Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

We report alkaline elution experiments that reveal the temperature dependence of DNA lesions, both single-strand breaks and DNA-protein cross-links, in L1210 cells exposed to Adriamycin. DNA damage, which at 37 degrees C is equivalent to several hundred rads of ionizing radiation exposure, diminishes as the temperature of drug exposure is lowered. At all temperatures below about 15 degrees C no DNA damage is detectable in L1210 cells exposed to Adriamycin, even at relatively high doses. The low temperature inactivity is not due to a redistribution of intracellular drug since at both 37 and 0 degrees C there is a high concentration of Adriamycin in both nuclear and cytoplasmic locations. The temperature profile for DNA damage parallels the profile for cytotoxicity, i.e., at low temperature, the drug is completely inactive as a cytotoxic agent (P. Lane, P. Vichi, D. L. Bain, and T. R. Tritton, Cancer Res., 47:4038-4042, 1987). Thus, DNA breaks and cell kill appear to be correlated with one another. However, when we examined DNA lesions in nuclei isolated from L1210 cells we found that the low temperature inability to sustain Adriamycin-induced single-strand breaks or DNA-protein cross-links was absent. In nuclei, then, the drug can provoke DNA damage at low temperature, while in whole cells it cannot. Topoisomerase II, an enzyme implicated in catalyzing DNA lesions in cells exposed to intercalating agents, retains its catalytic activity both to unknot P4 DNA at 0 degrees C, and to be induced by drug to alter the release of pBR322 supercoils, so a low temperature inactivation of this enzyme cannot explain the results. We propose that intact L1210 cells have a regulatory factor which controls DNA damage, possibly through topoisomerase II, but which is lost when nuclei are isolated.
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PMID:Temperature dependence of adriamycin-induced DNA damage in L1210 cells. 255 89

Previous studies have shown that DNA topoisomerase II enzyme activity and protein levels are reduced in cloned lines of Adriamycin-resistant P388 leukemia cells relative to drug-sensitive cells (Deffie et al., Cancer Res., 49: 58-62, 1989). The molecular basis of the reduced topoisomerase II levels in these resistant cells has been investigated. Northern blot analysis of total cellular RNA from drug-sensitive and -resistant cells using a 1.8-kilobase human topoisomerase II complementary DNA revealed the presence of two mRNA species: a 6.6-kilobase transcript that was strongly expressed in drug-sensitive cells but reduced 7- to 8-fold in resistant cells; and a 5.5-kilobase transcript detected only in drug-resistant cells. Southern blot analysis of genomic DNA digested with BamHI, StuI, or PvuII and probed with the 1.8-kilobase complementary DNA for human topoisomerase II showed that, in Adriamycin-resistant cells, there were two different alleles for topoisomerase II, one identical to the native allele but with a lower gene copy number than that found in sensitive cells, and a second allele containing a mutation present only in resistant cells. These findings suggest that the reduced levels of topo II protein in drug-resistant cells may be due to reduced amounts of the native 6.6-kilobase mRNA. The unique 5.5-kilobase mRNA in resistant cells may represent a shortened transcript of the mutated topoisomerase II allele.
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PMID:Evidence for a mutant allele of the gene for DNA topoisomerase II in adriamycin-resistant P388 murine leukemia cells. 255 55

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

10-[3-Diethylaminopropylamino]-6-methyl-5H-pyrido[3',4':4,5] pyrrolo[2,3-g]isoquinoline (PZE) is an ellipticine derivative currently in clinical trials. PZE has been postulated to produce cellular DNA lesions by an uncommon mechanism. PZE-induced DNA damage was further investigated in L1210 cells in culture. PZE was highly cytotoxic for these cells (90% inhibitory concentration = 3.1 microM). The effects of PZE on cellular DNA were studied first by alkaline sucrose sedimentation, in comparison with those of 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA). Like m-AMSA, PZE induced DNA strand breaks which were detected without a proteolytic treatment of the cell lysate. This result rules out the existence of covalent protein bridges sealing DNA termini at the break sites. PZE was less active than m-AMSA. DNA fragmentation was maximum at 5 microM and was lower at higher concentrations. The DNA effects of PZE were also studied by alkaline elution, and compared with those of Adriamycin and m-AMSA. Like Adriamycin, PZE induced single-strand breaks (SSBs) in a bell-shaped manner with respect to drug concentration. The maximum SSB frequency [1784 +/- 370 (SEM) rad equivalents)] was obtained at 16 microM. The kinetics of SSB reversion after drug removal was slower than in the case of m-AMSA. Similar bell-shaped curves were obtained for PZE-induced double-strand breaks and DNA-protein cross-links. PZE induced more double-strand breaks per SSB than did m-AMSA. However, as in the case of m-AMSA, PZE induced equal SSB and DNA-protein cross-link frequencies. These results suggest that PZE induces DNA breaks by inhibiting topoisomerase II as do other antitumor intercalators.
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PMID:Production of protein-associated DNA breaks by 10-[diethylaminopropylamino]-6-methyl-5H-pyrido[3',4':4,5]pyrrolo [2,3-g]isoquinoline in cultured L1210 cells and in isolated nuclei: comparison with other topoisomerase II inhibitors. 283 Sep 64

Pleotropic resistant human breast cancer cells (MCF-7), selected for resistance to Adriamycin, were used to study the production of DNA strand breaks by etoposide (VP-16) and its relationship to drug cytotoxicity. It was shown that the resistant MCF-7 cell line was cross-resistant to VP-16, and the degree of resistance was found to be 125-200-fold. Alkaline elution studies indicated that the parental cell line was very sensitive to VP-16 which caused extensive DNA strand breakage. In contrast, little DNA strand breakage was detected in the resistant MCF-7 cells, even at very high drug concentrations, indicating a good agreement between strand breaks and cytotoxicity. Further studies indicated that the nuclei isolated from the parental cell line were more resistant to VP-16-induced DNA strand breaks than the intact cells, while the opposite was found in the resistant cell line. In addition, the alkaline elution studies in isolated nuclei showed only a 2-fold reduction of VP-16-induced DNA breaks in nuclei from the resistant cells. In agreement with this result, it was found that nuclear extract from the resistant cells produced 2-3-fold less VP-16-induced DNA breaks than that from the sensitive cells in 32P-end-labeled SV40 DNA. VP-16 uptake and efflux studies indicated that there was a 2-3-fold decrease in net cellular accumulation of VP-16 in the resistant cells. Although the reduced uptake of VP-16 and decreased drug sensitivity of topoisomerase II appear to contribute to the mechanism of action and the development of resistance to VP-16, they do not completely explain the degree of resistance to VP-16 in this multidrug-resistant MCF-7 cell line indicating that other biochemical factors, such as activation of VP-16, are also involved in drug resistance and suggesting that the resistance is multifactorial.
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PMID:DNA strand breaks produced by etoposide (VP-16,213) in sensitive and resistant human breast tumor cells: implications for the mechanism of action. 284 45

DNA intercalating drugs and the epipodophyllotoxins etoposide and teniposide interfere with the action of mammalian DNA topoisomerase II by trapping an intermediate complex of the enzyme covalently linked to the 5'-termini of DNA breaks. This effect can be observed in intact cells by alkaline elution measurement of protein-associated DNA strand breaks. To assess the cytotoxic role of this effect, we have studied a subline of DC3F Chinese hamster lung cells selected for resistance to the intercalating agent 9-hydroxyellipticine. This subline (DC3F/9-OHE) was cross-resistant to other intercalators as well as to etoposide. Resistance to Adriamycin was associated with reduced uptake. However, resistance to 4'-(9-acridinylamino)methanesulfon-m-aniside and 2-methyl-9-hydroxyellipticinium was observed in the absence of changes in drug uptake, suggesting a second mode of resistance. DC3F/9-OHE cells formed fewer protein-associated DNA strand breaks in response to 4'-(9-acridinylamino)methanesulfon-m-aniside, 2-methyl-9-hydroxyellipticinium, or etoposide than did the sensitive parental cells. The same was true for isolated nuclei from these cells, which is consistent with a mode of resistance unrelated to drug uptake through the plasma membrane. These data suggest that resistance to DNA topoisomerase II inhibitors exhibited by DC3F/9-OHE cells is due in part to a modification of topoisomerase II activity.
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PMID:Reduced formation of protein-associated DNA strand breaks in Chinese hamster cells resistant to topoisomerase II inhibitors. 300 May 81

Several intercalating agents, as well as the epipodophyllotoxins, appear to effect DNA damage through their interaction with type II DNA topoisomerases. However, the relationship of this phenomenon to anti-tumor activity remains unproven. Our studies with an epipodophyllotoxin-resistant cell line not only provide additional evidence that the enzyme is a multidrug target but also serve to implicate it as a mediator of cytotoxic effect. When compared to wild-type cells, the epipodophyllotoxin-resistant Chinese hamster ovary cell line, VpmR-5, exhibits cross-resistance to both the cytotoxic and DNA cleavage activities of 4',9-acridinylaminomethanesulfon-m-anisidide, mitoxantrone, and Adriamycin. Steady-state concentrations of radiolabeled-4',9-acridinylaminomethanesulfon-m-anisidide and daunomycin are identical in both cell lines. Sharp plateaus in the VpmR-5 dose-response curves for Adriamycin-induced DNA strand breaks and cytotoxicity appear to be related to interference with type II topoisomerase-mediated cleavage of DNA at high concentrations of the intercalator. These data support a direct role for DNA strand scission in cell death and also suggest that multidrug resistance may be acquired by a qualitative change in type II topoisomerase that alters interaction of drug with the enzyme or enzyme-DNA complex.
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PMID:Cross-resistance to intercalating agents in an epipodophyllotoxin-resistant Chinese hamster ovary cell line: evidence for a common intracellular target. 300 12

I have found that antineoplastic drugs which are known to be inhibitors of mammalian DNA topoisomerases have pronounced and selective effects on simian virus 40 DNA replication. Ellipticine, 4'-(9-acridinylamino)methanesulfon-m-aniside, and Adriamycin blocked decatenation of newly replicated simian virus 40 daughter chromosomes in vivo. The arrested decatenation intermediates produced by these drugs contained single-strand DNA breaks. Ellipticine in particular produced these catenated dimers rapidly and efficiently. Removal of the drug resulted in rapid reversal of the block and completion of decatenation. The demonstration that these drugs interfere with decatenation suggests that they may exert their cytotoxic and antineoplastic effects by preventing the separation of newly replicated cellular chromosomes. Camptothecin rapidly breaks replication forks in growing Cairns structures. It is likely that the target of camptothecin is the "swivel" topoisomerase required for DNA replication and that it is located at or very near the replication fork in vivo. Evidence is presented that many of the broken Cairns structures are in fact half-completed sister chromatid exchanges. One pathway for the resolution of these structures is completion of the sister chromatid exchange to produce a circular head-to-tail dimer.
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PMID:Topoisomerase inhibitors can selectively interfere with different stages of simian virus 40 DNA replication. 302 45

In a human small cell lung carcinoma cell line, GLC4, Adriamycin (ADR) resistance was induced. In the resistant cell line, GLC4/ADR, a 45% decreased intracellular ADR level was found compared to GLC4, but this could not fully explain the resistance. Evaluation of DNA damage in both cell lines after incubation with ADR by alkaline and neutral elution revealed single-strand breaks, DNA-protein cross-links, and double-strand breaks (DSB). At all incubation concentrations there was a decreased amount of all types of DNA damage in GLC4/ADR. The number of DSB was decreased also when corrected for the decreased intracellular concentration. This can at least partly be explained by the decreased stability of ADR induced DSB. After removal of ADR, 80% of DSB was repaired in 1 h in GLC4/ADR against no repair in GLC4. X-ray induced DSBs were also repaired faster: in GLC4/ADR t1/2 = 10 min and in GLC4 t1/2 = 23 min. Ratios for single strand breaks/DSBs and single strand breaks/DNA-protein cross-links between GLC4 and GLC4/ADR after exposure to ADR differed; these differences were compatible with differences in the distribution of the various types of DNA damage induced in the cell lines due to an altered ADR-topoisomerase II interaction. In this human small cell lung carcinoma cell line the resistance is multifactorial with decreased intracellular ADR levels, increased DNA repair, and altered ADR-topoisomerase interaction.
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PMID:Multifactorial drug resistance in an adriamycin-resistant human small cell lung carcinoma cell line. 302 13

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


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