Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:5.99.1.3 (topoisomerase)
 9,911 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have produced metaphase spindles and induced them to enter anaphase in vitro. Sperm nuclei were added to frog egg extracts, allowed to replicate their DNA, and driven into metaphase by the addition of cytoplasm containing active maturation promoting factor (MPF) and cytostatic factor (CSF), an activity that stabilizes MPF. Addition of calcium induces the inactivation of MPF, sister chromatid separation and anaphase chromosome movement. DNA topoisomerase II inhibitors prevent chromosome segregation at anaphase, demonstrating that the chromatids are catenated at metaphase and that decatenation occurs at the start of anaphase. Topoisomerase II activity towards exogenous substrates does not increase at the metaphase to anaphase transition, showing that chromosome separation at anaphase is not triggered by a bulk activation of topoisomerase II.
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PMID:Sister chromatid separation in frog egg extracts requires DNA topoisomerase II activity during anaphase. 131 85

We have investigated the effect of 8-methoxycaffeine on the interaction between Drosophila DNA topoisomerase II and DNA. We have shown that 8-methoxycaffeine affected the enzyme strand-passing activity by inhibiting decatenation of kinetoplast DNA, and that it interfered with the breakage-reunion reaction by stabilizing a cleavable complex. Treatment of the cleavable complex with protein denaturant resulted in DNA breaks. High resolution mapping of the cleavage sites in the central spacer region of Tetrahymena rDNA revealed that, contrary to what was observed with clinically important DNA topoisomerase II inhibitors, 8-methoxycaffeine did not modify the cleavage pattern observed without the drug.
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PMID:8-methoxycaffeine inhibition of Drosophila DNA topoisomerase II. 131 70

The decatenation activity of DNA topoisomerase II is essential for viability as eukaryotic cells traverse mitosis. Phosphorylation has been shown to stimulate topoisomerase II activity in vitro. Here we show that topoisomerase II is a phosphoprotein in yeast and that the level of incorporated phosphate is significantly higher at mitosis than in G1. Comparison of tryptic phosphopeptide maps reveals that the major phosphorylation sites in vivo are targets for casein kinase II. Incorporation of phosphate into topoisomerase II is nearly undetectable at the non-permissive temperature in a conditional casein kinase II mutant. The sites modified by casein kinase II are located in the extreme C-terminal domain of topoisomerase II. This domain is absent in prokaryotic and highly divergent among eukaryotic type II topoisomerases, and may serve to regulate functions of topoisomerase II that are unique to eukaryotic cells.
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PMID:Casein kinase II phosphorylates the eukaryote-specific C-terminal domain of topoisomerase II in vivo. 131 74

Three camptothecin-resistant sublines (V79r, IRS-1r and IRS-2r) of V79 cells and their irradiation-sensitive mutants, IRS-1 and IRS-2, were developed by stepwise, continuous exposure to camptothecin (CPT). The degree of resistance varied among these cells. Based on the biochemical characterizations of these resistant cell lines, the mechanisms which could be responsible for the resistance to CPT were proposed to be: (a) a decrease in the intracellular accumulation of CPT with or without alteration of DNA topoisomerase I, (b) a decrease in the amount of DNA topoisomerase I, or (c) a decrease in the sensitivity of DNA topoisomerase I to CPT. The resistant cells which exhibited down-regulation of DNA topoisomerase I were collaterally sensitive to etoposide (VP-16) and its analogue, 4'-demethy-4 beta-(4"-fluoroanilino)-4-desoxypodophyllotoxin, despite the fact that there were equal amounts of DNA topoisomerase II in the parental and in the resistant cell lines. Alternating the usage of CPT and VP-16 for the treatment of cancer is indicated.
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PMID:Characterization of camptothecin-resistant Chinese hamster lung cells. 131 61

The antitumor drug fostriecin (phosphotrienin, FST) has been reported to exert its cytostatic and cytotoxic effects via inhibition of DNA topoisomerase II. The sensitivity of human lymphocytic leukemic MOLT-4 and promyelocytic HL-60 leukemic cells to a wide range of FST concentrations was studied by analyzing the cell cycle-specific effects and changes in nuclear chromatin induced by this inhibitor. The latter was evaluated by assaying the sensitivity of DNA in situ to acid-induced denaturation cytofluorimetrically, with the use of the metachromatic fluorochrome acridine orange (AO), which differentially stains double-stranded and denatured DNA. The cytostatic effects were observed soon after addition of FST (at concentrations of 1-30 microM for MOLT-4 cultures and 1-5 microM for HL-60 cultures) as a perturbation of cell progression through S and G2 phases of the cell cycle. Cell progression through the cycle was halted at greater than 30 microM FST in MOLT-4 cultures and at greater than 5 microM in HL-60 cultures; the effect was instantaneous and affected all phases of the cycle, so that no changes in the cell cycle distribution were apparent with increasing length of exposure to the drug. Instead, at these high FST concentrations, immediate cytotoxic effects became evident, manifesting either as cell apoptosis or necrosis. Apoptosis was observed only in the case of HL-60 cells, at FST concentrations of 5-100 microM, and was characterized by markedly increased sensitivity of DNA to denaturation combined with a decrease in overall DNA stainability, either with the DNA-specific dye DAPI or with AO, indicative of the activation of endogenous nucleases. Necrotic cell death was observed at FST concentrations of 1 mM and at greater than 30 microM for HL-60 and MOLT-4 cells, respectively: in both cases the overall DNA stainability, with either DAPI or AO, was unchanged compared to the control, but their DNA was very sensitive to denaturation. Interestingly, DNA in G2 and late S phase MOLT-4 cells, which were undergoing necrotic death, was much more sensitive to denaturation than was DNA in G1 cells of this lineage. The data indicate that chromatin changes induced by DNA topoisomerase II inhibitors in cells that undergo apoptotic or necrotic death can be conveniently monitored by the assay of DNA in situ sensitivity to denaturation.
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PMID:Changes in nuclear chromatin related to apoptosis or necrosis induced by the DNA topoisomerase II inhibitor fostriecin in MOLT-4 and HL-60 cells are revealed by altered DNA sensitivity to denaturation. 131 46

DNA topoisomerase II is an enzyme that affects nuclear structure and function and is the target of a number of anticancer drugs in clinical use, including teniposide (VM-26). We have used our polyclonal antisera that recognize both the M(r) 170,000 and 180,000 forms of topoisomerase II to examine the nuclear distribution of topoisomerase II in cytospin preparations of drug-sensitive (CEM) and VM-26-resistant (CEM/VM-1 and CEM/VM-1-5) human leukemic lymphoblasts. We have also examined the nuclear distribution of topoisomerase II in monolayer cultures of a human rhabdomyosarcoma (Rh30) cell line. In the absence of drug, we observed a focal "patchy" staining of nuclear topoisomerase II in all cell lines, that was especially notable in the lymphoblastic cells. Treatment of CEM and Rh30 cells with VM-26 under conditions that increase the number of covalent topoisomerase II-DNA complexes increased both the intensity and the homogeneity of nuclear topoisomerase II staining in a subpopulation of cells; focal staining was less evident after treatment with drug. These responses were roughly proportional to the concentration of VM-26 used and required only brief (approximately 25-min) incubation with drug. We also found that treatment of CEM cells with 4'-(9-acridinylamino)methanesulfon-m-anisidide similarly increased the intensity and homogeneity of nuclear topoisomerase II immunostaining. In contrast, 4'-(9-acridinylamino)methanesulfon-o-anisidide and 1-beta-D-arabinofuranosylcytosine, agents that do not inhibit topoisomerase II, did not produce this effect. Finally, the VM-26-mediated alteration in topoisomerase II staining intensity and distribution was attenuated in proportion to the degree of VM-26 resistance in the CEM/VM-1 and CEM/VM-1-5 sublines. These results appear to be related to the ability of the drug to stabilize DNA-topoisomerase covalent ("cleavable") complexes in intact cells. Our findings indicate that anti-topoisomerase II drugs, such as VM-26, have profound effects on the ability to detect topoisomerase II in the nucleus and provide a novel way of examining drug-stabilized DNA topoisomerase II complexes in intact single tumor cells.
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PMID:DNA topoisomerase II immunostaining in human leukemia and rhabdomyosarcoma cell lines and their responses to topoisomerase II inhibitors. 132 39

Increasing the cellular concentration of DNA topoisomerase II in yeast by expressing constitutively a plasmid-borne TOP2 gene encoding the enzyme greatly increases the sensitivity of the cells to amsacrine and etoposide (VP-16). This increased drug sensitivity at a higher intracellular DNA topoisomerase II level is observed in both RAD52+ repair-proficient strains and rad52 mutants that are defective in the repair of double-stranded breaks. These results provide strong support of the hypothesis that the cellular target of these drugs is DNA topoisomerase II, and that these drugs kill cells by converting DNA topoisomerase II into a DNA damaging agent.
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PMID:Amsacrine and etoposide hypersensitivity of yeast cells overexpressing DNA topoisomerase II. 132 91

In Escherichia coli, the miniF plasmid CcdB protein is responsible for cell death when its action is not prevented by polypeptide CcdA. We report the isolation, localization, sequencing and properties of a bacterial mutant resistant to the cytotoxic activity of the CcdB protein. This mutation is located in the gene encoding the A subunit of topoisomerase II and produces an Arg462----Cys substitution in the amino acid sequence of the GyrA polypeptide. Hence, the mutation was called gyrA462. We show that in the wild-type strain, the CcdB protein promotes plasmid linearization; in the gyrA462 strain, this double-stranded DNA cleavage is suppressed. This indicates that the CcdB protein is responsible for gyrase-mediated double-stranded DNA breakage. CcdB, in the absence of CcdA, induces the SOS pathway. SOS induction is a biological response to DNA-damaging agents. We show that the gyrA462 mutation suppresses this SOS activation, indicating that SOS induction is a consequence of DNA damages promoted by the CcdB protein on gyrase-DNA complexes. In addition, we observe that the CcdBS sensitive phenotype dominates over the resistant phenotype. This is better explained by the conversion, in gyrA+/gyrA462 merodiploid strains, of the wild-type gyrase into a DNA-damaging agent. These results strongly suggest that the CcdB protein, like quinolone antibiotics and a variety of antitumoral drugs, is a DNA topoisomerase II poison. This is the first proteinic poison-antipoison mechanism that has been found to act via the DNA topoisomerase II.
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PMID:Cell killing by the F plasmid CcdB protein involves poisoning of DNA-topoisomerase II complexes. 132 24

The clinical phenotype of Werner's syndrome (WS) includes short stature, premature cataracts, skin atrophy, osteoporosis, graying and loss of hair, neoplasia, diabetes mellitus, and arteriosclerosis. Cultured cells from patients with this autosomal recessive disorder exhibit chromosomal instability and a markedly reduced replicative lifespan and growth rate. To elucidate the cell cycle alterations associated with the growth deficit, we continuously labeled lymphoid cell lines from five WS patients and from four healthy adult controls with 5-bromodeoxyuridine. Bivariate Hoechst 33258/ethidium bromide flow cytometry revealed a 2.4-h prolongation in the minimal duration of the S phase of WS cells (P less than 0.005). Moreover, the fraction of proliferating cells irreversibly arrested in the S phase (5.4% vs 1.4% in controls) was significantly elevated in WS (P less than 0.001). Other cell cycle compartments were not significantly affected in WS cell lines. As a partial test of the hypothesis that the WS phenotype is due to a defect in DNA topoisomerase I (topo I) or DNA topoisomerase II (topo II) we exposed lymphoid cells from a healthy control to the topo I inhibitor camptothecin or to the topo II inhibitor 4'-(9-acridinylamino)methanesulfon-m-anisidine. The cell kinetic alterations elicited by these compounds differed from that exhibited by untreated WS patients. Thus, a primary defect in topo I or II is unlikely in WS. Our cell cycle results, however, provide important evidence that the biochemical genetic lesion is in fact expressed in lymphoblastoid cell lines, the most readily available cells from such subjects.
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PMID:Impaired S-phase transit of Werner syndrome cells expressed in lymphoblastoid cell lines. 132 51

Genistein (GEN) is an isoflavone known to inhibit both tyrosine protein kinases and DNA topoisomerase II. The effects of GEN on cell proliferation and cell cycle kinetics of human myelogenous leukemia HL-60 and lymphocytic leukemia MOLT-4 cell cultures were studied, and the data were compared to results obtained with normal human lymphocytes stimulated to proliferate with phytohemagglutinin. GEN concentrations greater than 50 micrograms/ml (185 microM) were cytotoxic to HL-60 and MOLT-4 cells following exposure for 24 h; in HL-60 cell cultures, a population of cells with decreased DNA content and nuclear fragmentation characteristic of apoptosis was observed within 8 h. The 50% inhibition concentration after 24 h of exposure for HL-60 and MOLT-4 cells was 8.5 and 13.0 micrograms/ml, respectively. Normal proliferating lymphocytes survived a 24-h exposure of up to 200 micrograms/ml GEN. Short-term (4-8 h) exposures of MOLT-4 or HL-60 cells to 5-20 micrograms/ml GEN resulted in a suppression of cell progression through S or through both S and G2 phases, respectively, while equivalent treatment had no effect on proliferating lymphocytes. A stathmokinetic experiment using MOLT-4 cells revealed that as little as 5 micrograms/ml GEN suppressed cell exit from S to G2 phase by 40%, with a terminal point of action at or near the S-G2 border. Cell progression through the very early portion of G1 phase (G1A, characterized by postmitotic chromatin decondensation) was also suppressed by approximately 40%, whereas cell advancement through the remainder of the G1 phase was not markedly affected. Longer (24 h) exposure of proliferating lymphocytes to 20 micrograms/ml GEN led to an S-phase arrest, while similar treatment of leukemic cells caused cell arrest in G2 phase and an increase in the number of cells entering the cycle at higher DNA ploidy. The mitogen-induced transition of lymphocytes from G0 to G1 phase was extremely sensitive to inhibition by GEN; the 50% inhibition concentration was 1.6 micrograms/ml. The chemotherapeutic value of GEN may be due to the fact that, in terms of cytotoxicity, this agent is more active against proliferating leukemic cells than against normal proliferating lymphocytes. The sensitivity of the G0 to G1 transition in normal lymphocyte cultures and the suppressive effect of GEN on the G1A exit in MOLT-4 cells both suggest that protein kinases involved in chromatin decondensation may be a target of this drug. In light of the observation that lymphocyte stimulation is sensitive to the presence of GEN, the drug is expected to be a strong immunosuppressant.
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PMID:Effects of genistein on the growth and cell cycle progression of normal human lymphocytes and human leukemic MOLT-4 and HL-60 cells. 133 Feb 89


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