UMLS:C0598766 - FACTA Search

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Query: UMLS:C0598766 (leukemogenesis)
4,065 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The t(11;19)(q23;p13.1) chromosomal translocation in acute myeloid leukemias fuses the gene encoding transcriptional elongation factor ELL to the MLL gene with consequent expression of an MLL-ELL chimeric protein. To identify potential mechanisms of leukemogenesis by MLL-ELL, its transcriptional and oncogenic properties were investigated. Fusion with MLL preserves the transcriptional elongation activity of ELL but relocalizes it from a diffuse nuclear distribution to the nuclear bodies characteristic of MLL. Using a serial replating assay, it was demonstrated that the MLL-ELL chimeric protein is capable of immortalizing clonogenic myeloid progenitors in vitro after its retroviral transduction into primary murine hematopoietic cells. However, a structure-function analysis indicates that the elongation domain is not essential for myeloid transformation because mutants lacking elongation activity retain a potent ability to immortalize myeloid progenitors. Rather, the highly conserved carboxyl terminal R4 domain is both a necessary and a sufficient contribution from ELL for the immortalizing activity associated with MLL-ELL. The R4 domain demonstrates potent transcriptional activation properties and is required for transactivation of a HoxA7 promoter by MLL-ELL in a transient transcriptional assay. These data indicate that neoplastic transformation by the MLL-ELL fusion protein is likely to result from aberrant transcriptional activation of MLL target genes. Thus, in spite of the extensive diversity of MLL fusion partners, these data, in conjunction with previous studies of MLL-ENL, suggest that conversion of MLL to a constitutive transcriptional activator may be a general model for its oncogenic conversion in myeloid leukemias. (Blood. 2000;96:3887-3893)
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PMID:A carboxy-terminal domain of ELL is required and sufficient for immortalization of myeloid progenitors by MLL-ELL. 1109 74

In order to identify genomic changes associated with an etoposide resistance acquisition, we used comparative genomic hybridization (CGH) to compare a human lung adenocarcinoma cell line, A549 wild type, and three sublines, A549-VP1-3, exposed to increasing concentrations of the topoisomerase II inhibitor, VP16. R-banding karyotype, fluorescence in situ hybridization (FISH), and Southern blot for the MLL gene were also performed. The CGH analysis showed that the A549-VP3 cell line shared chemoresistance-specific abnormalities (amplification of 11q23-qter, loss of chromosome 17, and deletions of 2p14-pter and 2q23-q24). FISH analysis confirmed the loss of one chromosome 17 in the three resistant sublines and revealed an increased fragmentation of chromosome 2 in more than two segments, depending on the etoposide concentration. FISH with an MLL gene probe showed additional signals of MLL (from three in the A549-WT to seven in the A549-VP3 cell line) translocated onto several other chromosomes. Southern blot indicated an amplification of the MLL gene, dependent on the etoposide concentration, without gene rearrangement. The CGH results are suggestive of loci that could be associated with the acquisition of an etoposide-chemoresistant phenotype. Deletion of the 2p region has already been reported, without any candidate gene being identified. The role of MLL in leukemogenesis has previously been demonstrated, but its role in the development of other tumors or its significance in the chemoresistance process remains to be elucidated.
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PMID:Identification of chromosomal loci associated with non-P-glycoprotein-mediated multidrug resistance to topoisomerase II inhibitor in lung adenocarcinoma cell line by comparative genomic hybridization. 1113 30

TEL-AML1 fusion resulting from the t(12;21)(p13;q22) is one of the most common genetic abnormalities in childhood acute lymphoblastic leukemia. Recent findings that site-specific cleavage of the MLL gene can be induced by chemotherapeutic agents such as topoisomerase-II inhibitors suggest that apoptogenic agents can cause chromosomal translocations in hematopoietic cells. This study demonstrates a possible relationship between exposure to apoptogenic stimuli, TEL breaks, and the formation of TEL-AML1 fusion in immature B lymphocytes. Short-term culture of immature B cell lines in the presence of apoptogenic stimuli such as serum starvation, etoposide, or salicylic acid induced double-strand breaks (DSBs) in intron 5 of the TEL gene and intron 1 of the AML1 gene. TEL-AML1 fusion transcripts were also identified by reverse transcriptase-polymerase chain reaction (RT-PCR) analysis in cell lines treated by serum starvation or aminophylline. DSBs within the TEL gene were also associated with fusion to other unknown genes, presumably as a result of chromosomal translocation. We also examined 67 cord blood and 147 normal peripheral blood samples for the existence of in-frame TEL-AML1 fusion transcripts. One cord blood sample (1.5%) and 13 normal peripheral blood samples (8.8%) were positive as detected by nested RT-PCR. These data suggest that breakage and fusion of TEL and AML1 may be relatively common events and that sublethal apoptotic signals could play a role in initiating leukemogenesis via the promotion of DNA damage.
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PMID:Breakage and fusion of the TEL (ETV6) gene in immature B lymphocytes induced by apoptogenic signals. 1115 92

We report on an adult patient with de novo acute myeloid leukemia (AML) with a t(11;22)(q23;q11.2) involving CDCREL1 and MLL genes. Reverse transcriptase (RT)-polymerase chain reaction (PCR) followed by direct sequencing analysis revealed the MLL-CDCREL1 fusion transcript in his leukemic cells. Analysis of the fusion transcript showed that exon 6 of MLL was fused to exon 4 of CDCREL1, which contains an AT-hook domain of MLL and a GTP binding domain of CDCREL1. To investigate the roles of CDCREL1 further, we examined the expression of the CDCREL1 gene in various cell lines. Expression of CDCREL1 was detected in 11 (85%) of 13 AML cell lines and 3 (21%) of 14 acute lymphoblastic leukemia (ALL) cell lines, but none of 11 EB virus transformed B-cell lines by RT-PCR. The expression rate of CDCREL1 was significantly higher in AML cell lines than in ALL cell lines (P = 0.0035). Platelet glycoprotein 1B beta (GP1B beta), which is located downstream of CDCREL1 and is cotranscribed with CDCREL1 due to a nonconsensus polyadenylation sequence, was expressed in all these cell lines. The higher expression rate of CDCREL1 in AML cell lines than in ALL cell lines suggests that this gene may play some role in myeloid leukemogenesis.
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PMID:The CDCREL1 gene fused to MLL in de novo acute myeloid leukemia with t(11;22)(q23;q11.2) and its frequent expression in myeloid leukemia cell lines. 1117 Feb 79

Acute myeloid leukemias (AMLs) are consistently associated with chromosomal rearrangements that result in the generation of chimeric genes and fusion proteins. One of the two affected genes is frequently a transcription factor Involved in the regulation of hematopoletic differentiation. Recent findings suggest a common leukemogenic mechanism for the fused transcription factor: abnormal recruitment of histone deacetylase (HDAC)-containing complexes to its target promoters. Inhibition of HDAC enzymatic activity reverts the leukemic phenotype in vitro and therefore represents a plausible strategy for antileukemic therapy. In this review, we first briefly describe the molecular structure and mechanisms of the most frequent AML associated fusion proteins (RAR, MLL, and CBF fusions) and then summarize available knowledge about their effects on the nuclear architecture. We propose that alteration of nuclear compartmentalization might represent an additional common mechanism of leukemogenesis.
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PMID:Effects of the acute myeloid leukemia--associated fusion proteins on nuclear architecture. 1117 39

The translocation t(11;19) is frequently found in acute leukemia in infants. This event truncates the proto-oncogene MLL and fuses the 5' end of MLL in frame with the ENL gene. ENL contributes a crucial protein-protein interaction domain to the resulting oncoprotein MLL-ENL. Here we show by yeast two-hybrid assays, GST-pull-down experiments and in a far western blot analysis that this domain is necessary and sufficient to recruit a novel member of the human Polycomb protein family (hPc3). hPc3 RNA was detected throughout the human hematopoietic system. Similar to other Polycomb proteins hPc3 acts as a transcriptional repressor. The ENL-hPc3 interaction was verified by mutual co-precipitation of the proteins from cell extracts. ENL and hPc3 tagged with fluorescent proteins co-localized in living cells in a nuclear dot pattern. An internal region of hPc3 was responsible for binding to ENL. Finally, hPc3 binds to the C-terminus of AF9, another common MLL fusion partner. The recruitment of a repressive function by ENL opens up a new insight into a possible mechanism of leukemogenesis by the fusion protein MLL-ENL.
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PMID:The ENL moiety of the childhood leukemia-associated MLL-ENL oncoprotein recruits human Polycomb 3. 1131 72

The t(4;11) translocation is the cytogenetic hallmark of a subset of acute lymphoblastic leukemias characterized by pro-B immunophenotype and a dismal prognosis. This translocation fuses the MLL gene on chromosome band 11q23 and the AF4 gene on 4q21, resulting in the expression of fusion transcripts from both translocated chromosomes. The MLL-AF4 chimeric transcript is thought to mediate the leukemic transformation. The MLL genomic disruption detected by Southern blot and the RT-PCR for the MLL-AF4 chimeric transcript expression are molecular evidence of this chromosomal translocation. However, similar molecular rearrangements have also been identified in cases without the cytogenetic t(4;11). We report a 30-year-old patient with high risk ALL, a normal karyotype, and molecular evidence of MLL-AF4 fusion. Using a double color FISH assay with MLL specific PAC probes, a cryptic t(4;11) due to insertion of 5' MLL sequences in chromosome 4q21 was demonstrated. Consequently the MLL-AF4 was encoded by der(4). This insertion mechanism precludes the genomic recombination of AF4-MLL and supports the crucial role played by MLL-AF4 in leukemogenesis. The findings of our case, along with others, show the importance of complementing the karyotype with molecular and FISH techniques.
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PMID:Cryptic t(4;11) encoding MLL-AF4 due to insertion of 5' MLL sequences in chromosome 4. 1136 62

The MLL-ELL chimeric gene is the product of the (11;19)(q23p13.1) translocation associated with de novo and therapy-related acute myeloid leukemias (AML). ELL is an RNA polymerase II elongation factor that interacts with the recently identified EAF1 (ELL associated factor 1) protein. EAF1 contains a limited region of homology with the transcriptional activation domains of three other genes fused to MLL in leukemias, AF4, LAF4, and AF5q31. Using an in vitro transformation assay of retrovirally transduced myeloid progenitors, we conducted a structure-function analysis of MLL-ELL. Whereas the elongation domain of ELL was dispensable, the EAF1 interaction domain of ELL was critical to the immortalizing properties of MLL-ELL in vitro. To confirm these results in vivo, we transplanted mice with bone marrow transduced with MLL fused to the minimal EAF1 interaction domain of ELL. These mice all developed AML, with a longer latency than mice transplanted with the wild-type MLL-ELL fusion. Based on these results, we generated a heterologous MLL-EAF1 fusion gene and analyzed its transforming potential. Strikingly, we found that MLL-EAF1 immortalized myeloid progenitors in the same manner as that of MLL-ELL. Furthermore, transplantation of bone marrow transduced with MLL-EAF1 induced AML with a shorter latency than mice transplanted with the MLL-ELL fusion. Taken together, these results indicate that the leukemic activity of MLL-ELL requires the EAF1 interaction domain of ELL, suggesting that the recruitment by MLL of a transactivation domain similar to that in EAF1 or the AF4/LAF4/AF5q31 family may be a critical common feature of multiple 11q23 translocations. In addition, these studies support a critical role for MLL partner genes and their protein-protein interactions in 11q23 leukemogenesis.
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PMID:The elongation domain of ELL is dispensable but its ELL-associated factor 1 interaction domain is essential for MLL-ELL-induced leukemogenesis. 1146 48

The recurrent translocation t(10;11) is associated with acute myeloid leukemia (AML). The AF10 gene on chromosome 10 at band p12 and MLL at 11q23 fuse in the t(10;11)(p12;q23). Recently, we have identified ABI1 as a new partner gene for MLL in an AML patient with a t(10;11)(p11.2;q23). The ABI1 is a human homologue of the mouse Abl-interactor 1 (Abi1), encoding an Abl-binding protein. The ABI1 protein exhibits sequence similarity to homeotic genes, and contains several polyproline stretches and a src homology 3 (SH3) domain. To clarify the clinical features of t(10;11)-leukemias, we investigated 6 samples from acute leukemia patients with t(10;11) and MLL rearrangement and detected MLL-AF10 chimeric transcripts in 5 samples and MLL-ABI1 in one. The patient with MLL-ABI1 chimeric transcript is the second case described, thus confirming that the fusion of the MLL and ABI1 genes is a recurring abnormality. Both of the patients with MLL-ABI1 chimeric transcript are surviving, suggesting that these patients have a better prognosis than the patients with MLL-AF10. To investigate the roles of AF10 and ABI1 further, we examined the expression of these genes in various cell lines and fresh tumor samples using the reverse transcriptase-polymerase chain reaction method. Although AF10 was expressed in almost all cell lines similarly, the expression patterns of ABI1 were different between leukemia and solid tumor cell lines, suggesting the distinctive role of each isoform of ABI1 in these cell lines. We also determined the complete mouse Abi1 sequence and found that the sequence matched with human ABI1 better than the originally reported Abi1 sequence. Further functional analysis of the MLL-AF10 and MLL-ABI1 fusion proteins will provide new insights into the leukemogenesis of t(10;11)-AML.
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PMID:t(10;11)-acute leukemias with MLL-AF10 and MLL-ABI1 chimeric transcripts: specific expression patterns of ABI1 gene in leukemia and solid tumor cell lines. 1147 55

The MLL (Mixed Lineage Leukemia) gene is a common target for chromosomal translocations associated with human acute leukemias. These translocations result in a gain of MLL function by generating novel chimeric proteins containing the amino-terminus of MLL fused in-frame with one of 30 distinct partner proteins. Structure/function studies using an in vitro myeloid progenitor immortalization assay have revealed that at least four nuclear partner proteins contribute transcriptional effector properties to MLL to produce a range of chimeric transcription factors with leukemogenic potential. Mouse models suggest that expression of an MLL fusion protein is necessary but not sufficient for leukemogenesis. Interestingly, whilst all MLL fusion proteins tested so far phenocopy each other with respect to in vitro immortalization, the latency period required for the onset of acute leukemia in vivo is variable and partner protein dependent. We discuss potential mechanisms that may account for the ability of distinct MLL fusion proteins to promote short or long latency leukemogenesis.
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PMID:Molecular mechanisms of leukemogenesis mediated by MLL fusion proteins. 1160 19

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