Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:5.99.1.2 (topoisomerase)
 9,166 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Chronic lymphocytic leukaemia (CLL) is a progressive disease, commonly treated in its early stage with alkylating agents. A multi-agent regimen which includes anthracyclines is used to treat advanced disease. Despite chemotherapy, the disease remains incurable. There is now considerable evidence to suggest that anthracyclines exert their effect via the nuclear enzyme topoisomerase II and that alterations in amount or activity of this enzyme may mediate drug resistance. We have investigated topoisomerase II mRNA expression in 34 CLL patients and in haemopoietic cells from 10 normal donors. Expression was found to be low but detectable in all patients and normals. Such low levels may contribute to the toxicity of alkylating agents, but could severely limit the effect of anthracyclines.
Leukemia 1993 Aug
PMID:Topoisomerase II expression in normal haemopoietic cells and chronic lymphocytic leukaemia: drug sensitivity or resistance? 839 82

A new flow cytometric method is described to detect DNA strand breaks associated with apoptosis, by labeling the 3'-OH termini in the breaks with biotinylated dUTP in a reaction employing exogenous terminal deoxynucleotidyl transferase. The method has been applied in studies on leukemic HL-60 and MOLT-4 cell lines to reveal whether it is specific to apoptotic cells, and whether it can be used in the clinic to detect DNA breakage in leukemic cells during chemotherapy. There was labeling of mononuclear cells in peripheral blood of all 11 patients studied during chemotherapy for acute lymphoblastic, acute myelogenous, or chronic myelogenous leukemia (ALL, AML, or CML) in blastic crisis, indicating induced DNA damage; the number of labeled cells increased from 1-8% before treatment up to 80% during the course of treatment. The DNA topoisomerase inhibitors mitoxantrone, VP-16 (etoposide), and m-AMSA (amsacrine) were more effective in inducing DNA breaks than was hydroxyurea or cytosine arabinoside (AraC). Cells with DNA breaks were identified in peripheral blood for up to 5 days following administration of Mitoxantrone and VP-16. In the case of DNA aneuploid leukemias, the DNA breaks were predominant in the aneuploid cell subpopulations, whereas presumably non-neoplastic diploid cells were unlabeled. In one case of ALL there were two distinct subpopulations of aneuploid cells: one responded to the treatment (by DNA breakage) and the other was non-responding. Thus, cells undergoing apoptosis can be detected by this method of labeling DNA strand breaks and the technique is applicable for analysis of response of leukemic cells to chemotherapy. With this method it may be possible to identify tumor cell sensitivity or resistance to particular drugs early in the course of treatment.
Leukemia 1993 May
PMID:Induction of DNA strand breaks associated with apoptosis during treatment of leukemias. 848 18

The National Cancer Institute (NCI) recently alerted clinicians to the possibility that patients, entered on a NCI-sponsored cooperative group trial of doxorubicin and cyclophosphamide adjuvant therapy for breast cancer, may be at high risk of developing secondary acute myeloid leukemia (AML). Secondary AML following standard doses of doxorubicin and cyclophosphamide is uncommon, suggesting that the high risk on this trial may result from its higher-than-standard doses of chemotherapy. However, the cases of secondary AML were characteristic of the type that follows treatment with topoisomerase II-active agents, especially etoposide, and this type of secondary AML is rare after treatment with either cyclophosphamide or doxorubicin at any dose. We raise the possibility that another component of this trial, hematopoietic growth factors to decrease the toxicities related to myelosuppression, may play an important role in the development of secondary AML. Growth factors not only stimulate hematopoietic progenitor proliferation and differentiation, they also regulate hematopoietic cell survival by interfering with apoptosis (programmed cell death). Inhibition of apoptosis by a variety of genetic factors is an important mechanism of oncogenesis, and appears to be the initiating event in some malignancies. Growth factor-mediated suppression of the apoptotic death of hematopoietic progenitors damaged by chemotherapy may contribute to their leukemic transformation.
Leukemia 1996 Jan
PMID:Are growth factors leukemogenic? 855 25

Only two classes of chemotherapeutic agents have shown activity in acute myeloid leukemia (AML): ara-C and topoisomerase II reactive agents. Frontline combinations of these agents produce complete response (CR) rates of 70% and long-term event free survival rates of 25%. New agents with different mechanisms of action are being explored. Nucleoside analogs such as chlorodeoxyadenosine (2-CdA) or fludarabine have shown single-agent efficacy and may be synergistic with ara-C. Combination therapy with ara-C and nucleoside analogs have shown promising results both as salvage therapy and in newly diagnosed patients. Combinations of topotecan with ara-C, VP16, and anthracyclines are being pursued, as is testing of other Topo-I inhibitors. Hypomethylating agents (5-azacytidine, decitabine) are showing activity in AML, producing CR rates of 5% to 30% as AML salvage therapy as a single agent, and 40%-60% in combinations. Decitabine may be synergistic with topo I inhibitors, biologic agents, and differentiating agents. Homoharringtonine has modest anti-AML activity, with CR rates of 10% to 30% as salvage therapy. Other classes of agents worthy of continuing investigation are platinum analogs and agents with novel mechanisms of action such as tallimustine.
Leukemia 1996 Apr
PMID:New chemotherapeutic agents in acute myeloid leukemia. 861 70

Gene expression was analyzed by cDNA-PCR at the mRNA level in bone marrow samples (>80% blasts) from ALL (28 primary, 22 first relapses, 10 recurrent relapses), from AML (14 primary, 23 relapses), In peripheral blood lymphocytes from CLL (five untreated, 10 treated), in one CML in blast crisis in the course of the disease (four samples), and in bone marrow samples from healthy donors (12 specimens). We found low mean MDR1 expression in primary ALL, first relapses of ALL, and primary AML. Significantly higher mean relative MDR1 expression levels were seen in recurrent relapses of ALL, and in the group of relapsed state AML. MDR1 expression measured intermediate in bone marrow samples from healthy donors. The CLL lymphocytes showed generally relatively high MDR1 expression levels. MRP gene expression measured very similar in primary ALL, first relapses of ALL, primary AML, and normal bone marrow. Significantly increased MRP mRNA levels were observed in the groups of recurrent ALL and relapsed state AML. CLL lymphocytes also showed high MRP expression levels. A combined increase of MDRI (about 20-fold) and MRP (about four-fold) was monitored in samples obtained from the CML in blast crisis after chemotherapy. While no significant differences of the mean topoisomerase IIbeta mRNA levels were found throughout, a significantly decreased topoisomerase IIalpha gene expression was measured in first and recurrent relapses of ALL. In CLL lymphocytes either the expression of the topoisomerase IIalpha gene was not detectable by cDNA-PCR, or it measured very low. Topoisomerase IIalpha gene expression was correlated to cyclin A gene expression in the samples of acute leukemias, Indicating the link of topoisomerase IIalpha expression to the proliferative activity of these leukemic blast cells. Our results point to a potentially multifactorial emergence of multidrug resistance in particular states and types of leukemias.
Leukemia 1996 Jul
PMID:MDR1, MRP, topoisomerase IIalpha/beta, and cyclin A gene expression in acute and chronic leukemias. 865 99

We have developed a method to quantify topoisomerase (topo) II activities in partially purified nuclear extracts from human leukemia cells. By virtue of their different pH optima in the reaction buffer, two different topo II activities were found with activity optima at pH 7.9 and at pH 8.9 under high stringency conditions. The activities could be identified as topo II beta activity (pH 7.9) and topo II alpha activity (pH 8.9) by their different sensitivities to topo II alpha inhibitors, dephosphorylation experiments and immunoprecipitation with polyclonal antibodies. Seventy-two bone marrow or blood samples from patients with acute myeloid leukemias have been examined and their in vitro sensitivities to anthracyclines and epipodophyllotoxines correlated to the activities of topo II alpha and topo II beta. Although the topo II alpha activity could be directly inhibited by incubation of the cells with the mentioned drugs, no correlation between the topo II alpha activity and the sensitivity of the cells could be found. In contrast, the topo II beta activity which was not substantially inhibited by the drugs inversely correlated with the sensitivity of the cells. These findings were statistically significant for idarubicin (P=0.017) and daunorubicin (P=0.006). Vice versa, resistant cells (IC90 > median) had a higher topo II beta activity. Clinical relevance might be indicated by the finding that cells from patients that relapsed after initial treatment with anthracyclin-containing regiments had a significantly higher topo II alpha/beta activity ratio (P=0.0276). Obviously, the sensitivity of AML cells is substantially influenced by the activity of the resistant topo II (topo II beta) which gives evidence that the remaining topo II activity after treatment helps the cell to survive the DNA repair phase.
Leukemia 1996 Jul
PMID:Topoisomerase II activities in AML blasts and their correlation with cellular sensitivity to anthracyclines and epipodophyllotoxines. 865

We have developed a method to quantify topoisomerase (topo) II activities in partially purified nuclear extracts from human leukemia cells. By virtue of their different pH optima in the reaction buffer, two different topo II activities were found with activity optima at pH 7.9 and at pH 8.9 under high stringency conditions. The activities could be identified as topo II beta activity (pH 7.9) and topo II alpha activity (pH 8.9) by their different sensitivities to topo II alpha inhibitors, dephosphorylation experiments and immunoprecipitation with polyclonal antibodies. Seventy-two bone marrow or blood samples from patients with acute myeloid leukemias have been examined and their in vitro sensitivities to anthracyclines and epipodophyllotoxines correlated to the activities of topo II alpha and topo II beta. Although the topo II alpha activity could be directly inhibited by incubation of the cells with the mentioned drugs, no correlation between the topo II alpha activity and the sensitivity of the cells could be found. In contrast, the topo II beta activity which was not substantially inhibited by the drugs inversely correlated with the sensitivity of the cells. These findings were statistically significant for idarubicin (P= 0.017) and daunorubicin (P = 0.006). Vice versa, resistant cells (IC50 > median) had a higher topo II beta activity. Clinical relevance might be indicated by the finding that cells from patients that relapsed after initial treatment with anthracyclin-containing regiments had a significantly higher topo II alpha/beta activity ratio (P=0.0276). Obviously, the sensitivity of AML cells is substantially influenced by the activity of the resistant topo II (topo II beta) which gives evidence that the remaining topo II activity after treatment helps the cell to survive the DNA repair phase.
Leukemia 1996 Jul
PMID:Topoisomerase II activities in AML and their correlation with cellular sensitivity to anthracyclines and epipodophyllotoxines. 868 99

Peripheral blood samples from 18 patients with chronic lymphocytic leukemias (CLL) who were either untreated but who were later sensitive to chlorambucil (CLL S) or resistant to a combination containing doxorubicin, vincristine, cyclophosphamide and prednisone (CLL R) were studied for glutathione system, P-glycoprotein, PCNA and topoisomerase II expression. P-glycoprotein expression detected by an immunocytochemical technique using MRK 16 antibody was present at the same level in CLL S and CLL R. The percentage of cells positive for P-gp was below 5% in all samples tested. Topoisomerase IIalpha level was quantified by Western blot analysis. None of the 18 CLL samples had detectable topoisomerase IIalpha protein. In addition, 12 CLL were tested for PCNA staining and no samples had more than 1% of positive cells at immunocytochemical detection indicating that CLL cells were not engaged in the cell cycle. Some differences were found between CLL S and CLL R in the glutathione system. Glutathione concentration (GSH) and GST activity was the same in CLL S and CLL R. The glutathione-S-transferase (GST) isoenzyme profile was different in the two CLL groups. The mean GST-pi and GST-alpha quantitation were twice as high as in CLL R compared to CLL S, but this difference did not reach statistical significance because of large variations between CLL samples. A significant correlation was observed between GST-pi expression and GST activity using CDNB as the substrate. GST-mu was detected in only one of seven CLL before therapy and in six of 11 resistant to chemotherapy. No correlation was found between P-glycoprotein expression, GST activity and the different GST isoenzymes studied. These results suggest that the glutathione system could play a role in the resistance of anticancer agents in chronic lymphocytic leukemia. The role of the other drug resistance mechanisms (P-glycoprotein and topoisomerase IIalpha) seems to be of limited importance.
Leukemia 1996 Dec
PMID:Drug resistance mechanisms in chronic lymphocytic leukemia. 894 35

Treatment-related acute myeloid leukemia (t-AML) following successful therapy of a primary malignancy has been recognized with increasing frequency among cancer survivors over the past several years. Many of these t-AML cases are associated with the use of intensive chemotherapy regimens that employ one or more agents which target eukaryotic topoisomerase II (topo II), and demonstrate non-random chromosomal translocations involving either the MLL (ALL-1, HRX) gene at 11q23 or the AML1 gene at 21q22. Although many investigators have speculated that these translocations are induced by the therapeutic use of topo II inhibitors, the molecular sequence of events by which topo II inhibitors might induce a chromosomal translocation are not well understood. We describe here the reproducible induction of highly specific, double-strand DNA cleavage at a specific site within the AML1 locus by topo II inhibitors. This DNA cleavage, which maps to a region of the AML1 locus frequently disrupted by chromosomal translocations, can be induced in several cell lines, with multiple different topo II inhibitors, indicating that this phenomenon is not restricted to a specific cell type or specific topo II inhibitor. It is conceivable that site-specific double-strand DNA cleavage within the AML1 locus induced by topo II inhibitors represents the initial molecular event leading to a chromosomal translocation and t-AML.
Leukemia 1997 Apr
PMID:Topoisomerase II inhibitors induce DNA double-strand breaks at a specific site within the AML1 locus. 909 88

One of the most serious consequences of cancer therapy is the development of a second cancer, especially leukemia. Several distinct subsets of therapy-related leukemia can now be distinguished. Classic therapy-related myeloid leukemia typically occurs 5 to 7 years after exposure to alkylating agents and/or irradiation, has a myelodysplastic phase with trilineage involvement, and is characterized by abnormalities of the long arms of chromosomes 5 and/or 7. Response to treatment is poor, and allogenic bone marrow transplantation is recommended. Leukemia following treatment with agents that inhibit topoisomerase II, however, has a shorter latency, no preleukemic phase, a monoblastic, myelomonocytic, or myeloblastic phenotype, and balanced translocations, most commonly involving chromosome bands 11q23 or 21q22. The MLL gene at 11q23 or the AML1 gene at 21q22 are almost uniformly rearranged. MLL is involved with many fusion gene partners. Therapy-related acute lymphoblastic leukemia also occurs with 11q23 rearrangements. Therapy-related leukemias with 11q23 or 21q22 rearrangements, inv(16) or t(15;17), have a more favorable response to treatment and a clinical course similar to their de novo counterparts.
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PMID:Myeloid leukemia after hematotoxins. 911 10


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