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:5.99.1.3 (topoisomerase)
9,911 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Using reverse transcription polymerase chain reaction, we determined mRNA expression of topoisomerase (topo) II alpha and beta in adriamycin- and etoposide-resistant small cell lung cancer sublines, SBC-3/ADM 100 and SBC-3/ETP. The expression of topo II alpha mRNA decreased substantially in SBC-3/ADM 100 and SBC-3/ETP as compared with the parent cell line, SBC-3; 0.71-fold in the former and 0.38-fold in the latter. Similarly, that of topo II beta mRNA decreased to an extent of 0.68-fold in SBC-3/ADM 100 and 0.28-fold in SBC-3/ETP as compared with the parent cell line. SBC-3/ADM 100 and SBC-3/ETP were highly resistant to topo II inhibitors such as daunorubicin, epirubicin, pirarubicin, mitoxantrone, and teniposide. However, SBC-3/ADM 100 showed a less resistance to aclarubicin, and SBC-3/ETP was as sensitive to the drug as was in the parent cell line. The resistance to topo II inhibitors excluding for aclarubicin might be partially explained by the decreased expression of topo II alpha and beta mRNA.
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PMID:[Cytotoxic effect of topoisomerase II inhibitors against adriamycin- and etoposide-resistant small cell lung cancer sublines]. 838 62

Reverse transcription-PCR-single-strand conformation polymorphism analysis was performed to detect topoisomerase IIalpha mutations using total RNA from 19 bronchial biopsy specimens obtained from 13 patients with small cell lung cancer. An abnormally migrating single-strand conformation polymorphism band was observed in one tumor sample from a patient treated with etoposide-containing chemotherapy. DNA sequence analysis of this tumor showed two transversions at codons 486 (G to A) and 494 (A to G), resulting in two missense mutations (Arg to Lys and Glu to Gly, respectively). The codon 486 mutation was identical to that previously found in two cell lines selected for amsacrine resistance. These results demonstrate that mutations of topoisomerase IIalpha occur in patients with small cell lung cancer. The significance of these mutations in the development of resistance to etoposide needs further investigation.
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PMID:Point mutations of the topoisomerase IIalpha gene in patients with small cell lung cancer treated with etoposide. 864 Aug 4

The complex catalytic cycle of topoisomerase II is the target of important antitumor agents. Topoisomerase II poisons, such as etoposide and daunorubicin, inhibit the resealing of DNA breaks created by the enzyme. This enzyme-coupled cell kill is susceptible to pharmacological regulation by drugs interfering with other steps in the enzyme's catalytic cycle (i.e. so-called catalytic inhibitors). From in vitro studies, is appears that there are 2 distinct sites in the cycle at which a complete antagonism of the toxicity of topoisomerase II poisons can be obtained. The first is the inhibition of the enzyme's binding to its DNA substrate as seen with intercalating drugs such as chloroquine and aclarubicin; a second, more specific, interaction is elicited by bisdioxopiperazines, which are thought to lock the homodimeric topoisomerase II in the form of a closed bracelet surrounding the DNA at the postreligation step. To investigate these in vitro findings in the more complex whole cell system, we studied enzyme-DNA binding in Western blots of 0.35 M NaCL nuclear extracts from human small cell lung cancer OC-NYH cells incubated with the bisdioxopiperazine ICRF-187 and aclarubicin. With ICRF-187, we found a reversible ATP dependent decrease in the extractable levels of both the alpha and the beta isoforms of topoisomerase II. In contrast to ICRF-187, aclarubicin increased the amount of extractable enzyme from cells. Further, when using the terpenoid clerocidin, which differs from conventional topoisomerase II poisons by forming a salt-and heat-stable inhibition of DNA resealing, no antagonism was found by ICRF-187 on formation of DNA strand breaks and cytotoxicity. However, aclarubicin, which interferes early in the topoisomerase II catalytic cycle, was able to antagonize DNA breaks and cytotoxicity caused by clerocidin. The results indicate 4 different steps in the topoisomerase II cycle that can be uncoupled in the cell by different drug types: etoposide and clerocidin cause reversible and irreversible inhibition of DNA resealing, respectively, and DNA intercalating agents, such as aclarubicin, inhibit binding of topoisomerase II enzyme to its DNA substrate. Finally, bisdioxopiperazines as ICRF-187 partake in an energy dependent inappropriate binding of topoisomerase II to DNA after the resealing step. This knowledge may enable the design of rational combinations of topoisomerase II poisons and catalytic inhibitors to enhance the efficacy of anticancer therapy.
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PMID:Mapping of DNA topoisomerase II poisons (etoposide, clerocidin) and catalytic inhibitors (aclarubicin, ICRF-187) to four distinct steps in the topoisomerase II catalytic cycle. 865 36

Expression of v-ras(H) in NCI-H82 human small cell lung cancer (SCLC) cells results in a line (NCI-H82ras(H)) with a non-small cell phenotype (Mabry et al., Proc Natl Acad Sci USA 85: 6523-6527, 1988). This v-ras(H) -associated phenotypic change is prevented by treatment with trans-retinoic acid (tRA) (Kalemkarian et al., Cell Growth Differ 5: 55-60, 1994). The present studies were performed to examine changes in drug sensitivity that accompanied these phenotypic changes. v-ras(H) expression was associated with increased metallothionein-IIa (MT-IIa) mRNA and decreased levels of nonprotein sulfhydryls in NCI-H82ras(H) cells compared with -H82 cells. These changes were accompanied by the development of CdCl2 resistance without any change in cisplatin sensitivity. In contrast, growth of parental NCI-H82 cells in 1 microM tRa resulted in increased MT-IIa mRNA without any change in nonprotein sulfhydryls. In these cells, a 3.3-fold increase in cisplatin IC50 was observed. Examination of the action of topoisomerase (topo) poisons revealed that NCI-H82 and -H82ras(H) cells had indistinguishable levels of topo II polypeptides and indistinguishable sensitivities to etoposide, an agent that is often combined with cisplatin clinically. On the other hand, v-ras(H) expression was accompanied by a 2-fold increase in topo I activity and a 1.7-fold decrease in IC50 for the topo I-directed agent camptothecin. These changes resulted in 30-fold lower survival of NCI-H82ras(H) cells compared with -H82 cells at camptothecin concentrations as low as 10 nM. In summary, these studies demonstrate that chronic tRA treatment is accompanied by decreased cisplatin sensitivity in NCI-H82 human SCLC cells. In contrast, v-ras(H) expression is not associated with any change in cisplatin or etoposide sensitivity, but is accompanied by increased camptothecin sensitivity.
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PMID:Effect of v-rasH on sensitivity of NCI-H82 human small cell lung cancer cells to cisplatin, etoposide, and camptothecin. 884 24

Cell lines, LC-5 and LC-172, were established from tumors of a small cell lung cancer patient prior to and after combination chemotherapy including etoposide (VP-16), when drug-resistant tumors developed in relapse. A VP-16-resistant cell line, LC-172/VP, was selected from the LC-172 cells in culture in multiple steps with VP-16. LC-172 cells were 3.5-fold resistant to VP-16 in growth inhibition, and 3.3-fold resistant to adriamycin as compared with LC-5 cells. LC-172/VP cells showed large differences in cross-resistance to topoisomerase II-targeting drugs such as VP-16, 200-fold, adriamycin, 10-fold, and MST-16, 4.3-fold; the cells were moderately refractory, 5.5-fold, to vincristine. VP-16 accumulation in the cells was similar in three cell lines. Topoisomerase II unknotting activity was reduced 7- to 10-fold in LC-172/VP and 1.5- to 2-fold in LC-172 cells compared with LC-5 cells, while relaxing activity of topoisomerase I appeared to be unchanged. Topoisomerase II protein was also reduced 5- to 10-fold in LC-172/VP and marginally so in LC-172 cells. Topoisomerase II alpha and II beta were each reduced 10-fold and 2-fold, respectively, in LC-172/VP cells, while they were both slightly decreased (-1.5-fold), respectively, in LC-172 cells compared with LC-5 cells. No apparent alteration in ATP requirement for catalytic activity and in sensitivity to VP-16 was observed for topoisomerase II from the three cell lines. Taken together, these results suggested that resistance to VP-16 in LC-172 and LC-172/VP is associated with a quantitative reduction in expression of topoisomerase II alpha of the parental type.
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PMID:Reduced expression of DNA topoisomerase II confers resistance to etoposide (VP-16) in small cell lung cancer cell lines established from a refractory tumor of a patient and by in vitro selection. 889 98

We have established an Adriamycin (ADM)-resistant small cell lung cancer (SCLC) cell line, SBC-3/ADM 100, which shows multifactorial mechanisms of resistance to ADM, such as over-expression of P-glycoprotein, an enhanced detoxifying system and a decrease in topoisomerase II activity. In the present study, we confirmed that SBC-3/ADM 100 showed collateral sensitivity to methotrexate and TNP-351, a new antifolate, though this cell line showed a typical multidrug resistance (MDR) pattern. We also demonstrated a faster uptake and higher accumulation (1.3-fold) of TNP-351 in the SBC-3/ADM 100 cells than those in the parent SBC-3 cells. These results explain one of the mechanisms for collateral sensitivity in the resistant cells. Furthermore, this cell line was found to have no cross-resistance to edatrexate and minimal cross-resistance to trimetrexate, 254-S (cisplatin analog), 5-fluorouacil and 4-hydroperoxyifosfamide. These drugs will have clinical importance in patients with SCLC who were previously treated with an ADM-containing regimen. Thus, antifolates, especially TNP-351 and edatrexate, can be expected to eradicate residual multidrug resistant SCLC cells selected by ADM.
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PMID:Growth inhibitory effects of antifolates against an adriamycin-resistant human small cell lung cancer cell line. 922 90

Etoposide, a topoisomerase II inhibitor, is a chemotherapeutic agent that is used in the treatment of a wide variety of neoplasms, including small cell lung cancer, germ cell cancer, testicular cancer, acute leukemia, and lymphoma. Although it has proven valuable, etoposide is also a known mutagen and has been implicated as a causative agent of treatment-related secondary acute nonlymphocytic leukemia. We have investigated the induction of mutation following etoposide treatment in vivo using the hypoxanthine phosphoribosyltransferase (hprt) T-cell cloning assay in small cell lung cancer patients receiving single-drug etoposide chemotherapy. This report presents results on the monitoring of 12 patients (mean age, 74.8 +/- 6.0 years; range, 66-83 years) before, during, and after chemotherapy. The treatment regimen included up to six cycles of oral etoposide given in twice-daily 50-mg tablets for 10-14 days, separated by 2 weeks of rest. Peripheral blood samples were collected on the first day of each cycle prior to treatment. Patients received one to six etoposide cycles and were followed for 0.7-5.3 months after the start of chemotherapy (total etoposide dose, 1.4-8.4 g). Results from the pooled data show no significant increase in the hprt mutant frequency (pretreatment, 46 x 10(-6) +/- 38 x 10(-6), versus posttreatment, 55 x 10(-6) +/- 46 x 10(-6)), although considerable interpatient variability was observed. Of a total of 424 selected mutants, 228 were analyzed by sequencing hprt cDNA. Spectra of 56 pretreatment and 147 posttreatment mutations revealed significant enhancement of AT-->TA transversions and a concomitant decrease in the number of GC-->TA transversions in posttreatment spectra, when they were compared with pretreatment or control spectra. No evidence for the induction of gross deletions or rearrangements was found in the spectra of mutants that were recovered from patients after etoposide treatment. The lack of enhanced mutant frequency after treatment suggests that the etoposide chemotherapy was not particularly effective in inducing mutation, as measured by the hprt assay. It is proposed that mutated cells are eliminated through apoptosis due to accumulated DNA damage.
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PMID:Mutation frequency and spectrum in lymphocytes of small cell lung cancer patients receiving etoposide chemotherapy. 933 Nov 3

The human small cell lung cancer NCI-H69 cell line selected for resistance to etoposide (H69/VP) has been reported previously to sequentially overexpress both the MRP and MDR1 multidrug resistance-conferring genes. In addition, immunocytochemistry of H69/VP cells demonstrated a distinct extranuclear localization of the nuclear enzyme topoisomerase IIalpha, the target of etoposide. Immunoblots showed a decrease in Mr 170,000 topoisomerase IIalpha in nuclear extracts in H69/VP but equal amounts of the enzyme in whole-cell extracts. Topoisomerase II catalytic activities in H69 and H69/VP whole-cell extracts were equal, as were their inhibition by etoposide. Sequencing of the entire H69/VP topoisomerase IIalpha cDNA showed a homozygous 9-nucleotide deletion encompassing nucleotides 4468-76, coding for Lys-Ser-Lys, overlapping two potential bipartite nuclear localization signals. The deletion occurred at the initial nine nucleotides of an exon, suggesting alternative splicing of topoisomerase IIalpha mRNA. Subsequent sequencing of H69/VP genomic DNA revealed a G-->T point mutation in the 3' acceptor splice site consensus sequence, resulting in the use of an alternate splice site. Comparison with previous reports on three drug-resistant cell lines with large truncations/deletions in the COOH-terminal region of topoisomerase IIalpha and extranuclear localization point to a pivotal role for the basic cluster 1490Lys-Ser-Lys1492 in the nuclear import of this enzyme.
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PMID:Loss of amino acids 1490Lys-Ser-Lys1492 in the COOH-terminal region of topoisomerase IIalpha in human small cell lung cancer cells selected for resistance to etoposide results in an extranuclear enzyme localization. 937 50

DNA topoisomerase II (Topo II) inhibitors are widely used in lung cancer chemotherapy, but small cell lung cancer (SCLC) and non-small cell lung cancer (NSCLC) show different sensitivity to them. In this study, we examined the gene expression levels of both isoforms of Topo II (II alpha and II beta) in lung cancer specimens to investigate the differential expression between SCLC and NSCLC. The expression levels of the Topo II alpha and Topo II beta genes were assessed in 80 autopsy samples (40 primary tumors and 40 corresponding normal lung tissues) by using the reverse transcription polymerase chain reaction. We found that the expression levels of the Topo II alpha gene in tumors were significantly higher than those in normal lung tissues, and that those in SCLC were significantly higher than those in NSCLC. There were no significant differences in Topo II beta gene expression between tumors and normal lung tissues and between SCLC and NSCLC. Further-more, correlation analysis revealed that Topo II alpha expression was correlated with Topo II beta expression in both tumor and normal lung tissues. These results indicate that a difference exists in the regulation of the Topo II gene between lung tumors and normal lung tissues. Our finding of differential expression of Topo II alpha between SCLC and NSCLC also suggests that the Topo II alpha expression level is associated with sensitivity to Topo II inhibitors.
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PMID:Differential expression of DNA topoisomerase II alpha and II beta genes between small cell and non-small cell lung cancer. 976 23

Combined modality therapy for lung cancer was first demonstrated to be successful in limited-stage small cell lung cancer. Concurrent administration of chemotherapy with chest and elective brain irradiation appears to produce the best results, with cisplatin/etoposide as the core chemotherapy. Using such programs, 2-year survival in the 40% range and 5-year survivals in excess of 20% may be expected, based on the results of multiple studies. Attempts to improve on these results through the use of altered schemes of chest irradiation or the delivery of high-dose consolidation chemotherapy are ongoing but to date have not been shown to affect survival significantly. We remain at a plateau in the effectiveness of combined modality therapy for small cell lung cancer, with little evidence that it impacts survival at all in extensive-stage disease. The incorporation of new agents in combination chemotherapy regimens, more "specific" immunotherapy directed at tumor-associated antigens, and the potential adjunctive use of broad-spectrum neuropeptide antagonists offer promise for the future. In non-small cell lung cancer, the sequential use of platinum-based chemotherapy and chest irradiation appears superior in survival to standard, daily fractionated radiation therapy used alone, with long-term survival increased from 5-10% to 15-20%. Concurrent administration of chemotherapy with cisplatin/etoposide and chest irradiation produces 2-year survival in the range of 30%, about twice that would be expected for radiation therapy alone, but has not been compared to it in the setting of a randomized trial. Low-dose cisplatin on a daily basis has been combined as a "sensitizer" with chest irradiation, producing initial results that appeared encouraging. However, these have not been reproduced in subsequent, randomized trials. Another approach to combined modalities has been to give chemotherapy or chemotherapy/radiation therapy as induction, followed by surgical resection, with or without subsequent additional treatment. Most patients (80-85%) can be resected, with encouraging survival at 2 and 3 years in the Southwest Oncology Group experience (37 and 26%, respectively). However, toxicity is greater, and such an approach is associated with an overall mortality risk in the range of 10%. A current intergroup study attempts to define the role of surgery in this setting. The major recent development that is likely to influence the future of combined modality therapy for this disease is the advent of multiple new chemotherapeutic agents, such as the taxanes, gemcitabine, vinorelbine, and the topoisomerase-I inhibitors, which have activity in stage IV disease. The immediate challenge is how to combine these agents with platinum analogues, radiation, and surgery. Aiding this process may be the use of molecular biological "markers" that may predict the chance of success or failure with a given systemic agent. The next decade is likely to see substantial improvements in the outcome of treatment for patients with stages I-III non-small cell lung cancer, based on the systemic exploration of combined modalities.
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PMID:Combined modality therapy of lung cancer. 1006 67


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