UMLS:C0023418 - FACTA Search

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Query: UMLS:C0023418 (leukemia)
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A patient with secondary acute myelomonocytic leukemia after treatment with chronic oral etoposide (VP-16) for lung cancer is reported. The leukemic cells showed a t(9;11)(p22;q23) translocation. Southern blot analysis revealed the rearrangement of the MLL (ALL-1/HRX) gene at 11q23. Reverse transcriptase-polymerase chain reaction (RT-PCR) revealed a chimeric mRNA between the MLL gene at 11q23 and LTG9 (MLLT3/AF-9) gene at 9p22. The patient was successfully treated with a VP-16 based regimen. This case is instructive in the understanding of the leukemogenesis of VP-16-related leukemias.
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PMID:Acute myelomonocytic leukemia after treatment with chronic oral etoposide: are MLL and LTG9 genes targets for etoposide? 794 64

We describe a patient with acute monocytic leukemia (M5a, FAB classification) associated with a new type of variant translocation (9;11). Southern blot analysis showed the rearrangement of the MLL (ALL-1/HRX) gene at 11q23. Fluorescence in situ hybridization (FISH) with painting probes of chromosomes 9, 11, and 22 revealed the translocation as t(9;11;22) (p22;q23;q11). This is more evidence that the production of chimeric mRNA following the translocation of the LTG9 (MLLT3/AF9) gene at 9p22 to 11q is a critical event in this leukemia subtype.
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PMID:Translocation (9;11;22)(p22;q23;q11). A new type of complex variant translocation of t(9;11)(p22;q23) with MLL rearrangement. 863 Sep 74

11q23 chromosome aberrations are frequently observed in infantile as well as therapy-related leukemias. The target gene at 11q23, MLL, is disrupted by the translocation and becomes fused to various translocation partner genes such as AF4/FEL, LTG9/AF9 and LTG19/ENL. The resulting chimeric mRNAs are fused in frame and have been predicted to encode leukemia-specific chimeric proteins. In the present study, we raised antibodies against MLL, LTG9 and LTG19 and demonstrated that MLL and chimeric MLL-LTG9 and MLL-LTG19 products are synthesized in vivo and are localized in the nuclei, using immunofluorescence and cell fractionation studies. The truncated N-terminal portion of the MLL product common to the various types of 11q23 translocation was also localized in the nuclei in a similar fashion. Murine 32Dc13 cells stably expressing the truncated N-terminal MLL protein exhibited an inhibition of differentiation and a growth advantage following stimulation by granulocyte-colony stimulating factor, although the IL-3 dependency was not significantly changed in comparison to the parental cells. These results suggest that the N-terminal portion common to various MLL-chimeric products plays an important role in leukemogenesis.
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PMID:Identification of MLL and chimeric MLL gene products involved in 11q23 translocation and possible mechanisms of leukemogenesis by MLL truncation. 893 41

A 20-year-old Japanese man was referred because of severe pancytopenia with 14% of abnormal blasts in hypocellular bone marrow. After treatment by granulocyte colony-stimulating factor (G-CSF) and transfusions of red blood cells, spontaneous remission was subsequently achieved. After 3 months' remission, however, the patient developed AML characterized by the abnormal karyotype: 46XY,+8,t(9;11)(p22;q23). FISH study revealed the presence of trisomy 8 clone also in the hypoplastic state. While MLL-AF9 chimeric mRNA was observed in leukemic cells, it was not detectable in bone marrow cells from the hypoplastic state by RT-PCR. This is the first report of a trisomy 8 clone which evolved into one with a MLL gene rearrangement.
Leukemia 1997 Aug
PMID:Clonal evolution to acute myeloblastic leukemia with MLL gene rearrangement from trisomy 8 clone. 926 97

We describe two new human leukemia cell lines, MOLM-13 and MOLM-14, established from the peripheral blood of a patient at relapse of acute monocytic leukemia, FAB M5a, which had evolved from myelodysplastic syndrome (MDS). Both cell lines express monocyte-specific esterase (MSE) and MLL-AF9 fusion mRNA. Gene fusion is associated with a minute chromosomal insertion, ins(11;9)(q23;p22p23). MOLM-13 and MOLM-14 are the first cell lines with, and represent the third reported case of, MLL gene rearrangement arising via chromosomal insertion. Both cell lines carry trisomy 8 which was also present during the MDS phase, as well as the most frequent trisomies associated with t(9;11), ie, +6, +13, +19 variously present in different subclones. Despite having these features in common, differences in antigen expression were noted between the two cell lines: that of MOLM-13 being CD34+, CD13-, CD14-, CD15+, CD33+; whereas MOLM-14 was CD4+, CD13+, CD14+, CD15+, CD33+. Differentiation to macrophage-like morphology could be induced in both cell lines after stimulation with INF-gamma alone, or in combination with TNF-alpha, which treatment also induced or upregulated, expression of certain myelomonocyte-associated antigens, including CD13, CD14, CD15, CD64, CD65 and CD87. Together, these data confirm that both cell lines are likely to be novel in vitro models for studying monocytic differentiation and leukemogenesis.
Leukemia 1997 Sep
PMID:Two acute monocytic leukemia (AML-M5a) cell lines (MOLM-13 and MOLM-14) with interclonal phenotypic heterogeneity showing MLL-AF9 fusion resulting from an occult chromosome insertion, ins(11;9)(q23;p22p23). 930

The MLL gene at chromosome 11, band q23, is involved in translocations with as many as 40 different chromosomal bands. Virtually all breakpoints occur within an 8.3 kb BamHI fragment and result in 5' MLL fused to partner genes in a 5'-3' orientation. The translocation t(9;11)(p22;q23), which results in the fusion of MLL to AF9, is the most common of the 11q23 chromosomal abnormalities observed in de novo acute myeloid leukemia (AML), in therapy related leukemia (t-AML), and rarely in acute lymphoblastic leukemia (ALL). We have studied 24 patients with a t(9;11) and an MLL rearrangement, including 19 patients with AML, four with t-AML, and one with ALL. To understand the mechanisms of this illegitimate recombination, we cloned and sequenced the t(9;11) translocation breakpoint junctions on both derivative chromosomes from one AML patient and from the Mono Mac 6 (MM6) cell line, which was derived from a patient with AML. Two different complex junctions were noted. In the AML patient, both chromosome 11 and 9 breaks were staggered, occurred in Alu DNA sequences, and resulted in a 331 bp duplication. In the MM6 cell line, breaks in chromosomes 11 and 9 were also staggered, but, in contrast to the finding in the AML patient, the breaks did not involve Alu DNA sequences and resulted in a 664 bp deletion at the breakpoints. Using reverse transcriptase (RT-) PCR, we analyzed 11 patient samples, including the two just described, for MML-AF9 fusions. The fusion occurred in six of seven AML patients, two of two t-AML patients, one patient with ALL, and in the MM6 cell line. Interestingly, all of the breaks within the AF9 gene in AML patients occurred in the central AF9 exon, called Site A by others, whereas in the single ALL patient the breakpoint mapped to a more 3' region of the AF9 gene. Our data, when combined with those of others, suggest that the fusion point within the AF9 gene, and thus the amount of AF9 material included in the MLL-AF9 fusion gene product, may influence the phenotype of the resulting leukemia. This further supports the proposal that the MML translocation partner genes play a critical role in the leukemogenic process.
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PMID:Identification of complex genomic breakpoint junctions in the t(9;11) MLL-AF9 fusion gene in acute leukemia. 933 69

The t(9;11)(p22;q23) is the most common chromosomal translocation in topoisomerase II inhibitor therapy-related acute myeloid leukemia (tAML). This translocation fuses the MLL and AF9 proto-oncogenes producing a novel chimeric protein. In order to gain insight into the mechanism generating the t(9;11) and to clarify the role topoisomerase II inhibition may play in that mechanism we have cloned and sequenced the breakpoints from four tAML patients with the t(9;11). This sequence analysis identifies topoisomerase II consensus binding sequences near or at the chromosome 11 and chromosome 9 breakpoints in all four patients. One patient also had the consensus binding sequence for the TRANSLIN DNA-binding protein at the 9p22 and 11q23 breakpoints. Our results further support a direct role for topoisomerase II in the genesis of these tAML translocations.
Leukemia 1998 Dec
PMID:Cloning and sequence analysis of four t(9;11) therapy-related leukemia breakpoints. 984 20

The MLL gene from human chromosome 11q23 is involved in >30 different chromosomal translocations resulting in a plethora of different MLL fusion proteins. Each of these tends to associate with a specific leukaemia type, for example, MLL-AF9 is found mainly in acute myeloid leukaemia. We have studied the role of the Mll-AF9 gene fusion made in mouse embryonic stem cells by an homologous recombination knock-in. Acute leukaemias developed in heterozygous mice carrying this fusion as well as in chimeric mice. As with human chromosomal translocation t(9;11), the majority of cases were acute myeloid leukaemias (AMLs) involving immature myeloblasts, but a minority were acute lymphoblastic leukaemia. The AMLs were preceded by effects on haematopoietic differentiation involving a myeloproliferation resulting in accumulation of Mac-1/Gr-1 double-positive mature myeloid cells in bone marrow as early as 6 days after birth. Therefore, non-malignant expansion of myeloid precursors is the first stage of Mll-AF9-mediated leukaemia followed by accumulation of malignant cells in bone marrow and other tissues. Thus, the late onset of overt tumours suggests that secondary tumorigenic mutations are necessary for malignancy associated with MLL-AF9 gene fusion and that myeloproliferation provides the pool of cells in which such events can occur.
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PMID:The mll-AF9 gene fusion in mice controls myeloproliferation and specifies acute myeloid leukaemogenesis. 1039 73

One of the most common chromosomal abnormalities in acute leukemia is a reciprocal translocation involving the HRX gene (also called MLL, ALL-1, or HTRX) at chromosomal locus 11q23, resulting in the formation of HRX fusion proteins. Using the yeast two-hybrid system and human cell culture coimmunoprecipitation experiments, we show here that HRX proteins interact directly with the GADD34 protein. We have found that transfected cells overexpressing GADD34 display a significant increase in apoptosis after treatment with ionizing radiation, indicating that GADD34 expression not only correlates with apoptosis but also can enhance apoptosis. The amino-terminal third of the GADD34 protein was necessary for this observed increase in apoptosis. Furthermore, coexpression of three different HRX fusion proteins (HRX-ENL, HRX-AF9, and HRX-ELL) had an anti-apoptotic effect, abrogating GADD34-induced apoptosis. In contrast, expression of wild-type HRX gave rise to an increase in apoptosis. The difference observed here between wild-type HRX and the leukemic HRX fusion proteins suggests that inhibition of GADD34-mediated apoptosis may be important to leukemogenesis. We also show here that GADD34 binds the human SNF5/INI1 protein, a member of the SNF/SWI complex that can remodel chromatin and activate transcription. These studies demonstrate, for the first time, a gain of function for leukemic HRX fusion proteins compared to wild-type protein. We propose that the role of HRX fusion proteins as negative regulators of post-DNA-damage-induced apoptosis is important to leukemia progression.
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PMID:Leukemic HRX fusion proteins inhibit GADD34-induced apoptosis and associate with the GADD34 and hSNF5/INI1 proteins. 1049 Jun 42

Twenty-seven patients with AML and MLL gene rearrangement were analyzed by a reverse transcriptase polymerase chain reaction (RT-PCR) for the MLL-AF9 translocation. The MLL-AF9 fusion transcript was detected in six patients. In five patients, the breakpoint of the AF9 gene was located within the recently described site A; in one patient, a novel breakpoint (AF9 site D) mapped to a position 377 bp 3' of site A. Five patients could be serially monitored for a period of 4-23 months. Two patients became two-step PCR negative in bone marrow and peripheral blood. Molecular remission was achieved rapidly after one cycle of induction chemotherapy. Both patients are in continuous complete remission (CR) at 22 and 15 months, respectively. Two patients who had achieved hematological CR did not become PCR negative and MLL-AF9 fusion transcripts were detectable in all samples after induction and consolidation chemotherapy. One patient relapsed 5 months after achieving CR. The other patient received allogeneic bone marrow transplantation from an HLA-identical sibling 2 months after achieving hematological CR and became PCR negative 4 weeks after transplantation. In the fifth patient, hematological CR could not be achieved with two cycles of intensive induction chemotherapy, and MLL-AF9 transcripts were present in all samples tested. Our data indicate that MLL-AF9 RT-PCR is specific for the t(9;11) translocation. PCR negativity can be achieved in responding patients already 1 month after induction chemotherapy. The fast reduction of MLL-AF9 positive blast cells below the detection limit of RT-PCR seems to be a prerequisite for long-term CR. The results of RT-PCR may be useful for treatment decisions (eg BMT).
Leukemia 1999 Oct
PMID:Monitoring of minimal residual leukemia in patients with MLL-AF9 positive acute myeloid leukemia by RT-PCR. 1051 52

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