UMLS:C0023418 - FACTA Search

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Query: UMLS:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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

A 43-year-old man with oligoblastic leukemia and t(3;8) variant translocation is reported. At first he was classified as refractory anemia with excess of blasts in transformation according to the FAB criteria for myelodysplastic syndrome. Remission was obtained after intensive chemotherapy. After 8 months, a relapse occurred as overt M2 AML. At presentation chromosome study of bone marrow cells using R- and G-bandings revealed 45,X, -Y,t(3;8)(q29;q22) in 35 of the 42 metaphases analyzed and 46,XY,t(3;8) in one metaphase in addition to normal karyotype in the other six metaphases. However, RT-PCR assay showed no AML1/ETO fusion transcript. At relapse, a karyotype of 46, XY,t(3;8), deletion(4)(p14), add(7)(q32) was observed in all abnormal cells indicating a clonal karyotypic evolution. We believed that this case should be diagnosed as an early form of M2 AML initially. It may be the first case of oligoblastic leukemia with t(3;8) variant translocation. Further study is needed to elucidate its molecular entity.
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PMID:A rare variant translocation t(3;8)(q29;q22) without AML1/ETO fusion transcript in a case of oligoblastic leukemia. 978 4

Donor leukocyte infusions (DLI) have turned out to be an efficient way to re-establish complete remission (CR) in chronic myeloid leukemia (CML) patients relapsing after allogeneic bone marrow transplantation (BMT). In these patients, absence of PCR bcr-abl fusion transcripts confirmed the potency of donor leukocytes to induce molecular response in relapsed CML. This ensured sustained remission and long-term survival. In this study, the capacity of DLI to induce molecular remission in acute leukemia relapse after BMT was analyzed. The results showed that following DLI, leukemic cell eradication gradually occurred over a prolonged time period. The time to complete disappearance of the molecular marker of the disease was 30 weeks in RT-PCR analysis. A sustained and persistent elimination of an AML1/ETO-positive leukemic clone in an AML-M2 patient was observed. In contrast, an AML-M5 with t(11;19) and an E2A/PBX1-positive ALL achieving cytogenetic and molecular bone marrow CR developed following DLI unusual sites of extramedullary leukemia relapse, despite continued bone marrow remission. This study adds further proof of the benefit of donor cell therapy in acute leukemia but shows that complete leukemic cell eradication appears to require a critical interval in order to establish effective immune responses at all sites where leukemic cells persist.
Leukemia 1998 Nov
PMID:Extramedullary relapse after favorable molecular response to donor leukocyte infusions for recurring acute leukemia. 982 40

In an earlier study we observed residual normal colonies in the CD34+, lineage-negative fraction in AML with a differentiated phenotype. The phenotype of both normal and leukemic progenitors in AML M2, t(8;21) was the subject of this study. The specific translocation enabled discrimination of normal and leukemic cells. Bone marrow samples from eight patients were evaluated for CD34 and the differentiation markers CD33, CD19 and CD56. Growth in all phenotypic fractions was measured in a single cell assay, which enabled quantification of plating efficiency, colony size and determination of progenitor cell origin. No growth was observed in the CD34-negative fraction. In the CD34+, lineage-positive fraction only clusters up to 20 cells were found in 6/8 samples. In 7/8 samples highly proliferative myeloid, erythroid and mixed colonies were cloned from the CD34+/CD56-CD19-CD33- fraction with a frequency between 1 and 12%. Such large colonies grew at a lower frequency (1-6%) from the CD34+/CD56 fraction (4/8 samples), the CD34+/CD56-CD19- fraction (5/8 samples) and from the CD34+/CD19- fraction (1/8 samples), respectively. Among the colonies consisting of more than 150 cells, only 3/45 evaluated were positive for the AML1/ETO fusion transcript. On the other hand, 8/19 colonies with less than 150 cells were AML1/ETO positive. This study shows that like normal progenitors leukemic progenitors are also present exclusively in the lineage-negative fraction in AML M2 t(8;21). A similar hierarchy of proliferation and differentiation was found for these leukemic progenitors, the smaller colony size fitting with their limited proliferation capacity. The frequency of leukemic progenitors was in the same range as their normal counterparts and detectable only after enrichment for the CD34+, lineage-negative population.
Leukemia 1998 Nov
PMID:In AML t(8;21) colony growth of both leukemic and residual normal progenitors is restricted to the CD34+, lineage-negative fraction. 982 54

Chromosomal translocations are commonly found in de novo acute myeloid leukemia (AML) cells, and the fusion proteins produced from these genetic abnormalities are assumed to contribute directly to leukemogenesis and/or progression. The AML1/ETO fusion protein, created by translocations between chromosomes 8 and 21 [t(8;21); G. Nucifora and J. D. Rowley, Leuk. Lymphoma, 14: 353-362, 1994; K. L. Rhoades et al., Proc. Natl. Acad. Sci. USA, 93: 11895-11900, 1996] can induce anti-apoptotic Bcl-2 expression in vitro and was proposed to thereby promote the survival of t(8;21)-bearing AML cells (L. Klampfer et al., Proc. Natl. Acad. Sci. USA, 93: 14059-14064, 1996). We confirm that cells of the t(8;21)-bearing Kasumi cell line do express high levels of Bcl-2 protein, as reported previously. However, we show that primary AML cells with (8;21) chromosomal translocations generally express low levels of Bcl-2 protein relative to normal bone marrow-derived myeloid cells and to AML samples with other simple karyotypic abnormalities. We note that p53 mutations are present in the myeloid cell lines expressing AML-ETO protein from chromosomal translocations (Kasumi and SKNO) or from transfected fusion genes (U937) but were undetected in our analyses of 28 primary t(8;21)-bearing AML cell samples from de novo AMLs. Because wild-type p53 can transcriptionally down-regulate bcl-2, we speculate that p53 mutations may contribute to the association of t(8;21) chromosomal abnormalities with higher Bcl-2 expression levels in leukemia cell lines. We also note that some t(8;21)-bearing samples from pediatric and older adult patients do express somewhat higher levels of Bcl-2 than t(8;21)-bearing samples from young adult patients. This suggests that Bcl-2 overexpression could occur in these AML cells by an as yet undefined, p53-independent mechanism and could contribute to the reported association of t(8;21) karyotypes with poor clinical outcomes in childhood AML patients and/or to typically poor clinical outcomes in elderly AML patients.
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PMID:The t(8;21) translocation is not consistently associated with high Bcl-2 expression in de novo acute myeloid leukemias of adults. 986 20

The translocation (8;21)(q22;q22) is a karyotypic abnormality detected in acute myeloid leukaemia (AML) M2 and results in the formation of the chimeric fusion gene AML1/MTG8. We previously reported that two hammerhead ribozymes against AML1/MTG8 cleave this fusion transcript and also inhibit the proliferation of myeloid leukaemia cell line Kasumi-1 which possesses t(8;21)(q22;q22). In this study, we investigated the mechanisms of inhibition of proliferation in myeloid leukaemic cells with t(8;21)(q22;q22) by ribozymes. These ribozymes specifically inhibited the growth of Kasumi-1 cells, but did not affect the leukaemic cells without t(8;21)(q22;q22). We observed the morphological changes including chromatin condensation, fragmentation and the formation of apoptotic bodies in Kasumi-1 cells incubated with ribozymes for 7 days. In addition, DNA ladder formation was also detected after incubation with ribozymes which suggested the induction of apoptosis in Kasumi-1 cells by the AML1/MTG8 ribozymes. However, the ribozymes did not induce the expression of CD11b and CD14 antigens in Kasumi-1 cells. The above data suggest that these ribozymes therefore inhibit the growth of myeloid leukaemic cells with t(8;21)(q22;q22) by the induction of apoptosis, but not differentiation. We conclude therefore that the ribozymes targeted against AML1/MTG8 may have therapeutic potential for patients with AML carrying t(8;21)(q22;q22) while, in addition, the product of the chimeric gene is responsible for the pathogenesis of myeloid leukaemia.
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PMID:Induction of apoptosis in myeloid leukaemic cells by ribozymes targeted against AML1/MTG8. 1018 72

Reverse transcriptase-polymerase chain reaction (RT-PCR) methods often detect the AML1/MTG8 fusion transcript even in acute myelogenous leukemia (AML) patients with t(8;21) who have been in long-term remission. We encountered 2 hypoplastic leukemia patients with t(8;21) who achieved cytogenetic remission with short-term conventional chemotherapy. Patient 1 was a 42-year-old woman. Chromosomal analysis detected t(8;21) (q22;q22) and PCR analysis (35 cycles PCR amplification; detection limit 1 x 10(-5) cells) detected the AML1/MTG8 fusion transcript. Complete remission was obtained with 1 course of chemotherapy consisting of low-dose cytarabine (20 mg x 14 days) and etoposide (50 mg x 14 days). After 2 courses of consolidation chemotherapy consisting of conventional-dose cytarabine and mitoxantrone, the RT-PCR findings were negative for the AML1/MTG8 fusion transcript. Patient 2 was a 67-year-old man. Cytogenetic analysis detected t(8;21) (q22;q22), and was positive for the AML1/MTG8 fusion transcript. After 2 courses of induction chemotherapy comprising low-dose cytarabine (20 mg x 14 days) and etoposide (50 mg x 14 days), and 3 courses of conventional consolidation chemotherapy, RT-PCR analysis confirmed the disappearance of the AML1/MTG8 fusion transcript.
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PMID:[Disappearance of residual disease confirmed by RT-PCR following induction chemotherapy in two hypoplastic leukemia patients with t(8;21)]. 1035 40

We report a case of Philadelphia-positive chronic myelogenous leukaemia in blastic phase with the additional translocation (8;21)(q22;q22), which is frequent in acute myeloid leukaemia but not in chronic myelogenous leukaemia. The t(8;21) was not detected in the chronic phase, and was the only additional chromosomal anomaly in the blastic clone. Reverse transcription-polymerase chain reaction revealed the AML1/ETO fusion transcript in the cells of blastic phase but not in those of chronic phase. Regarding t(9;22), the breakpoint on chromosome 22 occurred in the mu-BCR region of the BCR gene, resulting in hybrid BCR/ABL mRNA with an e19a2 junction. Our findings provided molecular evidence that t(8;21) can occur as an additional genetic change in Philadelphia-positive chronic myelogenous leukaemia.
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PMID:Additional translocation (8;21)(q22;q22) in a patient with Philadelphia-positive chronic myelogenous leukaemia in the blastic phase. 1102 93

AML1/MTG8 was quantified relative to the expression of the GAPDH housekeeping gene by real-time RT-PCR in 22 patients with t(8;21)-positive acute myeloblastic leukaemia (AML) at initial diagnosis and in seven of these patients also during/after chemotherapy and allogeneic bone marrow transplantation. Real-time PCR was able to specifically detect and quantify AML1/MTG8 over a 5 log range. The detection limit for t(8;21)-positive cells was a dilution of 1:105. The AML1/MTG8 expression varied considerably among the 22 AML patients at intial diagnosis with a ratio AML1/MTG8:GAPDH of 0.5135+/-0.536 (range 0.1-2.14, median 0.318). In six patients with t(8;21)-positive AML a marked decline of AML1/MTG8 could be induced by chemotherapy. These patients are in ongoing complete haematological remission (CR) with a constant low-level AML1/MTG8 expression. In another patient a rapid rise of AML1/MTG8 transcripts could be detected in CR after allogeneic bone marrow transplantation and the patient relapsed 10 weeks later. In conclusion, real-time RT-PCR is a suitable approach for the quantification of AML1/MTG8 transcripts in the monitoring of AML patients with t(8;21) during/after chemotherapy and can provide data of prognostic relevance.
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PMID:Real-time RT-PCR for the detection and quantification of AML1/MTG8 fusion transcripts in t(8;21)-positive AML patients. 1052 27

The chromosomal translocation t(8;21)(q22;q22) is one of the most frequent karyotypic aberrations in acute myeloid leukemia (AML) and results in a chimeric fusion transcript AML1/MTG8. Since AML1/MTG8 fusion transcripts remain detectable by RT-PCR in t(8;21) AML patients in long-term hematological remission, quantitative assessment of AML1/MTG8 transcripts is necessary for the monitoring of minimal residual disease (MRD) in these patients. Competitive RT-PCR and recently real-time RT-PCR are increasingly used for detection and quantification of leukemia specific fusion transcripts. For the direct comparison of both methods we cloned a 42 bp DNA fragment into the original AML1/MTG8 sequence. The resulting molecule was used as an internal competitor for our novel competitive nested RT-PCR for AML1/MTG8 and as an external standard for the generation of AML1/MTG8 standard curves in a real-time PCR assay. Using this standard molecule for both PCR techniques, we compared their sensitivity, linearity and reproducibility. Both methods were comparable with regard to all parameters tested irrespective of analyzing serial dilutions of plasmids, cell lines or samples from t(8;21) positive AML patients at different stages of the disease. Therefore, both techniques can be recommended for the monitoring of MRD in these particular AML patients. However, the automatization of the real-time PCR technique offers some technical advantages.
Leukemia 2000 Feb
PMID:Comparison of nested competitive RT-PCR and real-time RT-PCR for the detection and quantification of AML1/MTG8 fusion transcripts in t(8;21) positive acute myelogenous leukemia. 1067 53

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