UMLS:C0023473 - FACTA Search

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Query: UMLS:C0023473 (chronic myeloid leukemia)
18,916 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Seven secondary leukemia patients were treated for solid tumors or malignant lymphoma with anticancer drugs or radiation. We studied bone marrow samples from these patients by fluorescence in situ hybridization (FISH). Of the seven patients, three had increased signals for the ABL oncogene (9q34) on interphase nuclei and at metaphase. One of the three patients also had four signals for the CD3 (MLL) region (11q23). Whole painting probes revealed that these chromosomal regions were translocated onto structurally abnormal chromosomes, resulting in partial tri-, tetra- or penta-somy of these regions. We called this type of translocation "segmental jumping translocation (SJT)." SJT of the ABL oncogene was not detected in samples from 15 patients with de novo acute myelocytic leukemia (AML), 12 with myelodysplastic syndrome (MDS), or 20 with chronic myelocytic leukemia (CML) at the chronic phase. Furthermore, monosomy 7 was also found in the patients with the gene amplification. These results indicate that SJT of ABL and/or CD3 (MLL) genes is associated with the leukemogenesis of secondary leukemia. The SJT may be one mechanism of gene amplification.
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PMID:Frequent jumping translocations of chromosomal segments involving the ABL oncogene alone or in combination with CD3-MLL genes in secondary leukemias. 900 63

Mitogen-activated protein (MAP) kinase appears to be one of the key regulators of cell proliferation and differentiation. Very little, however, has been revealed as to how MAP kinase is involved in leukemogenesis. We have studied the activation of the MAP kinase pathway in 100 human primary leukemia cells including 73 acute myelogenous leukemias (AMLs). Forty acute leukemia samples (40% of the total), including 37 AML samples (51% of AML), showed activation of MAP kinase as revealed by the mobility shift of the phosphorylated form of the protein and by in vitro kinase assay. This activation was correlated with MAP kinase kinase activity in these cells. In contrast, none of 14 chronic myelogenous leukemia samples showed the activation of MAP kinase. These results suggest that the MAP kinase pathway is constitutively activated in a subset of primary acute leukemias, and thus indicate the possible role of the constitutively activated MAP kinase in leukemogenesis.
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PMID:Constitutive activation of mitogen-activated protein kinase pathway in acute leukemia cells. 909 86

Expression of T, sialosyl-T and disialosyl-T antigens on normal blood and bone marrow cells as well as transformed cells was examined using specific monoclonal antibodies and multidimensional flow cytometry. Both anti-sialosyl-T (QSH1) and anti-disialosyl-T (QSH2) monoclonal antibodies aggregated erythrocytes. The anti-disialosyl-T antibody was specific for the erythroid lineage and did not react with neutrophils, monocytes or T-lymphocytes, while the anti-sialosyl-T antibody reacted with erythroid cells and a subset of T-lymphocytes. The developing erythroid cells in bone marrow showed coordinate expression of glycophorin A and the two carbohydrate chains, sialosyl-T and disialosyl-T. Analysis of neoplastic cells showed that the anti-disialosyl-T antibody only reacted with glycophorin A-positive blasts from erythroleukemia (FAB M6) patients (4/4) and one patient with chronic myeloid leukemia in erythroblastic transformation (CMLET). Leukemic blasts from these patients demonstrated coordinate quantitative expression of glycophorin A and disialosyl-T. The anti-sialosyl-T antibody reacted with glycophorin A-positive blasts from FAB M6 patients (4/4) and one CMLET patient; however, the antibody also reacted with glycophorin A-negative blasts from one FAB M6 and the one CMLET patients and transformed cells from other types of leukemia. The anti-T monoclonal antibody (HH8) did not react with any of the other cells tested. These results indicate that glycophorin A and disialosyl-T expression are tightly linked during normal erythroid development and erythroid leukemogenesis.
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PMID:Expression of sialosyl-T and disialosyl-T antigens in erythroid cells. 925 Aug 10

Clinical studies have indicated that folate deficiency may enhance the development of various malignancies. In animal studies that examined the effect of folate deficiency on malignancies, conflicting results have been reported. In some studies, folate deficiency increased the development and growth of malignant tumors; in others, it decreased the development and growth of malignancies. We examined the effect of transient folate deficiency on the development of leukemia in mice infected with the anemia-inducing strain of Friend leukemia virus. Friend virus disease can be considered as a model for human acute leukemias that are preceded by a preleukemic period. These include leukemias that develop in patients who received previous chemotherapy and/or radiation therapy, as well as patients with chronic granulocytic leukemia or myelodysplasia. Folate deficiency around the time of Friend virus-infection delayed the onset but increased the incidence of leukemia. The rates of rearrangement of the Spi-1 (PU.1 ) oncogene by provirus integration and alteration of the p53 tumor-suppressor gene were the same in leukemia cell lines derived from folate-deficient mice as they were in cell lines from control mice. These results indicate that folate deficiency did not exert its enhancement of leukemogenesis through changes in either Spi-1 or p53, even though these two genes have been found to be the most frequently altered ones in Friend virus-induced leukemias. Our results suggest that folate deficiency may enhance the development of acute leukemia in patients who are at high risk for this disease.
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PMID:Folate deficiency delays the onset but increases the incidence of leukemia in Friend virus-infected mice. 935 75

Interferon consensus sequence binding protein (ICSBP) was first identified as a transcription factor of the interferon (IFN) regulatory factor family (IRF) which regulates expression of IFN-dependent genes by binding to DNA at specific sites, IFN-stimulated responsive elements. Analysis of ICSBP-deficient mice showed hematologic alterations similar to chronic myelogenous leukemia (CML) in humans and suggested a novel role for ICSBP in regulating proliferation and differentiation of hematopoietic progenitor cells. Here we show that ICSBP-mRNA expression is impaired in human myeloid leukemias: 27 of 34 CML patients (79%) and 21 of 32 patients with acute myeloid leukemia (AML) (66%) showed very low or absent transcript numbers of ICSBP. In contrast, only 2 of 33 normal volunteers (6%) showed low transcription of ICSBP (P < . 0001 both for CML and AML values). The lack of expression was not associated with lack of lymphatic cells, which normally have been shown to express ICSBP at the highest level. More detailed analysis showed an absence of ICSBP-mRNA also in sorted B cells derived from CML patients. To analyze whether ICSBP may be induced in leukemic cells, ex vivo experiments using a known inducer of ICSBP, IFN-gamma, were performed. Ex vivo treatment of primary CML cells using IFN-gamma resulted in induction of ICSBP transcripts. Furthermore, samples of CML patients during IFN-alpha treatment were analyzed. In 11 of 12 CML patients ICSBP-mRNA was inducible upon in vivo treatment with IFN-alpha, but decreased with progression of CML. Stable transfection of K-562 cell line with ICSBP led to no difference in bcr-abl expression in vitro, although two patients showed an inverse correlation between bcr-abl and ICSBP in vivo. These data suggest that lack of ICSBP may have an important role also in human myeloid leukemogenesis.
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PMID:Lack of interferon consensus sequence binding protein (ICSBP) transcripts in human myeloid leukemias. 941 65

The ETV6 (also known as TEL) gene on chromosome 12p13 is the target of a number of translocations associated with various hematologic malignancies. The contribution of ETV6 to leukemogenesis occurs through different mechanisms that involve either its helix-loop-helix dimerization domain or its E26 transformation-specific (ETS) DNA-binding domain. Using fluorescence in situ hybridization we characterized seven new ETV6 rearrangements in chronic myeloid leukemia, acute myeloid leukemia, acute lymphoblastic leukemia, and non-Hodgkin's lymphoma. These aberrations, not always discernible at the cytogenetic level, include a t(5;12)(q31;p13), t(6;12;17)(p21;p13;q25), t(7;12)(p15;p13), t(7;12)(p12;p13), t(7;12)(q36;p13), t(12;13)(p13;q12), and a not completely defined t(12;?)(p13;?). Loss or disruption of the second ETV6 allele by a del(12)(p12p13) or by an intragenic ETV6 deletion was detected in two cases. In six cases the 12p13 breakpoint occurred in the 5' end of ETV6, upstream to exons encoding the HLH domain, whereas the remaining case had a breakpoint between the exons coding for the HLH domain and the exons coding for the ETS domain of ETV6. These observations provide further evidence for the multiple contributions of ETV6 in the pathogenesis of a wide range of hematologic malignancies.
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PMID:Fluorescence in situ hybridization characterization of new translocations involving TEL (ETV6) in a wide spectrum of hematologic malignancies. 945 71

There is strong clinical and epidemiological evidence that ionizing radiation can cause leukemia by inducing DNA damage. This crucial initiation event is believed to be the result of random DNA breakage and misrepair, whereas the subsequent steps, promotion and progression, must rely on mechanisms of selective pressure to provide the expanding leukemic population with its proliferative/renewal advantage. To investigate the susceptibility of human cells to external agents at the genetic recombination stage of leukemogenesis, we subjected two hematopoietic cell lines, KG1 and HL60, to high doses of gamma-irradiation. The irradiation induced the formation of fusion genes characteristic of leukemia in both cell lines, but at a much higher frequency in KG1 than in HL60. In KG1 cells, the AML1-ETO hybrid gene [associated with the t(8;21) translocation of acute myeloid leukemia] occurred significantly more often than the BCR-ABL [associated with t(9;22) chronic myeloid leukemia] or the DEK-CAN [associated with t(6;9) acute myeloid leukemia] fusion genes. These findings support the notion that ionizing radiation can directly generate leukemia-specific fusion genes but emphasize the differing susceptibility of different cell populations and the differing frequency with which the various fusion genes are formed. The selectivity observed at the primary level of gene fusion formation may explain at least in part the differential risk for development of some but not other forms of leukemia after high-dose radiation exposure.
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PMID:Selective induction of leukemia-associated fusion genes by high-dose ionizing radiation. 945 83

The XIX Symposium of the International Association for Comparative Research on Leukemia and Related Diseases (IACRLRD, President: Prof. Dr. R. Hehlmann) was held in Mannheim and Heidelberg, Germany, July 13 - 18, 1997. Comparative research in cancer was systematically established in the 1950s. Similarities in morphology, biology and pathology between animal and human leukemias and related diseases and the viral origin of a variety of animal leukemias and related diseases (lymphomas, sarcomas, breast tumors etc.) led to the concept that comparative research should promote the understanding of human leukemias and related diseases. In 1960 the World Health Organization inaugurated the establishment of a World Committee for Comparative Leukemia Research. The first symposium took place in Hannover, Germany, in 1963. After the fifth symposium in Padova, Italy, in 1971 the International Association for Comparative Research on Leukemia and Related Diseases (IACRLRD) was founded to complement the World Committee and to expand the international effort. The history of the symposium shows the evolution from a meeting on animal leukemia viruses into one dealing with viral and genetic aspects of human and animal leukemia and related diseases. The scientific evolution of the Abelson murine leukemia virus with its abl oncogene in the 1970s to what currently appears as the most reliable marker for human chronic myeloid leukemia is merely one example. Comparative research has reached a new dimension with the the recent advances in sequencing of the genomes of a variety of species and of humans. Many genes identified in the human genome and relevant for disease can be found in the genomes of animal species and even in the genomes of bacteria and of yeast. This reminds us that not just human and animal biology but also pathology must be regarded as a continuum of evolution and that much can be learned from comparing the genetic information of different species. Comparative genome research will allow conclusions to be drawn from principles recognized in animal species which are relevant to human diseases. It is likely that the application of comparative research to genome analysis will provide basic new insights in molecular medicine into the function of living beings for both animal species and humans. The current revolution in genomics is the latest phase in a rich history of medical progress related to the comparative approach. Meetings and organizations that have grown out of IACRLRD, include, at least to some extent: the Meeting of the International Human Retrovirology Association, the Gallo Lab Meeting , the Feline Retrovirus Meeting, the Cold Spring Habor Retrovirus Meeting, international and regional AIDS meetings, and many others. The XIX symposium in Mannheim included five memorial lectures, seven plenary sessions, 18 parallel sessions, two round table discussions and a public forum. In addition, six associated satellite symposia were held. The general meeting, attended by participants from 27 countries, integrated thematically contributions of genetic, cellular, and viral factors toward the development of leukemia and lymphoma and sought unifying concepts in leukemogenesis.
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PMID:Congress Report: XIX symposium of the International Association for Comparative Research on Leukemia and Related Diseases, Mannheim/Heidelberg, Germany, July 13 - 18, 1997. 953 31

Fluorescence in situ hybridization (FISH) was performed in 17 myeloid leukemia patients and seven lymphoid leukemia/ lymphoma patients who exhibited chromosomal abnormalities on the short arm of chromosome 17, in order to detect a commonly deleted region on chromosome band 17p13. Twenty-four leukemia/lymphoma patients studied cytogenetically at our institution over a period of 10 years had detectable 17p abnormalities such as translocation (six patients), addition (11 patients) and deletion of 17p13 (seven patients). A 17p abnormality was the only abnormality present in three patients. Most of the patients had additional complex cytogenetic abnormalities. The diagnosis was acute myeloid leukemia (AML) in 10 patients, two each with chronic myeloid leukemia (CML), acute lymphoblastic leukemia (ALL), chronic lymphocytic leukemia (CLL) and myelodysplastic syndrome (MDS) and the remaining three with malignant lymphoma (ML). Seven cosmid probes (D17S34, cCI17-624, cCI17-453, D17S379, cCI17-636, cCI17-732 and TP53) which mapped on 17p13 were used to analyze the allelic deletion. Eighty percent (19 out of 24) of the informative leukemia patients exhibited allelic loss in 17p13.3 at cC17-624. The smallest region of an overlapping deletion was observed on chromosome band 17p13.3 between cCI17-624 and cCI17-453. Patients with translocation involving 17p also showed deletion at cCI17-624 and cCI17-453. We hypothesize that this region contains a novel tumor suppressor gene(s) that is involved in leukemogenesis.
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PMID:Identification of a commonly deleted region at 17p13.3 in leukemia and lymphoma associated with 17p abnormality. 955 9

WT1 (Wilms tumor gene) expression is a new tumor marker of leukemic blast cells of AML, ALL, and CML. Minimal residual disease (MRD) of leukemia can be detected at frequencies as low as 1 in 10(3) to 10(4) normal bone marrow (BM) cells and 1 in 10(5) normal peripheral blood (PB) cells by means of the quantitation of expression levels of the WT1 gene using reverse transcriptase-polymerase chain reaction (RT-PCR). This is regardless of the types of leukemia or the presence or absence of tumor-specific DNA markers. Thus, the WT1 assay makes it possible to rapidly assess the effectiveness of treatment and to evaluate the degree of eradication of leukemic cells in individual leukemia patients. Moreover, molecular relapse using PCR can be diagnosed by the monitoring of WT1 expression levels in BM or PB 1-24 months (means, 7 months for BM and 8 months for PB) before the clinical relapse became apparent. In case of rapid or gradual increase in WT1 expression levels to or over 10(-2) after return to normal BM levels during CR; or retention of the WTI expression at levels near or over 10(-2) in BM without return to normal BM levels even in CR (WT1 expression level in K562 cells was defined as 1.0), it seems that clinical relapse is impending. Since WT1 antisense oligomers inhibit the growth of leukemic cells, it is apparent that the WT1 gene plays an important role in leukemogenesis.
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PMID:Wilms tumor gene (WT1) as a new marker for the detection of minimal residual disease in leukemia. 966 76

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