UMLS:C0026986 - FACTA Search

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Query: UMLS:C0026986 (myelodysplastic syndrome)
14,926 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The treatment of cancer with alkylating drugs or topoisomerase II inhibitors can be responsible for the development of myelodysplastic syndromes and acute myelogenous leukemia. Alkylating agents such as melphalan and cisplatinum mainly produce damages at chromosomes 5 and 7 whereas topoisomerase II inhibitors-induced lesions essentially affect chromosomes 11 and 21. Rearrangements of the MLL gene at band 11q23 are frequently observed in human de novo myeloid and lymphoid leukemia as well as in leukemia or myelodysplasia secondary to therapy with drugs targetting topoisomerase II such as the epipodophyllotoxins. A relationship between the treatment with etoposide on teniposide and the development of translocations of the MLL gene has been clearly evidenced. The potential molecular basis of the chromosomal rearrangements implicating topoisomerase II and its inhibitors are discussed. The chemical structure of the inhibitors, their mechanism of action and the genes targetted by these drugs are presented. DNA cleavages induced directly by topoisomerase II inhibitors or by the drug induced apoptotic cellular response are responsible for nonrandom chromosomal aberrations and contribute to leukemogenesis.
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PMID:[Chromosome translocations and leukemias induced by inhibitors of topoisomerase II anticarcinogenic drugs]. 975 16

CBFA2(AML1) has emerged as a gene critical in hematopoiesis; its protein product forms the DNA-binding subunit of the heterodimeric core-binding factor (CBF) that binds to the transcriptional regulatory regions of genes, some of which are active specifically in hematopoiesis. CBFA2 forms a fusion gene with ETO and MDS1/EVI1 in translocations in myeloid leukemia and with ETV6(TEL) in the t(12;21) common in childhood pre-B acute lymphoblastic leukemia. We have analyzed samples from 30 leukemia patients who had chromosome rearrangements involving 21q22 by using fluorescence in situ hybridization (FISH). Our analysis showed that 7 of them involved CBFA2 and new translocation partners. Two patients had a t(17;21)(q11.2;q22), whereas the other 5 had translocations involving 1p36, 5q13, 12q24, 14q22, or 15q22. Five of these novel breakpoints in CBFA2 occurred in intron 6; this same intron is involved in the t(3;21). One breakpoint mapped to the t(8;21) breakpoint region in intron 5, and 1 mapped 5' to that region. All 7 CBFA2 rearrangements resulted from balanced translocations. All 7 patients had myeloid disorders (acute myeloid leukemia or myelodysplastic syndrome); 2 were de novo and 5 had treatment histories that included topoisomerase II targeting agents. The association of therapy-related disorders with translocations involving CBFA2 was significant by Fisher's exact test (P < .003). These results provide further evidence that this region of CBFA2 is susceptible to breakage in cells exposed to topoisomerase II inhibitors.
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PMID:CBFA2(AML1) translocations with novel partner chromosomes in myeloid leukemias: association with prior therapy. 976 73

Myelodysplastic syndromes (MDS) and chronic myelomonocytic leukemia (CMML) are heterogeneous disorders for which there exist few active therapies and where the standard of care is still considered supportive. Identification of new effective therapies in MDS and CMML is a high priority for hematologic oncologists. We have evaluated the efficacy of single-agent topotecan, a topoisomerase I inhibitor, in patients with MDS (refractory anemia with excess blasts [RAEB] and refractory anemia with excess blasts in transformation [RAEB-T]) and CMML. Sixty patients (MDS = 30; CMML = 30) with a median age of 66 years were treated. Chromosomal abnormalities were present in half of the patients, as was thrombocytopenia. Topotecan was administered at 2 mg/m2 by continuous intravenous infusion over 24 hours daily for 5 days every 4 to 6 weeks until remission, followed by one course every 4 to 8 weeks for a maximum of 10 courses. Nineteen patients (32%) achieved a complete response (CR); seven had hematologic improvement. CRs were observed in 11 of 30 patients with MDS (37%) and eight of 30 patients with CMML (27%). Conversion to diploid karyotype was observed in eight patients with karyotypic abnormalities at diagnosis who later achieved a CR. History of prior chemotherapy and monocytosis was associated with poor prognosis. Mutation of the RAS oncogene was found in six CMML patients (20%), and none responded to topotecan therapy. The estimated 12-month survival rate was 33%, the median survival time was 9.3 months, and the median remission duration was 7 months. The most significant toxicities were gastrointestinal, including mucositis (67%; severe 23%) and diarrhea (38%; severe 17%). Febrile episodes were noted in 85% of the patients, while documented infection occurred in 47%. Topotecan has demonstrated significant single-agent activity in MDS and CMML with generally manageable side effects. Future studies will evaluate topotecan-based combination therapies with topoisomerase II reactive agents, cytarabine, alkylating agents, and hypomethylating agents.
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PMID:Topotecan in the treatment of hematologic malignancies. 977 79

The activity of topotecan was evaluated in patients with myelodysplastic syndrome (MDS) and chronic myelomonocytic leukemia (CMML). Sixty patients with a diagnosis of MDS (n = 30) or CMML (n = 30) were treated. Their median age was 66 years, with 50 patients (83%) being over 60 years of age at time of study entry. Chromosomal abnormalities were present in 50% of patients and thrombocytopenia of less than 50 x 10(9)/L in 50%. Topotecan was administered as 2 mg/m2 by continuous infusion over 24 hours daily for five days (10 mg/m2 per course) every 4 to 6 weeks for two courses, then at maximum tolerated dose level (1-2 mg/m2 by continuous infusion over 24 hours daily for five days) once every 4-8 weeks for a maximum of 12 courses. Evaluation of outcome and of differences among subgroups was performed according to standard methods; the criteria for response were those used for acute leukemia. Nineteen patients (31%) achieved a complete response (CR). A CR was achieved in 11 of 30 patients with MDS (37%) and in eight of 30 with CMML (27%). A CR was achieved in 10 of 23 patients with previously untreated MDS (43%). Eight of 11 patients who presented with cytogenetic abnormalities (five of which involved chromosome 5 and/or 7 abnormalities) and achieved CR, were evaluated cytogenetically in CR: all were cytogenetically normal in CR. Characteristics associated with a higher CR rate were lack of previous chemotherapy, absence of ras oncogene mutations, and presence of less than 10% monocytes in either peripheral blood or bone marrow. In contrast, CR rates were similar by different agent groups, by different karyotype abnormalities, and by other pre-therapy peripheral blood counts. Non-myelosuppressive side effects were mucositis in 67% of patients (severe [grade 3-4] 23%), diarrhea in 38% (severe 17%), and nausea and vomiting in 28% (severe 5%). Febrile episodes during neutropenia occurred in 85% of patients and documented infections in 47 %. Mortality in the first four weeks was 20%. With a median follow-up duration of 31 months, the 12 month survival rate was 38%, median survival time 10.5 months, and median remission duration 7.5 months. In summary, topotecan has significant single-agent activity in MDS and CMML. Complete responses associated with topotecan therapy often involve the disappearance of abnormal, poor-prognosis karyotypes, which is particularly encouraging. Future strategies to optimize topotecan's role include combination regimens with topoisomerase II reactive agents, cytarabine, or hypomethylating agents (azacytidine and decitabine).
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PMID:Results of topotecan single-agent therapy in patients with myelodysplastic syndromes and chronic myelomonocytic leukemia. 992 42

Two main types of therapy-related acute myeloid leukemias (tAML) and myelodysplastic syndromes (tMDS) have been described. The first classical type typically occurs late after use of alkylating agents and presents as MDS with -7/del 7q and/or -5/del5q. The second form occurs early after the use of agents targeted at topoisomerase II, and presents as AML with 11q23 or other rearrangements of de novo AML. Recently, we and others reported, in AML and MDS, a strong correlation between cytogenetic rearrangements leading to 17p deletion, a specific type of dysgranulopoiesis and p53 mutation; several of those cases of 17p- syndrome were therapy-related. Over the last 15 years, we observed 25 cases of tAML and tMDS with 17p deletion, which represented 36% of the AML and MDS with 17p deletion diagnosed during that period. Median age was 59 years. Twenty-one patients had tMDS and four tAML. Typical dysgranulopoiesis and p53 mutation and/or overexpression were seen in 22 of 24 and 16 of 19 evaluable patients, respectively. 17p deletion resulted from unbalanced translocations involving 17p (18 cases), monosomy 17 (five cases), i(17q) (one case) or del 17p (one case). Twenty-one patients also had -5/del 5q, and/or -7/del 7q. Median interval from treatment of the first tumor of tAML and tMDS was 94 months (range 19-252). Median survival was only 7 months. Based on primary tumor and antineoplastic agents used, patients could be relatively well divided into two groups: a first group of 11 cases, occurring mainly after a lymphoid neoplasm (eight cases) treated by chemotherapy with an alkylating agent (10 cases), and a second group of 14 cases occurring after essential thrombocythemia (ET) or polycythemia vera (PV) treated mainly by hydroxyurea (10 cases), pipobroman (eight cases), 32P (six cases) but rarely by alkylating agents (two cases). -7/del 7q was found in 10 of the 11 patients in the first group, as compared to three of the 14 patients of the second group (P = 0.0001). Therefore, therapy-related cases represent a high proportion of AML and MDS with the 17p- syndrome. They have many features in common with classical tMDS and tAML, including long interval from the first tumor, a usual preleukemic phase, and frequent occurrence of -5/del 5q. About one half of them, in addition, occur after alkylating agents and generally carry -7/del 7q. The other half, however, occur mainly after ET or PV treated by hydroxyurea or other non-alkylating agents, and usually have no -7/del 7q. These findings bring further support to a possible relationship between prior drugs used and cytogenetic rearrangements in tAML and tMDS.
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PMID:Therapy-related myelodysplastic syndrome and acute myeloid leukemia with 17p deletion. A report on 25 cases. 1002 99

The oral antitumor drugs against hematological malignancies are summarized. Sobuzoxane, a topoisomerase II inhibitor, is useful for the treatment of lymphoma, especially adult T cell leukemia/lymphoma. Sobuzoxane has an effect to protect against doxorubicin cardiotoxicity. Cytarabine ocfosfate, a derivative of cytosine arabinoside, is a useful agent against acute leukemia and MDS, especially RAEB, RAEB in T, CMMoL. The JALSG AML 92 study for APL with all-trans retinoic acid resulted in a 89% CR rate in 196 and 64% 4-year DFS in CR cases. Hydroxycarbamide is can control the WBC in CML. This agent is also effective for other myeloproliferative disorders, such as acute leukemia and MDS. Oral administration of 50 mg etoposide daily showed a good outcome in old patients with malignant lymphoma. For old patients and those with refractory hematological malignancies, oral administration of these agents can offer a new form of palliative therapy to allow them to remain at home while maintaining a high quality of life.
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PMID:[Oral antitumor drugs for hematological malignancies]. 1006 91

NAD(P)H:quinone oxidoreductase (NQO1) converts benzene-derived quinones to less toxic hydroquinones and has been implicated in benzene-associated hematotoxicity. A point mutation in codon 187 (Pro to Ser) results in complete loss of enzyme activity in homozygous subjects, whereas those with 2 wild-type alleles have normal activity. The frequency of homozygosity for the mutant allele among Caucasians and African Americans is 4% to 5% but is higher in Hispanics and Asians. Using an unambiguous polymerase chain reaction (PCR) method, we assayed nonmalignant lymphoblastoid cell lines derived from 104 patients with myeloid leukemias; 56 had therapy-related acute myeloid leukemia (t-AML), 30 had a primary myelodysplastic syndrome (MDS), 9 had AML de novo, and 9 had chronic myelogenous leukemia (CML). All patients had their leukemia cells karyotyped. Eleven percent of the t-AML patients were homozygous and 41% were heterozygous for the NQO1 polymorphism; these proportions were significantly higher than those expected in a population of the same ethnic mix (P =.036). Of the 45 leukemia patients who had clonal abnormalities of chromosomes 5 and/or 7, 7 (16%) were homozygous for the inactivating polymorphism, 17 (38%) were heterozygous, and 21 (47%) had 2 wild-type alleles for NQO1. Thus, NQO1 mutations were significantly increased compared with the expected proportions: 5%, 34%, and 61%, respectively (P =.002). An abnormal chromosome no. 5 or 7 was observed in 7 of 8 (88%) homozygotes, 17 of 45 (38%) heterozygotes, and 21 of 51 (41%) patients with 2 wild-type alleles. Among 33 patients with balanced translocations [14 involving bands 11q23 or 21q22, 10 with inv(16) or t(15;17), and 9 with t(9;22)], there were no homozygotes, 15 (45%) heterozygotes, and 18 (55%) with 2 wild-type alleles. Whereas fewer than 3 homozygotes were expected among the 56 t-AML patients, 6 were observed; 19 heterozygotes were expected, but 23 were observed. The gene frequency for the inactivating polymorphism (0. 31) was increased approximately 1.4-fold among the 56 t-AML patients. This increase was observed within each of the following overlapping cohorts of t-AML patients: the 43 who had received an alkylating agent, the 27 who had received a topoisomerase II inhibitor, and the 37 who had received any radiotherapy. Thus, the frequency of an inactivating polymorphism in NQO1 appears to be increased in this cohort of myeloid leukemias, especially among those with t-AML or an abnormality of chromosomes 5 and/or 7. Homozygotes and heterozygotes (who are at risk for treatment-induced mutation or loss of the remaining wild-type allele in their hematopoietic stem cells) may be particularly vulnerable to leukemogenic changes induced by carcinogens.
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PMID:Prevalence of the inactivating 609C-->T polymorphism in the NAD(P)H:quinone oxidoreductase (NQO1) gene in patients with primary and therapy-related myeloid leukemia. 1039 48

The t(3;21)(q26;q22) is a recurring chromosomal abnormality in blastic crisis of chronic myelogenous leukemia (CML) and in therapy-related myelodysplastic syndrome and acute leukemia. In order to clarify the genetic recombination mechanism underlying the t(3;21), we molecularly cloned the breakpoints and determined their nucleotide sequence in a case of CML in blastic crisis with t(3;21). Near the breakpoint on chromosome 21, three homopyrimidine (CT)-rich sequences were found. We also identified a sequence homologous to the topoisomerase II binding and cleavage consensus sequence surrounding the breakpoint on chromosome 3, and two topoisomerase II binding and cleavage consensus sequences near the breakpoint on chromosome 21. In addition, around the breakpoint on chromosome 21, four chi-like sequences, potential consensus signals for activating recombination, were found. There were no Alu sequences or antigen receptor gene-like heptamer/nonamer signal sequences within the breakpoints on chromosomes 3 and 21. The breakpoints were found adjacent to the topoisomerase II binding and cleavage consensus sequence or the homopyrimidine-rich sequence. Furthermore, the chi-like sequences and the homopyrimidine-rich sequence were detected on chromosome 21 but not on chromosome 3. Genes Chromosomes Cancer 26:92-96, 1999.
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PMID:Molecular characterization of the genomic breakpoints in a case of t(3;21)(q26;q22). 1044 Oct 11

Drug resistant cells often have an increased capacity to repair their DNA after damage by cytotoxic agents. Aphidicolin can inhibit this DNA repair. We describe a study of the effect of aphidicolin to modulate the sensitivity to cytotoxic drugs of blast cells from 13 patients with AML, 11 with de novo disease on presentation and 2 secondary to MDS. Three patients had relapsed following previous therapy and samples were received from 1 patient both on presentation and relapse. Blast cells were exposed to anthracyclines, antimetabolites or etoposide +/- aphidicolin (15 microM) for 48 hours. The MTT assay was used to measure cell survival and the LC50 (concentration of drug required for 50% cell kill) was calculated. Overall, there was a significant increase in sensitivity to ara-C on co-incubation with aphidicolin in 12/14 samples (p = 0.007). The median increase in sensitivity was 3.88-fold (range 1.26- to 80-fold). Interestingly, when patients were grouped according to in vitro sensitivity to ara-C, cells from resistant patients demonstrated the greatest increase in sensitivity (median 14-fold compared to 2-fold for the sensitive group, p = 0.02). Despite the documented evidence for altered DNA repair as a mechanism of resistance to the topoisomerase II inhibitors, we found no significant increase in sensitivity to daunorubicin, doxorubicin or etoposide on co-incubation with aphidicolin. Nevertheless, we believe the unparalleled modulation of ara-C warrants further investigation.
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PMID:Aphidicolin markedly increases the in vitro sensitivity to ara-C of blast cells from patients with AML. 1050 Aug 35

Clinically distinct features in both alkylating agents--and topoisomerase II (topo II)-induced secondary leukemias (SL) are reviewed with special reference to the increasing frequencies observed in relation to advances in modern cancer chemotherapy. Topo II interacts with, and then stabilizes the cleavable complex that ultimately results in double strand breaks. In patients with SL, breakpoints in MLL gene are clustered within SARs of 3' bcr. However, mechanisms by which the former type of SL is caused remain to be elucidated. Since alkylating agents often induce profound marrow dysplasia, long-lived lesions induced on hematopoietic stem cells are of potential relevance to the development of SL. This process may be partially demonstrated by the variety of mitotic modifications found in MDS. Recently, the association has been investigated between certain enzyme polymorphisms related to activation or detoxification of anticancer agents and SL. These studies have potential importance, since individuals with a certain genotype may be at increased risk for SL.
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PMID:[Secondary leukemias: their clinical features, incidence among populations at risk, mechanisms and new strategy for prediction]. 1058 63

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