UMLS:C0023418 - FACTA Search

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Query: UMLS:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The frequent occurrence of TF gene involvement in translocations associated with leukemia is remarkable, although not yet explained. The wide variety of TFs involved in these translocations and the different stages of cellular maturation argue against a unifying mechanism. Recombinases, active during B-cell and T-cell development, have been implicated in gene arrangements involving TCR genes and in the SIL/SCL rearrangement, which involves two genes not normally rearranged. However, other mechanisms must clearly be active in generating these molecular abnormalities and perhaps they relate to the multistep maturation and differentiation processes and continuous cell turnover seen in hematopoietic cells. The difficulties in obtaining human solid tumor samples may make it more difficult to identify translocations involving TF genes in solid tumors. Recently, the cytogenetic analysis of solid tumors has improved and specific cytogenetic abnormalities have been associated with specific types of tumors. With advanced techniques, such as fluorescent in situ hybridization (a technique that does not depend on cell growth) and PCR, abnormalities involving TF genes will be discovered. Abnormalities of TF genes, other than translocations, have been seen in a broad variety of nonhematopoietic malignancies. The p53 protein has been shown to bind DNA in a sequence-specific fashion and interact with a variety of DNA tumor virus oncoproteins. The broad range of cell types that harbor p53 abnormalities suggests that TF abnormalities will likely be implicated in many solid tumors. We have detailed several examples of how gene rearrangements that accompany chromosomal translocations in acute leukemia can alter the expression or activity of cellular TFs. Several translocations generate fusion RNA transcripts and fusion TF proteins with altered functional characteristics. Other translocations result in the expression of a gene not normally detectable in hematopoietic cells or alter the level of its expression, or affect the promoter usage or exon structure of the gene (Table 2). Studies are underway in many laboratories to characterize the biologic activity of these abnormal TFs and it remains to be proven that these molecular abnormalities are directly linked with leukemogenesis. The identification of abnormal fusion transcripts and proteins may allow specific therapies to be directed against "tumor-specific" DNA, mRNA, or protein targets. Therapeutic strategies based on antisense or ribozyme technology may be used to turn off expression of these genes and inhibit leukemia cell growth. Immunologic methods can also be used to direct therapy against the malignant cells.
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PMID:Transcription factors, translocations, and leukemia. 136 70

In a prospective study on 44 cases of T-cell origin acute lymphoblastic leukemia, 20 patients were found to display an immature immunophenotype (CD7+, CD4-, CD8-, CD1-) and were classified as T-stem cell leukemia (T-SCL). Twenty-four patients expressed CD4 and/or CD8 antigens on their blast cells, designated T acute lymphoblastic leukemia (T-ALL). The T-SCL subset showed a significantly higher median age, a more frequent incidence of extramedullary leukemia, a morphology L1 in most cases, and a poor response to treatment in terms of either complete remission rate or median survival duration. In addition, significant differences between the two groups were found in evaluating the number of days of blast disappearance from peripheral blood, of CR achievement, and of neutrophils and platelets recovery. We conclude that T-SCL represents a distinct clinical entity, characterized by a poor response to ALL conventional chemotherapy. Alternative therapeutic approaches should be developed for patients suffering from this form of leukemia, to modify its severe prognosis.
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PMID:Clinical relevance of immunological dissection in T-ALL: a report on 20 cases with stem cell (CD7+, CD4-, CD8-, CD1-) phenotype. 137 1

The SCL gene encodes a member of the helix-loop-helix (HLH) family of transcription factors and is reportedly involved in up to 25% of T-cell acute lymphoblastic leukemia (T-ALL). We have surveyed over 120 primary human tumors including melanomas, myeloid, and lymphoid leukemias, and other solid tumors without evidence of rearrangements involving SCL. These results are further supported by low level expression of SCL in these tumors (as assessed by a polymerase chain-reaction-based method). We conclude that rearrangement/translocation with subsequent activation of SCL occurs infrequently in myeloid leukemias and melanomas.
Leukemia 1992 Jul
PMID:SCL gene in human tumors. 162 84

Molecular study of a t(1;14)(p32;q11) translocation found in an acute T-cell leukemia (Kd cells) with a relatively mature phenotype is reported. Complex DNA rearrangements were characterized in the TCR alpha/delta locus. Besides a productive V alpha/J alpha assembly found on the normal allele, two deletions within the J alpha cluster were identified in the translocated allele. The translocation breakpoints involved the TCR delta gene on chromosome 14 and the SCL locus on chromosome band Ip32 that was recently shown to be activated by the t(1;14) translocation of the DU 528 leukemic cell line. Significantly, both Kd and DU 528 translocation breakpoints were located at the boundaries of D delta or J delta segments and were clustered in a 10 kb genomic fragment of the SCL gene. The presence of recombination signal motifs (heptamer-12/23 bp spacer-nonamer) on both normal chromosome partners, and N nucleotide addition on both derivative chromosomes involved the recombinase system in the translocation event. The SCL locus was highly expressed as a 5 kb transcript in Kd cells and, as already reported, as a 2 kb transcript in DU 528 cells. Importantly, a 5 kb SCL transcript was also detected in immature nonlymphoid hematopoietic cells but not in normal mature T cells, suggesting that it might correspond to the normal SCL transcript. Taken together, our data support the notion that the involvement of the SCL gene in the leukemogenic process may occur through overexpression of an apparently normal transcript (Kd cells) or expression of a truncated RNA (DU 528 cells).
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PMID:Two distinct mechanisms for the SCL gene activation in the t(1;14) translocation of T-cell leukemias. 196 81

The helix-loop-helix genes LYL, SCL and E2A are associated with chromosome translocations found in human lymphoid leukemias. To establish their hematopoietic expression patterns, we have isolated murine LYL and SCL cDNA clones and investigated the expression of all three genes by Northern blot analysis of 58 murine hemopoietic cell lines and tissues. The nucleotide sequences of LYL cDNA clones revealed alternative 5' untranslated sequences and differential splicing within the 5' portion of the coding region that may produce a LYL polypeptide lacking an N-terminal segment. The LYL gene was expressed in most myeloid, erythroid and B lymphocyte cell lines and displayed two alternative size classes of transcripts, the smaller size class (1.5-1.8 kb) being typical of the erythroid lineage and the larger class (2.0-2.3 kb) of the B cell lineage. These two size classes were found to differ in the 5' untranslated region. Thus, expression of the LYL gene appears to be differentially regulated in different hemopoietic cell types. In contrast, the E2A gene was expressed throughout the hemopoietic compartment as a single dominant transcript (3.5 kb). SCL expression was restricted to erythroid, mast and early myeloid cell lines, and the level of SCL transcripts (3.0 and 4.7 kb species) increased markedly during DMSO-induced differentiation of erythro-leukemia cells. Hence the SCL gene product may be an important regulatory factor for the erythroid lineage. The low or undetectable expression of both SCL and LYL in most T lymphoid cell sources is consistent with the view that the translocations of these genes in human T cell leukemias alter their normal regulation and may thereby contribute to neoplasia.
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PMID:Differential expression of the LYL, SCL and E2A helix-loop-helix genes within the hemopoietic system. 200 Feb 19

We have studied a leukemic stem-cell line, DU.528, that is able to differentiate into myeloid and lymphoid cells. The leukemic cells have a translocation between chromosomes 1 and 14, t(1;14)(p33;q11), which we have molecularly cloned and sequenced. Initial screening used joining (J)-segment probes from the T-cell receptor (TCR) alpha- and delta-chain loci. In apparent concert with the translocation, a deletion has occurred between delta-chain diversity (D)-region genes D delta 1 and D delta 2. D delta 2 was observed on derivative chromosome 1 [der(1)] and D delta 1 on der(14) with a deletion of the intervening 10 kilobases of germ-line DNA. The nature of the D delta 1-D delta 2 deletional event implicates a lymphoid recombinase in the mechanism of the translocation. As a consequence of the translocation, an unusual fusion transcript was generated. Probes from chromosome 1 detected a previously unreported transcript in RNA from both the cell line and the patient. A chromosome 14 probe identified the same transcript, thus confirming a fusion transcript derived from both chromosomes 1 and 14. This translocation may identify a gene for which we propose the name SCL (stem-cell leukemia) that is important for hemopoietic development and oncogenesis and that has been disrupted or altered in this stem-cell line.
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PMID:Chromosomal translocation in a human leukemic stem-cell line disrupts the T-cell antigen receptor delta-chain diversity region and results in a previously unreported fusion transcript. 246 96

Total skin electron beam therapy (TSEB) was used in the treatment of 33 patients with lymphoma and 13 patients with leukemia involving extensive segments of the skin surface. Twenty-two of 23 had skin lesions as a primary manifestation of lymphoma (primary cutaneous lymphoma--PCL) and 11 developed cutaneous lesions following disseminated nodal lymphoma (secondary cutaneous lymphoma--SCL). A once weekly fractionation scheme was employed to irradiate the entire skin surface with 3.5 to 4 MeV electron beam from a 6 MeV linear accelerator. During each weekly session, 400 rad were delivered to the entire skin and a complete course consisted of 4-6 consecutive weekly sessions. The majority of patients have been previously treated elsewhere for various periods and all patients have been at risk for a median of 12 months, range from 12-117 months following TSEB. Striking predominance of the diffuse pattern (76%) was demonstrated in both the PCL and SCL. There was extracutaneous involvement in 63% (13/22) of the PCL, nodal or visceral at onset of TSEB; median follow-up was 24 months, range 6-117 months; 20/22 (90%) of all patients obtained prompt relief of symptoms and complete regression of cutaneous lesions. Duration of cutaneous remission ranged from 6-96 months, median 18 months; in general, duration was adversely influenced by the presence of visceral involvement at onset of TSEB. Although cutaneous response among the patients with SCL and leukemia was equally good, many of these patients were treated for palliation because of rapid progression of their disease. Once weekly treatments were highly effective, well-tolerated and no untoward immediate or late effects have been noted in the bone marrow or normal skin irradiated.
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PMID:Total skin electron beam therapy for cutaneous lymphomas and leukemias. 714 34

The SCL/TAL1 gene was originally identified by virtue of its rearrangement and transcriptional activation in patients with T cell acute lymphoblastic leukaemia. It encodes a helix-loop-helix transcription factor, is not normally expressed in T cells, but is expressed in erythroid, mast, megakaryocytic and progenitor cells. Over-expression of sense and antisense constructs have implicated SCL as a positive regulator of erythroid differentiation. In addition we have previously shown that SCL mRNA levels undergo biphasic modulation during induced erythroid differentiation of murine erythroleukaemia (MEL) cells with a transient early fall followed by a late rise. In this paper we have studied expression of the SCL protein during erythroid differentiation and also the molecular basis for the raised SCL mRNA levels that accompany erythroid differentiation. We have generated an anti-SCL antiserum and used it to demonstrate that an early transient fall in SCL protein does not occur during induced differentiation of MEL cells. Furthermore SCL protein levels underwent a late fall in three different models of erythroid differentiation and in two models of myeloid differentiation. The fall in SCL protein levels during induced erythroid differentiation contrasted with the concomitant marked rise in SCL mRNA levels. These observations have significant implications for the mechanism by which SCL may regulate erythropoiesis. In addition we have demonstrated that the stability of SCL mRNA was only marginally enhanced during erythroid differentiation of MEL cells, whereas the activity of a luciferase reporter construct driven by the SCL promoter was increased 11- to 17-fold. Up-regulation of transcription therefore accounted for most of the increase in SCL mRNA levels during erythroid differentiation.
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PMID:Discordant regulation of SCL/TAL-1 mRNA and protein during erythroid differentiation. 762 20

We have studied gene expression of GATA-1, GATA-2, and SCL, which are known as cell-specific transcription factors, in 110 various leukemias consisted of 76 patients with acute myeloid leukemia (AML), 19 with acute lymphoblastic leukemia (ALL), and 15 with chronic myeloid leukemia (CML) in blast crisis by the revearse transcription-polymerase chain reaction assay. Accordingly, we divided into three groups. Group I (GATA-1+SCL+): patients with AML exhibiting phenotypic characteristics of erythroid or megakaryocytic lineage and most of CML myeloid blast crisis were included. Group II (GATA-1+, SCL-): Not only CD7-positive and CD19-positive AML, but also a part of Ph+ALL demonstrated this pattern. Leukemia in this group is considered to have a capability to differentiate into myeloid and lymphoid lineages. Group III (GATA-1-, SCL-): patients in this group consisted of leukemias which are differentiated into specific cell-lineages, either myeloid or lymphoid, when compared to groups I or II. Our data suggest that the expression pattern of transcription factors reflects lineage potential in leukemia cells, leading to classification of leukemias.
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PMID:[The expression pattern of transcription factors (GATA, SCL) and biological characteristics in various leukemia cells]. 764 49

A comparative study of the immunohistochemical (Stem cell leukemia/T-cell acute leukemia [SCL/TAL-1] protein expression) and genotypic (deletions in the SCL/tal-1 gene) findings in T-acute lymphoblastic leukemia (T-ALL) is presented. Formalin-fixed tissue from 50 cases of T-ALL were stained with a novel monoclonal antibody, 2TL 242, which recognizes SCL/TAL-1 protein. Twenty-four cases showed nuclear immunolabeling of leukemic cells. Nuclear positivity was not evident in any other type of leukemia or lymphoma tested with the antibody. Genotypic analysis of 25 cases of T-ALL showed a deletion involving the SCL/tal-1 gene in nine cases. These results suggest that protein expression is not dependent on derangement of the SCL/tal-1 gene, because immunohistochemical detection of the protein was noted in the presence and absence of a tal-d1 deletion.
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PMID:SCL/Tal-1 expression in T-acute lymphoblastic leukemia: an immunohistochemical and genotypic study. 767

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