Recurring chromosomal translocations involving chromosome 11, band q23, have been observed in acute lymphoid leukemias and especially in acute myeloid leukemias. We recently showed that breakpoints in four 11q23 translocations, t(4;11)(q21;q23), t(6;11)(q27;q23), t(9;11)(p22;q23), and t(11;19)(q23;p13.3), were contained within a yeast artificial chromosome done bearing the CD3D and CD3G gene loci. We have identified within the CD3 yeast artificial chromosome a transcription unit that spans the breakpoint junctions of the 4;11, 9;11, and 11;19 translocations, and we describe two other, related transcripts that are upregulated in the RS4;11 cell line. We have named this gene MLL (myeloid/lymphoid, or mixed-fineage, leukemia).
Translocations involving chromosome band 11q23, found in acute lymphoid and myeloid leukemia, disrupt the MLL gene. This gene encodes a putative transcription factor with homology to the zinc fingers and other domains of the Drosophila trithorax gene product and to the "AT-hook" motif of hig mobility group proteins. To map potential transcriptional activation or repression doains of the MLL protein, yeast GAL4 DNA-binding domain and MLL hybrid protein-expressing plaids were cotransfected with chioramphenicol acetyltransferase reporter plasmids in a transient transfection system. We found that MLL contains a strong activation domain and a repression domain. The former, located telomeric (3') to the breakpoint region, activated transcription 18-fold to >200-fold, depending on the promoter and cell line used for transfection. A repression domain that repressed transcription 4-fold was located centromeric (5') to the breakpoint region of MLL. The MLL AT-hook domain protein was expressed in bacteria and was utilized in a gel mobility shift assay to assess DNA-binding activity. The MLL AT-hook domain could bind cruciform DNA, recognizing structure rather than sequence of the target DNA. In translocations involving MLL, loss of an activation domain with retention of a repression domain and a DNA-binding domain on the der(11) chromosome could alter the expression of downstream target genes, suggesting a potential mechanism of action for MLL in leukemia.
A BSTR ACTThe recurring translocation t(11;16)-(q23;p13.3) has been documented only in cases of acute leukemia or myelodysplasia secondary to therapy with drugs targeting DNA topoisomerase II. We show that the MLL gene is fused to the gene that codes for CBP (CREB-binding protein), the protein that binds specifically to the DNAbinding protein CREB (cAMP response element-binding protein) in this translocation. MLL is fused in-frame to a different exon of CBP in two patients producing chimeric proteins containing the AT-hooks, methyltransferase homology domain, and transcriptional repression domain of MLL fused to the CREB binding domain or to the bromodomain of CBP. Both fusion products retain the histone acetyltransferase domain of CBP and may lead to leukemia by promoting histone acetylation of genomic regions targeted by the MLL AT-hooks, leading to transcriptional deregulation via aberrant chromatin organization. CBP is the first partner gene of MLL containing well defined structural and functional motifs that provide unique insights into the potential mechanisms by which these translocations contribute to leukemogenesis.The t(11;16)(q23;p13.3) is a rare recurring translocation that has been described in 11 patients to date (1). All of these patients have therapy-related acute leukemia of myeloid or lymphoid phenotype, or myelodysplasia, after exposure to DNA topoisomerase II inhibitors (anthracyclines or epipodophyllotoxins) for treatment of a primary malignancy.MLL (also called ALL1, Htrx, and HRX; refs. 2-6), which is located on chromosomal band 11q23, is involved in translocations with at least 40 different partner genes (7-9). These translocations result in acute leukemia, either lymphoblastic or myeloid͞monocytic, with a close correlation between the specific translocation and a particular leukemia phenotype. MLL also is involved in translocations that occur secondary to therapy of a primary malignant disease with drugs that target DNA topoisomerase II and result in therapy-related acute myeloid leukemia or acute lymphoblastic leukemia (10-14). The t(11;16)(q23;p13.3) occurs only in therapy-related leukemia or myelodysplasia, in contrast to other MLL translocations such as the t(9;11), t(4;11), or t(11;19), which are seen primarily in de novo leukemia with no more than about 5-10% having leukemia occurring after treatment.MLL codes for a very large protein, with a predicted molecular mass of 431 kDa (4-6). The protein contains several domains identified by homology to other proteins or by functional analysis. Three AT-hook DNA-binding domains near the amino terminus also are found in the high-mobility group proteins HMG-I(Y) (15). MLL contains a region of homology to mammalian DNA methyltransferases, transcriptional activation and repression domains, and a cysteine-rich region that forms three C4HC3 zinc fingers [plant homeodomain (PHD) or leukemia-associated-protein domains] (16-21). The PHD domain and the SET [Su(var)3-9 enhancer of zeste, and trithorax] domain at the carboxyl terminus are the regions...
Structural rearrangements involving the short arm of chromosome 9, including bands 9p21 and 22, are found in the leukemia cells of 7 to 13 percent of patients with acute lymphoblastic leukemia. The interferon-alpha gene cluster and the interferon-beta 1 gene have been localized to this chromosomal region. We have previously demonstrated deletions of these genes in several cell lines established in vitro from patients with lymphoblastic leukemia. We report here homozygous or hemizygous deletions of the interferon-alpha and interferon-beta 1 genes in samples of leukemia cells from patients with lymphoblastic leukemia. Of 62 patients examined, 18 (29 percent) had such deletions. Four patients (7 percent) had homozygous deletions of the interferon-alpha gene cluster; of these, one also had a homozygous deletion and three had hemizygous deletions of the interferon-beta 1 gene. Fourteen patients (23 percent) had hemizygous deletions of both the interferon-alpha gene cluster and the interferon-beta 1 gene. In 8 of the 18 patients with deletions, the deletions of interferon genes were submicroscopic; in the 11 other patients, chromosomal rearrangements of 9p, including translocations or deletions, were visible on light microscopy. These chromosomal and molecular deletions are likely to be related to the loss of a tumor-suppressor gene (or genes) located on 9p, which may be an interferon gene or an unrelated but closely linked gene.
Translocations involving chromosome band Ilq23, found in acute lymphoid and myeloid leukemias, disrupt the MLL gene. This gene encodes a putative transcription factor with regions of homology to several other proteins including the zinc fingers and other domains of the Drosophila trithorax gene product, and the "AT-hook" DNA-binding motif of high mobility group proteins. We have previously demonstrated that MLL contains transcriptional activation and repression domains using a GAL4 fusion protein system (21). The repression domain, which is capable of repressing transcription 3-5-fold, is located centromeric to the breakpoint region of MLL. The activation domain, located telomeric to the breakpoint region, activated transcription from a variety of promoters including ones containing only basal promoter elements. The level of activation was very high, ranging from IO-fold to more than 300-fold, depending on the promoter and cell line used for transient transfection.In translocations involving MLL, the protein produced from the der(ll) chromosome which contains the critical junction for leukemogenesis includes the AT-hook domain and the repression domain. We assessed the DNA binding capability of the MLL AT-hook domain using bacterially expressed and purified AT-hook protein. In a gel mobility shift assay, the MLL AT-hook domain could bind cruciform DNA, recognizing structure rather than sequence of the target DNA. This binding could be specifically competed with Hoechst 33258 dye and with distamycin. In a nitrocellulose protein-DNA binding assay, the MLL AT-hook domain could bind to AT-rich SARs, but not to non-SAR DNA fragments. The role that the AT-hook binding to DNA may play in vivo is unclear, but it is likely that DNA binding could affect downstream gene regulation. The AT-hook domain retained on the der(ll) would potentially recognize a different DNA target than the one normally recognized by the intact MLL protein. Furthermore, loss of an activation domain while retaining a repression domain on the der( 11) chromosome could alter the expression of various downstream target genes, suggesting potential mechanisms of action for MLL in leukemia.
HSB-2 is a cell line derived from a patient who had T-cell acute lymphoblastic leukemia (T-cell ALL) with a t(1;7)(p34;q34). We used a genomic probe from the T-cell receptor beta (TCR beta) locus (7q34) to identify DNA rearrangements in HSB-2. Two rearranged BglII DNA fragments were cloned, and one of these clones was shown to contain the translocation breakpoint on the derivative chromosome I [der(I)]. We used a probe derived from this clone to isolate an unrearranged phage clone encompassing the breakpoint at Ip34. The restriction map of this clone was compared to the published maps of known protooncogenes located at Ip32-34. By restriction mapping, Southern blot analysis, and DNA sequencing we showed that the translocation breakpoint on chromosome I is located within the first intron of the LCK gene. The LCK gene codes for p56lck, a member of the SRC family of cytoplasmic tyrosine protein kinases. There are two classes of LCK transcripts (type I and type II), each expressed from a distinct promoter, and each having a unique 5' untranslated region (UTR); the protein coding regions of the two classes are identical. The breakpoint in the t(1;7) separates the two LCK promoters and juxtaposes the constant region of the TCR beta locus with the proximal promoter and with the protein-coding region of the LCK gene on the der(I) chromosome.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.