ouabain. Alkaline elution studies demonstrated that ouabain greatly decreased doxorubicin-induced DNA strand breakage. Protection from cytotoxicity correlated closely with this decrease in strand breakage. These studies suggest that the stabilization of DNA-topoisomerase II complexes is closely linked to the mechanism of doxorubicin cytotoxicity and that this stabilization is influenced by the intracellular ionic milieu.
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PMID:Reduction of doxorubicin cytotoxicity by ouabain: correlation with topoisomerase-induced DNA strand breakage in human and hamster cells. 282 82

The specific inhibition of eukaryote DNA topoisomerase II by the anti-cancer drugs VP16, VM26, and 21 other congeners of podophyllotoxin has been extensively studied in this laboratory through the use of alkaline elution and other techniques. A structure-activity relationship has been established for cytotoxicity, single and double strand DNA breakage, and inhibition of the DNA strand passing activity of topoisomerase II. Furthermore, topoisomerase inhibition was measured in four naturally sensitive and resistant human lung carcinoma cells by quantifying the amount of single and double strand DNA breakage produced by VP16 and VM26 in cells and isolated nuclei. A direct correlation between double but not single strand DNA breaks and cytotoxicity was observed for the analogs in A549 human lung adenocarcinoma cells. In fact, some analogs were capable of producing substantial single strand DNA breakage without producing cytotoxicity. A similar correspondence was observed between double strand DNA breaks and cytotoxicity produced by VP16 and VM26 in the naturally sensitive and resistant cell lines. Evidence is also presented suggesting that the association of the drug with enzyme-DNA intermediate complex and the formation of the enzyme-DNA complex alone both reflected equilibrium governed conditions that were readily reversible. These studies support a model based on the proposal that the actual cytotoxic events are genetic alterations caused by possible heterologous subunit exchanges occurring between adjacent enzyme molecules, which result from the stabilization of the intermediate complex, rather than the actual loss of topoisomerase II activity caused by the inhibition. The resistance of normal cells and cells with acquired resistance to the possible clastogenic effects of topoisomerase inhibition may be, in part, related to the low topoisomerase II levels found in such cells. Topoisomerase II may also play a role in gene amplification and tumor cell heterogeneity by serving as a vehicle through which genetic recombination events may occur.
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PMID:Inhibitors of topoisomerase II: structure-activity relationships and mechanism of action of podophyllin congeners. 285 48

Evidence suggests that the anticancer agents etoposide (VP16-213) and teniposide (VM26) produce DNA breaks and cytotoxicity by interaction with type II topoisomerase. Therefore, levels of type II topoisomerase may influence sensitivity to VP16-213 and VM26. We have characterized four lung carcinoma-derived cell lines for natural sensitivity or resistance to VP16-213 and VM26. Included in this study were two small cell lung carcinoma lines (SW900 and SW1271), an adenocarcinoma line (A549), and a large cell carcinoma (H157). SW1271 was the most sensitive line with a median inhibitory concentration for cell proliferation of 0.5 microM for VM26 and 2.7 microM for VP16-213, and SW900 was the most resistant with median inhibitory concentration values of 2.0 and 16 microM, respectively. A549 and H157 cells were intermediate in sensitivity to these drugs. Alkaline elution techniques were used to study in vivo formation and repair of single and double strand DNA breaks. Single strand DNA breaks were observed in SW1271 cells exposed to as little as 10 nM VM26 or 100 nM VP16-213 for 1 h, whereas SW900 cells required exposure to 10-fold higher concentrations of VM26 or VP16-213 to produce similar results. Single strand DNA breaks predominated only in SW1271 and A549 cells and then, only at low drug concentrations, whereas the ratios between single and double strand DNA breaks decreased at higher drug concentrations. Plots of cytotoxicity versus single and double strand DNA breakage revealed that cytotoxicity produced by both drugs was more closely related to double strand DNA break formation in all four cell lines. DNA breaks appeared rapidly upon addition of drug, reaching plateaus in DNA breaks within 30 min, and repair of both single and double strand DNA breaks occurred rapidly with time to repair one-half of the DNA breaks of 20 to 60 min in all four cell lines upon removal of drug, arguing against repair as a mechanism for drug resistance. DNA breakage was also observed in nuclei isolated from SW900 and SW1271 cells in similar magnitude to that observed in the respective cells. Results indicate that DNA breakage plateaus may reflect a steady-state equilibrium established between the drug and its nuclear target, possibly type II topoisomerase, and suggest that natural resistance to VP16-213 and VM26 may be due to different enzyme levels in sensitive and naturally resistant cells.
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PMID:DNA breakage in human lung carcinoma cells and nuclei that are naturally sensitive or resistant to etoposide and teniposide. 301 77

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