EC:5.99.1.2 - FACTA Search

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Query: EC:5.99.1.2 (topoisomerase)
9,166 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

MLL rearrangements in acute myeloid leukemia (AML) include translocations and intragenic abnormalities such as internal duplication and breakage induced by topoisomerase II inhibitors. In adult AML, FLT3 internal tandem duplications (ITDs) are more common in cases with MLL intragenic abnormalities (33%) than those with MLL translocation (8%). Mutation/deletion involving FLT3 D835 are found in more than 20% of cases with MLL intragenic abnormalities compared with 10% of AML with MLL translocation and 5% of adult AML with normal MLL status. Real-time quantification of FLT3 in 141 cases of AML showed that all cases with FLT3 D835 express high level transcripts, whereas FLT3-ITD AML can be divided into cases with high-level FLT3 expression, which belong essentially to the monocytic lineage, and those with relatively low-level expression, which predominantly demonstrate PML-RARA and DEK-CAN. FLT3 abnormalities in CBF leukemias with AML1-ETO or CBFbeta-MYH11 were virtually restricted to cases with variant CBFbeta-MYH11 fusion transcripts and/or atypical morphology. These data suggest that the FLT3 and MLL loci demonstrate similar susceptibility to agents that modify chromatin configuration, including topoisomerase II inhibitors and abnormalities involving PML and DEK, with consequent errors in DNA repair. Variant CBFbeta-MYH11 fusions and bcr3 PML-RARA may also be initiated by similar mechanisms.
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PMID:FLT3 and MLL intragenic abnormalities in AML reflect a common category of genotoxic stress. 1279 58

MLL gene fusions are the hallmark of more than 70% of therapy-related leukemias (t-ML) associated with topoisomerase II inhibitors (e.g., etoposide) and cause leukemia in murine transgenic models. To determine whether Mll genomic fusions can occur after exposure to topoisomerase II inhibitors, we developed a long-distance inverse PCR DNA-based assay for chimeric Mll fusions in mouse embryonic stem cells. We detected Mll fusions at a higher frequency following 100 microM etoposide for 8 h (16x10(-6) cell(-1)) than in no-drug controls (1.0x10(-6) cell(-1), P=0.0002) or after treatment with a comparably cytotoxic exposure to the antimicrotubule drug vincristine (1.0x10(-6) cell(-1), P=0.0047). The fusion points in Mll chimeric products induced by etoposide were localized to a 1.5 kb region between exons 9 and 11, analogous to the MLL breakpoint cluster region in human leukemia. All 49 Mll fusion partners analyzed matched known genomic murine sequences, with 40 (82%) matching annotated genes covering eighteen murine autosomes. One partner was Runx1, the murine homologue of the transcription factor AML-1, a target of human translocations in therapy-related leukemia. These findings indicate that etoposide triggers the formation of Mll gene fusions, a critical step for the development of treatment-induced leukemic transformation.
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PMID:Etoposide induces chimeric Mll gene fusions. 1463 Jun 94

We report the development of therapy-related early pre-B acute lymphoblastic leukemia in a patient administered a topoisomerase II inhibitor, etoposide, a consolidation therapy agent for acute promyelocytic leukemia. Our case is of interest because of simultaneous relapse of the original leukemia and onset of therapy-related leukemia and relatively rare t(1;11)(p32;q23) translocation with confirmed MLL/AF-1p fusion. This case suggests that careful monitoring for MLL gene rearrangements is necessary after administration of topoisomerase II inhibitors.
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PMID:MLL/AF-1p fusion in therapy-related early pre-B acute lymphoblastic leukemia with t(1;11)(p32;q23) translocation developing in the relapse phase of acute promyelocytic leukemia. 1470 37

The MLL (Mixed Lineage Leukaemia or Myeloid/Lymphoid Leukaemia) gene on chromosome 11q23 is frequently involved in chromosomal translocations associated with human acute leukaemias. These translocations lead to fusion genes generally resulting in novel chimeric proteins containing the amino terminus of MLL fused in-frame to one of about 30 distinct partner proteins. Abnormalities involving the MLL gene are observed in leukaemias of either lymphoid or myeloid lineage derivation, as well as in poorly differentiated or biphenotypic leukaemias. They are frequently seen in infant patients, and patients with therapy-related secondary AML following treatment with inhibitors of topoisomerase II (epipodophyllotoxins). In the majority of cases, abnormalities involving the MLL gene are associated with a very poor prognostic outcome. In this review, we will discuss some of the recent advances in MLL research resulting from biological as well as clinical studies.
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PMID:The biological and clinical significance of MLL abnormalities in haematological malignancies. 1529 2

The recurring chromosome translocation t(11;16)(q23;p13) is detected in leukemia patients, virtually all of whom have received previous chemotherapy with topoisomerase (topo) II inhibitors. In the t(11;16), 3' CBP, on 16p13, is fused to 5' MLL, on 11q23, resulting in an MLL-CBP fusion gene that plays an important role in leukemogenesis. In this study, we cloned genomic breakpoints of the MLL and CBP genes in the t(11;16) in the SN-1 cell line and in five patients with therapy-related leukemia, all of whom had received topo II inhibitors for previous tumors. In all patients except one, both the genomic MLL-CBP and the reciprocal fusions were cloned. Genomic breakpoints in MLL occurred in the 8.3-kb breakpoint cluster region in all patients, whereas the breakpoints in CBP clustered in an 8.2-kb region of intron 3 in four patients. Genomic breakpoints in MLL occurred in intron 11 near the topo II cleavage site in the SN-1 cell line and in one patient, and they were close to LINE repetitive sequences in two other patients. In the remaining two patients, genomic breakpoints were in intron 9 in Alu repeats. Genomic breakpoints in CBP occurred in and around Alu repeats in one and two patients, respectively. In two patients, the breaks were near LINE repetitive sequences, suggesting that repetitive DNA sequences may play a role. No specific recombination motifs were identified at or near the breakpoint junctions. No topo II cleavage sites were detected in introns 2 and 3 of CBP. However, there were deletions and duplications at the breakpoints in both MLL and CBP and microhomologies or nontemplated nucleotides at most of the genomic fusion junctions, suggesting that a nonhomologous end-joining repair mechanism was involved in the t(11;16).
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PMID:Characterization of genomic breakpoints in MLL and CBP in leukemia patients with t(11;16). 1533 49

Therapy-related acute myeloid leukemia (t-AML) characterized by the t(9;11)(p22;q23) translocation is one of the most frequent secondary malignancies. The timing of the initiation of translocation and of development of the malignant t(9;11) clone during chemotherapy is presently unknown. In the present study, we backtracked bone marrow samples from three children during treatment for acute lymphoblastic leukemia (ALL). Two patients developed a t(9;11)-positive t-AML 19 and 30 months after therapy start, whereas the third patient, diagnosed with a rare t(9;11)-positive ALL, suffered from an ALL relapse 23 months after initial diagnosis. The genomic MLL-MLLT3 (MLL-AF9) fusion site was amplified by a multiplex, nested long-range PCR and used as a clonal marker for quantification of the MLL-MLLT3-positive cells during chemotherapy. The t(9;11)-positive clone was detectable 13 and 18 months after therapy start in both t-AML cases, which was 6-12 months before clinical diagnosis of the secondary malignancy. In the t(9;11)-positive ALL patient, the identical leukemic clone reoccurred during maintenance therapy after a short molecular remission, 8 months before clinically overt ALL relapse. The time course and characteristics of the genomic breakpoints in the present t-AML cases support the hypothesis of translocation formation as a result of defective breakage repair after topoisomerase II cleavage.
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PMID:Emergence of translocation t(9;11)-positive leukemia during treatment of childhood acute lymphoblastic leukemia. 1533 54

Rearrangements involving the MLL gene on chromosome band 11q23 are a hallmark of therapy-related acute myeloid leukemias following treatment with topoisomerase II poisons including etoposide. Therapy-related and de novo genomic translocation breakpoints cluster within a well-characterized 8.3-kb fragment of MLL. Repair of etoposide-stabilized DNA topoisomerase II covalent complexes may initiate MLL rearrangements observed in patients. We used a culture system of primary human hematopoietic CD34+ cells and inverse polymerase chain reaction to characterize the spectrum of stable genomic rearrangements promoted by etoposide exposure originating within an MLL translocation hotspot in therapy-related leukemia. Alterations to the region were observed at a readily detectable frequency in etoposide-treated cells. Illegitimate repair events after minimal repair included MLL tandem duplications and translocations, with minor populations of deletions or insertions. In stably repaired cells that proliferated for 10 to 14 days, the significant majority of illegitimate events were MLL tandem duplications, and several deletions, inversions, insertions, and translocations. Thus, etoposide promotes specific rearrangements of MLL consistent with the full spectrum of oncogenic events identified in leukemic samples. Although etoposide-initiated rearrangements are frequent, only a small subset of translocations occurs in cells that proliferate significantly.
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PMID:Therapy-related acute myeloid leukemia-like MLL rearrangements are induced by etoposide in primary human CD34+ cells and remain stable after clonal expansion. 1574

The MLL gene, located within band 11q23, has been shown to be involved in translocations with a large variety of reciprocal sites in both lymphoid and myeloid leukemia and has also been shown to undergo submicroscopic self-fusion/partial duplication. We report 29 patients with cytogenetic evidence of 11q23 alteration, all of which demonstrate molecular cytogenetic evidence of amplification of the MLL gene by fluorescence in situ hybridization (FISH). In all MLL cases, the patients were clinically classified as having transforming myelodysplasia (RAEB/RAEBT) or AML. An additional patient with AML was found by 24-color and gene-specific FISH to have AML1 oncogene amplification. Four patients had been previously diagnosed with cancer and had received topoisomerase II targeted drug therapy which is known to be associated with fusion transcripts involving the MLL and AML1 genes. MLL amplification appeared in various forms: an atypical banded region that bridges from 11q23 into a dicentric chromosome, expanded regions emanating from band 11q23, chromosome 11 paint-positive rings with "spoke-like" MLL amplification, and expansion at sites other than chromosome 11 (including extra markers) in the absence of one of the 11 homologues. The fluorescence pattern in most cases suggests palindromic duplication with neighboring sequences in the long arm of chromosome 11. As opposed to MYCN amplification in hsrs (homogeneously staining regions) and double minutes in neuroblastoma, amplification of MLL in most cases occurred at the site of the gene. All of our patients rapidly developed refractory AML. The frequency and clinical correlations of MLL gene amplification in leukemia will need careful follow-up, since the frequently cryptic amplification described in these cases may not generally provoke confirmatory FISH studies. The reported MLL cases represented about 1% of the total abnormal MDS/AML cases over 8 years. A common cytogenetic profile of 5 q-, -17/17 p-, -18/18 q-, and a missing or abnormal chromosome 11, may help direct appropriate follow-up studies. The MLL and the AML1 oncogenes appear to be the only oncogenes amplified at the natural site of the gene. Both genes also show a high degree of diversity of pathogenic mechanisms of leukemia evolution, including numerous reciprocal fusion genes in transformation to either AML or ALL and gain of function amplification.
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PMID:Oncogene amplification in transforming myelodysplasia. 1602 82

Exposure to topoisomerase II inhibitors is linked to the generation of leukemia involving translocations of the MLL gene, normally restricted to an 8.3 kbp tract, the breakpoint cluster region (BCR). Using an in vitro assay, apoptotic activators, including radiation and anti-CD95 antibody, trigger site-specific cleavage adjacent to exon 12 within the MLL BCR and promote translocation of the MLL gene in cells that can survive. To explore the mechanism of cleavage and rearrangement in more detail, the entire MLL BCR was placed into the pREP4 episomal vector and transfected into human lymphoblastoid TK6 cells. Episomes containing either the MLL BCR, or deletion constructs of 367 bp or larger, were cleaved at the same position as genomic MLL after exposure to apoptotic stimuli. Further analysis of sequence motifs surrounding the cleaved region of MLL showed the presence of both a predicted nuclear matrix attachment sequence and a potential strong binding site for topoisomerase II, flanking the site of cleavage. Inactivation of topoisomerase II by the catalytic inhibitor merbarone did not inhibit MLL cleavage, suggesting that the initial cleavage step for MLL rearrangement is not mediated by topoisomerase II.
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PMID:Cleavage of the MLL gene by activators of apoptosis is independent of topoisomerase II activity. 1619 84

Phenomena involving the disassembly of chromosomes to approximately 50 kbp double-stranded fragments upon protein denaturing treatments of normal and apoptotic mammalian nuclei as well as yeast protoplasts may be an indication of special, hypersensitive regions positioned regularly at loop-size intervals in the eukaryotic chromatin. Here we show evidence in yeast cell systems that loop-size fragmentation can occur in any phase of the cell cycle and that the plating efficiency of these cells is approximately 100%. The possibility of sequence specificity was investigated within the breakpoint cluster region (bcr) of the human MLL gene, frequently rearranged in certain leukemias. Our data suggest that DNA isolated from yeast cultures or mammalian cell lines carry nicks or secondary structures predisposing DNA for a specific nicking activity, at non-random positions. Furthermore, exposure of MLL bcr-carrying plasmid DNA to S1 nuclease or nuclear extracts or purified topoisomerase II elicited cleavages at the nucleotide positions of nick formation on human genomic DNA. These data support the possibility that certain sequence elements are preferentially involved in the cleavage processes responsible for the en masse disassembly of chromatin to loop-size fragments upon isolation of DNA from live eukaryotic cells.
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PMID:Nick-forming sequences may be involved in the organization of eukaryotic chromatin into approximately 50 kbp loops. 1619 88

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