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Query: EC:5.99.1.3 (
topoisomerase
)
9,911
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The human myeloid-lymphoid leukemia gene, MLL (also called ALL-1, Htrx, or HRX ), maps to chromosomal band 11q23. MLL is involved in translocations that result in de novo acute lymphoblastic leukemia (ALL), acute myelogenous leukemia (AML), mixed lineage leukemia, and also in therapy AML (t-AML) and therapy ALL (t-ALL) resulting from treatment with
DNA topoisomerase II
(topo II) targeting drugs. MLL can recombine with more than 30 other chromosomal bands, of which 16 of the partner genes have been cloned. Breaks in MLL occur in an 8. 3-kb
breakpoint cluster region
(
BCR
) encompassing exons 5 through 11. We recently demonstrated that 75% of de novo patient breakpoints in MLL mapped in the centromeric half of the
BCR
between two scaffold-associated regions (SAR), whereas 75% of the t-AML patient breakpoints mapped to the telomeric half of the
BCR
within a strong SAR. We have mapped additional structural elements in the
BCR
. An in vivo DNA topo II cleavage site (induced with several different drugs that target topo II) mapped near exon 9 in three leukemia cell lines. A strong DNase I hypersensitive site (HS) also mapped near exon 9 in four leukemia cell lines, including two in which MLL was rearranged [a t(6;11) and a t(9;11)], and in two lymphoblastoid cell lines with normal MLL. Two of the leukemia cell lines also showed an in vivo topo II cleavage site. Our results suggest that the chromatin structure of the MLL
BCR
may influence the location of DNA breaks in both de novo and therapy-related leukemias. We propose that topo II is enriched in the MLL telomeric SAR and that it cleaves the DNase I HS site after treatment with topo II inhibitors. These events may be involved in recombination associated with t-AML/t-ALL breakpoints mapping in the MLL SAR.
...
PMID:An in vivo topoisomerase II cleavage site and a DNase I hypersensitive site colocalize near exon 9 in the MLL breakpoint cluster region. 980 73
Chromosomal translocations involving the MLL gene occur in about 80% of infant leukemia. In the search for possible agents inducing infant leukemia, we identified bioflavonoids, natural substances in food as well as in dietary supplements, that cause site-specific DNA cleavage in the MLL
breakpoint cluster region
(
BCR
) in vivo. The MLL
BCR
DNA cleavage was shown in primary progenitor hematopoietic cells from healthy newborns and adults as well as in cell lines; it colocalized with the MLL
BCR
cleavage site induced by chemotherapeutic agents, such as etoposide (VP16) and doxorubicin (Dox). Both in vivo and additional in vitro experiments demonstrated
topoisomerase
II (topo II) as the target of bioflavonoids similar to VP16 and Dox. Based on 20 bioflavonoids tested, we identified a common structure essential for topo II-induced DNA cleavage. Reversibility experiments demonstrated a religation of the bioflavonoid as well as the VP16-induced MLL cleavage site. Our observations support a two-stage model of cellular processing of topo II inhibitors: The first and reversible stage of topo II-induced DNA cleavage results in DNA repair, but also rarely in chromosome translocations; whereas the second, nonreversible stage leads to cell death because of an accumulation of DNA damage. These results suggest that maternal ingestion of bioflavonoids may induce MLL breaks and potentially translocations in utero leading to infant and early childhood leukemia.
...
PMID:Dietary bioflavonoids induce cleavage in the MLL gene and may contribute to infant leukemia. 1078 Oct 30
Leukemic cells have been shown to generate several classes of DNA fragments after treatment with cytotoxic cancer chemotherapy agents. However, it is unclear which of these fragmentation events are a direct effect of DNA-damaging chemotherapy agents, and which fragmentation events are caused by downstream processes, such as apoptosis. We have performed a detailed analysis of DNA fragmentation events which occur following cytotoxic chemotherapy in four representative leukemic cell lines (HL-60, Jurkat, K562, and Molt-4). We used a
DNA topoisomerase II
inhibitor (etoposide), an alkylating agent (melphalan), a nucleoside analog (cytosine arabinoside), and a non-genotoxic agent (N-methylformamide) to induce cell death. We studied high molecular weight and low molecular weight DNA fragmentation events, as well as the specific cleavage of the MLL
breakpoint cluster region
(
bcr
). The DNA fragments produced at late time points were largely independent of the agents used, while those generated at earlier time points showed clear differences in terms of fragment size and relative abundance, depending on the agent used. In addition, there were clear differences between cell lines in terms of size, relative abundance, and rate at which DNA fragments were produced by treatment with the same agents. We think that this survey documents the importance of studying several different cell lines, time points, and assays before reaching conclusions about the types of DNA fragments produced during treatment with cytotoxic agents, and provides a useful framework for studying a wide range of DNA fragments produced by cytotoxic agents.
...
PMID:Characterization of DNA fragmentation events caused by genotoxic and non-genotoxic agents. 1116 35
Chromosomal breakage resulting from stabilization of
DNA topoisomerase II
covalent complexes by epipodophyllotoxins may play a role in the genesis of leukemia-associated MLL gene translocations. We investigated whether etoposide catechol and quinone metabolites can damage the MLL
breakpoint cluster region
in a
DNA topoisomerase II
-dependent manner like the parent drug and the nature of the damage. Cleavage of two DNA substrates containing the normal homologues of five MLL intron 6 translocation breakpoints was examined in vitro upon incubation with human
DNA topoisomerase
IIalpha, ATP, and either etoposide, etoposide catechol, or etoposide quinone. Many of the same cleavage sites were induced by etoposide and by its metabolites, but several unique sites were induced by the metabolites. There was a preference for G(-1) among the unique sites, which differs from the parent drug. Cleavage at most sites was greater and more heat-stable in the presence of the metabolites compared to etoposide. The MLL translocation breakpoints contained within the substrates were near strong and/or stable cleavage sites. The metabolites induced more cleavage than etoposide at the same sites within a 40 bp double-stranded oligonucleotide containing two of the translocation breakpoints, confirming the results at a subset of the sites. Cleavage assays using the same oligonucleotide substrate in which guanines at several positions were replaced with N7-deaza guanines indicated that the N7 position of guanine is important in metabolite-induced cleavage, possibly suggesting N7-guanine alkylation by etoposide quinone. Not only etoposide, but also its metabolites, enhance
DNA topoisomerase II
cleavage near MLL translocation breakpoints in in vitro assays. It is possible that etoposide metabolites may be relevant to translocations.
...
PMID:Etoposide metabolites enhance DNA topoisomerase II cleavage near leukemia-associated MLL translocation breakpoints. 1117 Apr 41
The epipodophyllotoxins etoposide and teniposide and other
DNA topoisomerase II
inhibitors including anthracyclines and dactinomycin are highly efficacious anticancer drugs. All are associated with a distinct form of leukemia characterized by chromosomal translocations as a treatment complication. Most of the translocations disrupt a
breakpoint cluster region
(
bcr
) of the MLL gene at chromosome band 11q23. Other characteristic translocations also may occur. The normal function of the nuclear enzyme
DNA topoisomerase II
is to catalyze changes in DNA topology between relaxed and supercoiled states by transiently cleaving and re-ligating both strands of the double helix. Anticancer drugs that are
DNA topoisomerase II
inhibitors are cytotoxic because they form complexes with DNA and
DNA topoisomerase II
. The complexes decrease the re-ligation rate, disrupt the cleavage-re-ligation equilibrium, and have a net effect of increasing cleavage. The increased cleavage damages the DNA and leads to chromosomal breakage. Cells with irreparable DNA damage die by apoptosis. The association of
DNA topoisomerase II
inhibitors with leukemia suggests that the drug-induced,
DNA topoisomerase II
-mediated chromosomal breakage may be relevant to translocations in addition to this anti-neoplastic, cytotoxic action. Epidemiological studies, genomic translocation breakpoint cloning and in vitro
DNA topoisomerase II
cleavage assays together lead to a model for treatment-related leukemia in which
DNA topoisomerase II
causes chromosomal breakage and translocations form when the breakage is repaired.
...
PMID:Leukemias related to treatment with DNA topoisomerase II inhibitors. 1134 Jun 7
VP-16 (etoposide) has recently been shown to induce
topoisomerase
II (TOP2)-mediated DNA cleavage within the mixed lineage leukemia (MLL)
breakpoint cluster region
(
bcr
), suggesting a role of TOP2 in MLL gene rearrangement. In our current studies, we have compared the induction of DNA cleavage within the MLL
bcr
in different cell lines after treatment with various anticancer drugs. All anticancer drugs tested including VP-16 (a TOP2-directed drug), camptothecin (a topoisomerase I-directed drug), 5-fluorouracil and methotrexate (antimetabolites), and vinblastine (a microtubule inhibitor) induced the same site-specific cleavage within the MLL
bcr
. This cleavage was shown to be nuclease-mediated but not TOP2-mediated by the following observations: 1) drug-induced cleavage within the MLL
bcr
was not protein-linked; 2) unlike TOP2-mediated cleavage, drug-induced DNA cleavage within the MLL
bcr
was kinetically slow and coincided with the formation of the apoptotic nucleosomal DNA ladder; 3) drug-induced cleavage within the MLL
bcr
was unaffected in cells with reduced nuclear TOP2; and 4) drug-induced cleavage within the MLL
bcr
was abolished by the caspase inhibitor, Z-Asp(OCH(3))-Glu(OCH(3))-Val-Asp(OCH(3))-FMK. The possibility that an apoptotic nuclease may be involved in cleavage of the MLL
bcr
and MLL gene translocation is discussed.
...
PMID:Nucleolytic cleavage of the mixed lineage leukemia breakpoint cluster region during apoptosis. 1140 28
The correlation between infant leukemia and in utero exposure to
topoisomerase
II (topo-II) inhibitor has been clarified. We examined the in vitro effect of topo-II inhibitor (etoposide) on cleavage of the MLL gene in cord and peripheral blood mononuclear cells (MNCs). Southern blot analysis showed cleavage of the MLL gene in peripheral blood MNCs of infants when the MNCs were exposed to etoposide. MNCs were incubated with etoposide at various concentrations (1 to 50 microM), and a ligation-mediated polymerase chain reaction (LM-PCR) was used to detect double strand breaks (DSBs) of DNA in intron 8 of the MLL
breakpoint cluster region
. PCR products obtained with LM-PCR were subcloned and sequenced to identify the breakpoint in the MLL gene. The PCR products indicated DSBs of the MLL gene were obtained without any difference in the incidence between 3 different samples (cord and peripheral blood from infants and children). Sequencing analysis showed that the DSBs occurred on the telomeric side of intron 8 and near exon 9. There was no evidence that the cord blood was more susceptible to MLL DNA breakage by topo-II inhibitor than were other cells. Instability of the partner gene during the fetal period could be associated with the pathogenesis of infant leukemia.
...
PMID:In vitro cleavage of the MLL gene by topoisomerase II inhibitor (etoposide) in normal cord and peripheral blood mononuclear cells. 1213
The MLL gene is involved in many chromosomal translocations leading to both acute myeloid and lymphoid leukemia. Some patients treated for primary malignancies with chemotherapeutic agents that inhibit
DNA topoisomerase II
(topo II) develop treatment-related leukemia (t-AML) caused by MLL gene rearrangement. Whether these patients are unusually susceptible to anti-topo II drugs, or whether this is a random adverse event is unknown. To discover genetic polymorphisms that may predispose patients to t-AML development, we sequenced the 8.3-kb MLL
breakpoint cluster region
(
BCR
) from 22 patients who had been treated with topo II inhibitors and who developed t-AML and from 37 patients who did not, and from eight infants and 20 normal individuals. Four polymorphic sites within Alu repetitive elements were identified; three affected the length of poly-A tracts and one altered the size of a trinucleotide repeat. The three poly-A tract polymorphisms occurred with equal frequency in leukemic patients and controls and hence are not predictors of risk. The trinucleotide GAA repeat has three alleles: (GAA)4, (GAA)5, and (GAA)6. The (GAA)6 allele is very rare. The adult t-AML patients are almost exclusively (GAA)4/5 heterozygotes (83%), whereas the normal population is only 55% (GAA)4/5 heterozygotic and is represented equally by (GAA)4 and (GAA)5 homozygotes (20% each). Only certain trends could be established because of the small sample size of these leukemic groups. Whereas adult t-AML patients are more likely to be (GAA)4/5 heterozygotes, this is not statistically significant, and this polymorphism within the MLL
BCR
has only a suggestive association with t-AML development.
...
PMID:Polymorphisms in the MLL breakpoint cluster region (BCR). 1266 71
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.
...
PMID:Etoposide induces chimeric Mll gene fusions. 1463 Jun 94
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).
...
PMID:Characterization of genomic breakpoints in MLL and CBP in leukemia patients with t(11;16). 1533 49
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