UMLS:C0023418 - FACTA Search

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Query: UMLS:C0023418 (leukemia)
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The examination of the presence of Ph chromosome and of the fused gene BCR-ABL in patients with chronic myeloid leukemia (CML) is significant for the precise diagnosis and in some cases for the prognosis of the disease. We examined peripheral blood for the presence of BCR-ABL fused gene by polymerase chain reaction (PCR) in eight patients with CML consecutively cytogenetically studied before and after the bone marrow transplantation and in two patients treated with interferon. Southern blot analysis was performed before BMT in two patients and the molecular rearrangement of Ph chromosome was found. In all cases our results have proved that cytogenetic and recombinant DNA evaluations confirm each other. Due to the high sensitivity of PCR technique the minimal residual leukemia can be detected.
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PMID:[Use of cytogenetic and molecular biology in the detection of chronic myeloid leukemia]. 128 73

The polymerase chain reaction (PCR) cannot be used to amplify the breakpoint in the chimaeric BCR-ABL gene in CML and acute leukaemias due to the large variation in the sites of breakpoint in the BCR gene (within a 5.8 kb region) and in the ABL gene (within a 150 kb region). The disease state is usually monitored using RNA-PCR to monitor abnormal transcripts. We have used a new modification of the PCR to amplify breakpoints within zone 3 of the M-bcr. A synthetic oligonucleotide linker, the Vectorette, is ligated to restriction digested DNA, and amplification is carried out between primers for a known target sequence and the Vectorette linker. Three Philadelphia chromosome Ph1-positive CML patients with breakpoints within the ALU region of zone 3 have been amplified and the sequence immediately around the breakpoint determined. The breaks occurred within 70 bp and two were only 14 bp apart. The Vectorette-PCR technique has the potential to rapidly identify and sequence breakpoints, and will enable the design of patient-specific primers to monitor disease progression, particularly following bone marrow transplantation.
Leukemia 1992 May
PMID:Amplification and sequencing of genomic breakpoints located within the M-bcr region by Vectorette-mediated polymerase chain reaction. 131 90

The involvement of the BCRlABL fusion gene in patients with Philadelphia (Ph) chromosome positive chronic myeloid leukaemia (CML) and acute lymphoblastic leukaemia (ALL) is well characterised, but the molecular events underlying the cases of Ph-negative CML and ALL that lack BCR gene involvement and those that cause transformation of Ph-positive CML are unknown. The murine ABL gene can be activated by genetic events that do not involve the BCR gene, including the introduction of two specific point mutations in exons VII and XI respectively, as found in the homologous sequence of the v-abl oncogene. We therefore sought evidence for analogous point mutations in the ABL gene in patients with Ph-negative, BCR-negative CML (n = 25), Ph-negative ALL (n = 18) and in Ph-positive CML in transformation (n = 28). We used restriction fragment length polymorphism and single strand conformational polymorphism techniques to analyse DNA amplified fragments of selected ABL coding regions from leukaemia cells. We identified only normal wild-type DNA sequences. The absence of these transforming point mutations does not exclude the possibility that the ABL gene in such patients could be activated by other means.
Leukemia 1992 Aug
PMID:Specific point mutations that activate v-abl are not found in Philadelphia-negative chronic myeloid leukaemia, Philadelphia-negative acute lymphoblastic leukaemia or blast transformation of chronic myeloid leukaemia. 135 50

Advances in molecular genetics in the past decade enabled us to analyze the cause of mendelian disorders at molecular level and a variety of mutations, not only in point mutations and deletion in exons but also in those occurred in regulatory elements or in RNA processing have been precisely identified. Such a variety of mutations may constitute variable clinical manifestations even in the simple mendelian disorders. On the other hand, pathogenesis of common diseases is much complicated and remains greatly to be elucidated. However, if we could use the strategies applied in the past few years for mendelian disorders, it seems to be not difficult to approach them. It is recommended to categorize a certain disease into subgroups for distinguishing their heterogenous phenotypes by clinical, biochemical and other properties. Owing to the success in making a subgroup (FAB classification), many subtype-specific translocations were found in leukemia, and then, rearrangement of relevant genes is also being shown. The best example is seen in chronic myelocytic leukemia. Since rearrangement of ABL and BCR was shown and both genes were cloned, detection of minimal residual diseases after intensive treatment became possible at 10(-6) level using RT-PCR technique. Recently developed interphase cytogenetics using FISH has visualized Ph1 translocation in metaphase cells and also in round nuclei, suggesting a potential use in monitoring the effect of certain drugs during treatment. Furthermore, very selective targeting therapy is being devised using antisense DNA.
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PMID:[Present status of gene diagnosis in cancer]. 144 79

The Philadelphia (Ph1) chromosome, or its molecular counterpart, the BCR-ABL fusion gene, is a rare but important prognostic indicator in childhood acute lymphoblastic leukemia (ALL), but its impact on adult ALL has not been well ascertained. A prospective study of the BCR-ABL fusion gene was begun on patients entered on clinical trials conducted by the Cancer and Leukemia Group B (CALGB). All patients received intensive, multiagent chemotherapy that included daunorubicin. Over 2 years, 56 patients were studied for molecular evidence of a BCR-ABL gene using Southern blot and pulsed-field gel hybridization analysis. Results were compared with cytogenetic detection of a Ph1 chromosome, and clinical features were compared for the BCR-ABL-positive and -negative groups. Molecular methods detected the BCR-ABL gene in 30% of cases compared with cytogenetic detection of the Ph1 chromosome in only 23%. The majority of cases (76%) showed the p190 gene subtype similar to pediatric ALL; the BCR-ABL-positive cases displayed a more homogeneous immunophenotype than the BCR-ABL-negative cases and were predominantly CALLA positive (86%) and B-cell surface antigen positive (82%). The rate of achieving complete remission was similar in the BCR-ABL-positive and -negative groups (71% and 77%, respectively, P = .72). There were more early relapses in the BCR-ABL-positive group, resulting in a shorter remission duration that was especially marked in the CALLA-positive and B-cell antigen-positive populations. These preliminary data suggest that the impact of the BCR-ABL gene on clinical outcome in ALL may be on maintenance of complete remission (CR) rather than achievement of CR when aggressive, multiagent chemotherapy is used. This study identifies the BCR-ABL gene as an important factor in adult ALL and demonstrates the utility of molecular methods for its accurate diagnosis.
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PMID:Clinical significance of the BCR-ABL fusion gene in adult acute lymphoblastic leukemia: a Cancer and Leukemia Group B Study (8762). 146 14

Chromosome Philadelphia (Ph) which originated from translocation 9;22 is an aberration connected with chronic myelogenous leukaemia (CML) and with part of the cases of acute lymphoblastic leukaemia (ALL). The analysis on the molecular level has shown that the rearrangement of ABL and BCR genes is the most important consequence of this translocation. The new hybrid gene translates the protein p210, which shows tyrosine phosphokinase activity. This protein could play an important role in the pathogenesis of CML. The investigations of BCR/ABL rearrangement on molecular level are an important tool for differential diagnosis of lymphoblastic crisis of CML and ALL and also are very valuable in detection of residual Ph positive cells in cytogenetic conversion of CML.
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PMID:[Molecular biology of chronic myeloid leukemia]. 148 67

Chronic myeloid leukaemia (CML) is a generic term that include five apparently distinct entities. The best known form, the classical Ph-positive subtype, accounts for about 90% of all cases of CML. The morphology of its presentation blood film is highly characteristic but is also seen in about half of the remaining 10% of cases, which are Ph-negative. This classical morphological subtype, whether Ph-positive or Ph-negative I describe as 'chronic granulocytic leukaemia' to refer to the exuberant granulocytic proliferation which is its hallmark. This term is often used indiscriminately and interchangeably with 'chronic myeloid leukaemia' and similar terms, just as 'chronic lymphocytic leukaemia' was, until recently, used to cover the chronic lymphoid leukaemias in general, but is now used in a specific sense. Chronic granulocytic leukaemia (CGL), whether Ph-positive or Ph-negative, is almost always BCR-rearranged and associated with the production of a unique 210-kd protein with enhanced tyrosine kinase activity. Most of the remaining cases of Ph-negative CML are examples of either chronic myelomonocytic leukaemia (CMML), a subtype almost as homogeneous as CGL, and characterized in its presentation blood film by the presence of monocytes and neutrophils but few immature granulocytes, or atypical CML (aCML), distinct from and less homogeneous than either CGL or CMML, in which some cases also share features with CGL while others share some with CMML. CMML and aCML do not show BCR rearrangement and are not associated with the production of p210kd. CGL, CMML, and aCML, though characterized on morphological features differ in their clinical features and behaviour, response to treatment and survival.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Haematological differences between chronic granulocytic leukaemia, atypical chronic myeloid leukaemia, and chronic myelomonocytic leukaemia. 149 35

The Philadelphia chromosome (Ph1) was the first genetic change to be associated consistently with leukemia, and it is one of the best understood on the molecular level. Because of this, it is an excellent model to investigate the application of molecular techniques to the clinical setting. These techniques are reviewed as are their clinical use in chronic myelogenous leukemia (CML), acute lymphoblastic leukemia (ALL), and transplantation. The Ph1 is caused by the fusion of two genes on chromosomes 9 and 22, resulting in the BCR-ABL fusion gene. This new gene is believed to be the cause of these Ph1-positive leukemias. The ability to detect the BCR-ABL fusion gene evolved from cytogenetic detection to Southern blot analysis, and now includes sophisticated techniques such as polymerase chain reaction (PCR) methods and pulsed-field gels. Diagnosis of the BCR-ABL fusion gene by Southern blot detection of bcr genetic rearrangements is the prototype of molecular cancer diagnosis. The sensitivity and clinical uses of this test are reviewed, especially its application to monitoring the response to treatment. PCR methods enable the researcher to detect 1 CML cell in a population of 10(5) cells. Clinical experience with PCR, especially in transplantation medicine, is providing a better understanding of the meaning of the terms "remission" and "cure." Newer techniques using fluorescent in situ hybridization have considerable potential for BCR-ABL detection, but no clinical experience has been gained with these techniques currently. The diagnosis of the BCR-ABL fusion gene in ALL has important clinical implications because it is the most common molecular genetic change in adult ALL and is associated with short remissions and poor outcome in all age groups. Diagnosis of the BCR-ABL fusion in ALL is difficult because the molecular findings are more heterogeneous than they are in CML. The methods available and their accuracy and sensitivity are compared. A review of their clinical impact is included.
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PMID:The role of molecular techniques in the clinical management of leukemia. Lessons from the Philadelphia chromosome. 151 23

Ph1-positive leukemias consist of acute leukemia (Ph1 AL) and CML. Cytogenetically, Ph1 AL is often associated with +6, -7, +8, +21, or +Ph1. CML is predominantly accompanied by +Ph1, +8, i (17q), +19 in myeloid crisis and +Ph1, +8, +21 in lymphoid crisis. Thus, i(17q) seems specific for myeloid crisis of CML. Ph1 constricts ABL/BCR within M-BCR in CML and in one half of the adult Ph1 AL. BCR breaks upstream to M-BCR in the other half of adult AL and in most of childhood AL. However, the breakpoint does not affect clinical and hematological features in AL. Consequently, there seems to be two types of Ph1 leukemia; one is AL representing m-BCR rearrangement and the other is CML and Ph1 AL showing M-BCR rearrangement.
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PMID:[Ph1-positive leukemia: cytogenetic outline and prognosis]. 151 45

Different aspects related to initiation of chronic myelogenous leukemia by the t(9;22) translocation and progression of the disease were investigated. Computer search indicated that the repeat within BCR exon I has significant sequence homology to the long terminal repeats of three retroviruses, to two transposons and to the Alu family. This raises the possibility that the BCR repeat is involved in the t(9;22) as well as in generation of the BCR-related loci. Possible involvement of the p53 gene in clinical transition to acute phase was studied. In six patients and cell lines where one allele of the gene was deleted, the other allele was inactivated by loss of transcription, point mutation or rearrangement. The majority of patients, however, have both p53 alleles; detailed analysis of the p53 gene in several of them indicated normal transcription and amino acid sequence.
Leukemia 1992
PMID:Initiation and progression of chronic myelogenous leukemia. 154 34

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