KEGG:D03343 - FACTA Search

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Query: KEGG:D03343 (MDS)
2,225 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

There is compelling evidence that leukemia arises via a multistep process. Molecular analysis of human leukemias, which are typically clonal, commonly shows multiple genetic lesions in a single leukemia including chromosomal translocations, gene amplification, and point mutations, and in several cases the mutational activation of an oncogene and the loss of a tumor suppressor gene have been found in the same leukemic cell. Accumulative evidences suggest that a number of oncogenes and tumor suppressor genes are involved in the hematopoietic tumorigenesis. These mutations can be utilized for molecular diagnosis of human hematopoietic tumors. Among them, detection of chimeric gene generated by chromosomal translocation is especially useful for molecular diagnosis. The t(3;21) (q26;q22) translocation is found usually in blastic crisis of CML and leukemias developed from MDS or hematopoietic proliferative diseases, but never in de novo acute myelocytic leukemia. This raises the possibility that the molecular event underlying the t(3;21) translocation has a critical role in progression from a preleukemic state to a leukemic state. The generation of AML1/EVI-1 chimeric gene has been demonstrated to be consistent in t(3;21)-carrying leukemias. Although target genes remain to be elucidated for both AML1 and EVI-1 as transcription factors, the AML1/EVI-1 fusion protein could work on different set of genes critical to the process of proliferation and differentiation of hematopoietic cells.
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PMID:[Diagnosis of hematological disorders by mutational analysis of oncogenes]. 760 95

Two genes have been implicated in leukemias of patients with abnormalities of chromosome 3, band q26: EVI1, which can be activated over long distances by chromosomal rearrangements involving 3q26, and EAP, a ribosomal gene that fuses with AML1 in a therapy-related myelodysplasia patient with a t(3;21)(q26.2;q22). AML1 was identified by its involvement in the t(8;21)(q22;q22) of acute myeloid leukemia. Here we report the consistent identification of fusion transcripts between AML1 and EAP or between AML1 and previously unidentified sequences that we named MDS1 (MDS-associated sequences) in the leukemic cells of four patients with therapy-related myelodysplasia/acute myeloid leukemia and in one patient with chronic myelogenous leukemia in blast crisis, all of whom had a t(3;21). In addition, we have identified a third chimeric transcript, AML1/EVI1, in one of the therapy-related acute myeloid leukemia patients. Pulsed-field gel electrophoresis established the order of the genes as EAP, the most telomeric, and EVI1, the most centromeric, gene. The results indicate that translocations could involve multiple genes and affect gene expression over long distances.
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PMID:Consistent intergenic splicing and production of multiple transcripts between AML1 at 21q22 and unrelated genes at 3q26 in (3;21)(q26;q22) translocations. 817 Oct 26

A nonrandom translocation between chromosomes 3 and 21, t(3;21)(q26.2;q22) has been detected in patients with a myelodysplastic syndrome or acute myeloid leukemia after treatment (t-MDS/t-AML) for a primary malignant disease and in chronic myelogenous leukemia in blast crisis (CML-BC). In these patients, the breakpoint on chromosome 21 is at band 21q22. This band is also involved in the t(8;21)(q22;q22) detected in 40% of the patients with acute myeloid leukemia subtype M2 (AML-M2) de novo who have an abnormal karyotype. In the t(8;21), the AML1 gene is the site of the breakpoint on chromosome 21. The AML1 gene is transcribed from telomere to centromere, and in the t(8;21) the 5' part of AML1 is fused to the ETO gene on chromosome 8 to produce the chimeric AML1/ETO on the der(8) chromosome. We found that AML1 is also rearranged in two t-AML patients and in one CML-BC patient with the t(3;21), but the breakpoints are approximately 40 to 60 kb downstream to those of AML-M2 patients. This region contains at least one additional exon of AML1, as determined by using an AML1 cDNA as a probe in Southern blot analysis. The t(3;21) breakpoints for the remaining patients could not be determined because, by fluorescence in situ hybridization analysis, the breaks are outside of the region covered by the available probes.
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PMID:Involvement of the AML1 gene in the t(3;21) in therapy-related leukemia and in chronic myeloid leukemia in blast crisis. 849 Jan 81

Chromosome fluorescence in situ hybridization (FISH) analyses were performed on bone marrow cells in 3 adult patients with MDS or AML with a (16;21)(q24;q22) translocation. FISH analyses with AML1 probes at 21q22 proved in all 3 patients splitting of the AML1 gene at a region spanning exons 5 and 6 and the translocation of its 5' segment to distal 16q. Chromosome painting FISH analysis in patient 1 proved the translocation of the distal 21q segment to 16q, but it failed to prove the presumed translocation of the distal 16q segment to 21q, most likely because of its small size.
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PMID:A recurrent translocation, t(16;21)(q24;q22), associated with acute myelogenous leukemia: identification by fluorescence in situ hybridization. 921 14

We have investigated a case of acute myelocytic leukaemia derived from myelodysplastic syndrome (MDS-AML) with an 8;21 translocation. In this case the AML1/MTG8 (ETO) fusion transcript was not detected by reverse transcriptase-polymerase chain reaction (RT-PCR), and the rearrangement of the AML1 gene locus was not detected by Southern blot nor pulse field gel electrophoresis (PFGE) analyses using specific probes for the AML1 gene. Fluorescence in-situ hybridization (FISH) study using cosmid probes for 21q22 revealed that the breakpoint of 21q22 was telomeric to the AML1 gene locus and centromeric from D21S259, 351, 3421 loci. This is the first report concerning the t(8;21)(q22;q22) carrying AMLs (de novo AML, MDS-AML and therapy-related AML) to show that the breakpoint at 21q22 is located outside the AML1 gene locus. It is also noteworthy that the cell-surface antigen expression pattern of the bone marrow (BM) blasts was changed from CD7+ CD2+ CD13+ CD33+ CD19- CD11b+ CD14+ CD36+ to CD7- CD2- CD13+ CD19+ CD11b- CD14- CD33+ CD34+ CD36- CD56+ during leukaemic progression, and the pattern in leukaemic phase was similar to the characteristic phenotype of de novo AML cases with t(8;21), when the AML1/MTG8 fusion transcripts are always detected by RT-PCR.
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PMID:Genetic analysis of 8;21 chromosomal translocation without AML1 gene involvement in MDS-AML. 940 Oct 77

The AML1 (CBFA2) gene is the most frequent target of chromosomal rearrangements observed in human acute leukemia. These rearrangements include the commonly reported t(8;21)(q22;q22) or AML1/ETO fusion in AML-M2, the t(3;21)(q26;q22) or AML1 fusion with one of three genes, MDS1, EAP or EVI1, in therapy-related AML and MDS, as well as in blast crisis in CML and the t(12;21)(p13;q22) or TEL/AML1 fusion in B-cell ALL. In addition to the t(3;21), other AML1 translocations have also been reported in therapy-related MDS and AML, particularly after treatment with topoisomerase II inhibitors. AML1 gene rearrangements have also been observed less frequently with numerous other chromosomal partners. Here, we describe a patient with AML-M4 and a previously unreported rearrangement involving the AML1 locus and an unknown locus on the short arm of chromosome 1 at 1p32.
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PMID:A unique AML1 (CBF2A) rearrangement, t(1;21)(p32;q22), observed in a patient with acute myelomonocytic leukemia. 1156 47

The International Workshop on the relationship between prior therapy and balanced chromosome aberrations in therapy-related myelodysplastic syndromes (t-MDS) and therapy-related acute leukemia (t-AL) identified 79 of 511 (15.5%) patients with balanced 21q22 translocations. Patients were treated for their primary disease, including solid tumors (56%), hematologic malignancy (43%), and juvenile rheumatoid arthritis (single case), by radiation therapy (5 patients), chemotherapy (36 patients), or combined-modality therapy (38 patients). 21q translocations involved common partner chromosomes in 81% of cases: t(8;21) (n = 44; 56%), t(3;21) (n = 16; 20%), and t(16;21) (n = 4; 5%). Translocations involving 15 other partner chromosomes were also documented with involvement of AML1(CBFA2/RUNX1), identifying a total of 23 different 21q22/AML1 translocations. The data analysis was carried out on the basis of five subsets of 21q22 cases, that is, t(8;21) with and without additional aberrations, t(3;21), t(16;21), and other 21q22 translocations. Dysplastic features were present in all 21q22 cases. Therapy-related acute myeloid leukemia (t-AML) at presentation was highest in t(8;21) (82%) and lowest in t(3;21) (37.5%) patients. Cumulative drug dose exposure scores for alkylating agents (AAs) and topoisomerase II inhibitors indicated that t(3;21) patients received the most intensive therapy among the five 21q22 subsets, and the median AA score for patients with secondary chromosome 7 aberrations was double the AA score for the entire 21q22 group. All five patients who received only radiation therapy had t(8;21) t-AML. The median latency and overall survival (OS) for 21q22 patients were 39 and 14 months (mo), compared to 26 and 8 mo for 11q23 patients, 22 and 28 mo for inv(16), 69 and 7 mo for Rare recurring aberrations, and 59 and 7 mo for Unique (nonrecurring) balanced aberration (latency P < or = 0.016 for all pairwise comparisons; OS, P < or = 0.018 for all pairwise comparisons). The percentages of 21q22 patients surviving 1 year, 2 years, and 5 years were 58%, 33%, and 18%, respectively. Noticeable differences were observed in median OS between 21q22 patients (n = 7) receiving transplant (BMT) (31 mo) compared to 21q22 patients who received intensive non-BMT therapy (n = 46) (17 mo); however, this was nonsignificant because of the small sample size (log-rank, P = 0.33). t-MDS/t-AML with balanced 21q22 aberrations was associated with prior exposure to radiation, epipodophyllotoxins, and anthracyclines, dysplastic morphologic features, multiple partner chromosomes, and longer latency periods when compared to 11q23 and inv(16) t-MDS/AML Workshop subgroups. In general, patients could be divided into two prognostic risk groups, those with t(8;21) (median OS, 19 mo) and those without t(8;21) (median OS, 7 mo) leukemia (log-rank, P = 0.0007).
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PMID:21q22 balanced chromosome aberrations in therapy-related hematopoietic disorders: report from an international workshop. 1192 Dec 72

Expression of AML1/ETO mRNA was observed in bone marrow cells from 49 untreated leukemic patients, and continuously detected during different periods after chemotherapy (12 cases) or bone marrow transplantation (8 cases). The results showed that AML1/ETO mRNA could be expressed in cells from AML-M(2), AML-M(4) and MDS-RAEB-T patients. The positive expression changed into negative at different duration in patients who achieved complete remission either by chemotherapy (9 cases), allogeneic bone marrow transplantation (5 cases) and autologous peripheral blood stem cell transplantation (1 case), and they were sustained in complete remission status. In chemotherapeutic group, patients whose AML1/ETO expression turning from negative (2 cases) or faint positive (1 case) to positive relapsed later. Two patients treated with Allo-BMT showed continuously positive results and died of GVHD and relapse, respectively. These observations suggest that AML1/ETO chimeric mRNA could disappeared after chemotherapy or bone marrow transplantation. The patients have a great probability to relapse if the results of RT-PCR are continuously positive or change from negative to positive. Regular detection is necessary for leukemic patients.
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PMID:[Follow up Detection of AML/ETO Fushion Transcripts after Chemotherapy or Bone Marrow Transplantation in Leukemia Patients] 1257 21

The RUNX1/AML1 gene is the most frequent target for chromosomal translocation in leukemia. In addition, recent studies have demonstrated point mutations in the RUNX1 gene as another mode of genetic alteration in development of leukemia. Monoallelic germline mutations in RUNX1 result in familial platelet disorder predisposed to acute myelogenous leukemia (FPD/AML). Sporadic point mutations are frequently found in three leukemia entities: AML M0 subtype, MDS-AML, and secondary (therapy-related) MDS/AML. Therapy-related leukemias resulting from anticancer treatments are not uncommon, and the incidence of RUNX1 point mutations appears comparable to the incidence of the t(8;21) AML M2 subtype and the inv(16) AML M4Eo subtype. Half of the point mutations in M0 cases are biallelic, although the frequency varies with ethnicity. Most of the RUNX1 mutations are clustered in the Runt domain and result in defective DNA binding but active beta-subunit binding, which is consistent with three-dimensional structural findings and may explain the dominant inhibitory effects. Unlike the classical tumor suppressor genes requiring biallelic inactivation, haploinsufficient RUNX1 is apparently leukemogenic. However, RUNX1 abnormalities per se are insufficient to cause full-blown leukemia. Intensive investigation of cooperating genetic alterations should elucidate leukemic mechanisms.
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PMID:Point mutations in the RUNX1/AML1 gene: another actor in RUNX leukemia. 1515 85

Amplification or duplication of the AML1 gene at chromosome band 21q22 was detected by FISH using a locus-specific probe in three out of 171 unselected patients with therapy-related myelodysplasia (t-MDS) or t-AML (1.7%). In two patients AML1 signals were located tandemly on derivative chromosomes, in one patient on a dic(9;21) and in the the other patient on a derivative chromosome 18 made up of interchanging layers of material from chromosomes 9, 14, 18, and 21. In the third patient three single supernumerary copies of AML1 were located on derivatives of chromosomes 19 and 21. All three patients were older, had previously received therapy with alkylating agents without topoisomerase II inhibitors, had complex karyotypes including abnormalities of chromosomes 5 or 7, and presented acquired point mutations of the TP53 gene. No point mutations of the AML1 gene were observed. The results support a pivotal role of impaired TP53 function in the development of gene amplification or duplication in t-MDS and t-AML.
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PMID:Amplification or duplication of chromosome band 21q22 with multiple copies of the AML1 gene and mutation of the TP53 gene in therapy-related MDS and AML. 1561 58

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