EC:2.7.10.2 - FACTA Search

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Query: EC:2.7.10.2 (focal adhesion kinase)
44,029 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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.
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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.
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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

The cytogenetic hallmark of chronic myelogenous leukemia (CML) is the Philadelphia chromosome (Ph1), which reflects a chromosomal translocation t(9;22) and a rearrangement of the ABL and bcr genes. This marker is found in all cells arising from the same malignant precursor cell and can be detected in CML cells of the myeloid, monocytic, erythroid, and B-lymphocyte lineage. It is, however, controversial as to whether T lymphocytes of CML patients carry this gene rearrangement. An answer to this question would clarify whether the translocation in CML occurs in a pluripotent hematopoietic stem cell or in a precursor cell already committed to certain lineages, but not the T-cell lineage. To address this question, we established T-cell clones from peripheral venous blood cells of four patients with CML and screened these clones for bcr-abl fusion transcripts by means of polymerase chain reaction and Southern blot analysis. In four T-cell clones of three of these patients, the bcr-abl transcript could be detected. None of 12 T-cell clones of the fourth patient disclosed detectable bcr-abl amplification product. Both CD4+ as well as CD8+ clones displayed fused bcr-abl sequences. These data imply that in CML some but not all T lymphocytes may originate from the Ph1-positive stem cell.
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PMID:Clonal analysis of bcr-abl rearrangement in T lymphocytes from patients with chronic myelogenous leukemia. 137 Oct 78

We performed molecular studies to resolve the status of BCR and ABL in the bone marrow cells of a CML patient with a Ph chromosome resulting from a complex translocation involving chromosomes 9, 15, and 22. DNA digestion with BamHI, HindIII, and BglII, followed by hybridization to a bcr-specific 32P-labeled probe, showed a rearranged banding pattern confirming the involvement of the bcr locus in the translocation. Furthermore, total cellular RNA isolated from the marrow was subjected to reverse transcription into cDNA and amplified by PCR with primers specific for BCR-ABL fusion cDNA. The amplified products obtained from this patient and from a CML patient with the standard t(9;22) were both of the expected length of approximately 317 bp.
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PMID:Molecular confirmation of BCR-ABL fusion in a chronic myeloid leukemia with a complex translocation involving chromosomes 9, 15, and 22. 137 43

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

Twenty six patients with Philadelphia chromosome (Ph1) positive chronic myelogenous leukemia (CML) treated with IFN-alpha were classified on the basis of the fusion pattern of BCR/ABL chimeric mRNA determined by a reverse-transcriptase-polymerase chain reaction (RT-PCR) method. The relationship between the fusion pattern of BCR/ABL mRNA and the clinical outcome was also analysed. Twelve patients showed M-bcr exon 3/ABL exon 2 (B3/A2) chimeric mRNA and nine had M-bcr exon 2/ABL exon 2 (B2/A2) mRNA. Eleven of the 12 patients with B3/A2 achieved complete hematological response with IFN-alpha therapy, as did three of the nine patients with B2/A2. The mean duration to blastic crisis was significantly longer in the B3/A2 patients (mean 52.4 months) than in the B2/A2 patients (mean 26.2 months) (p less than 0.01). These results suggest that the fusion pattern of BCR/ABL mRNA may affect the therapeutic response to IFN-alpha and clinical outcome in CML patients.
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PMID:Possible correlation between fusion pattern of BCR/ABL mRNA and clinical response to alpha-interferon in chronic myelogenous leukemia. 151 6

The Philadelphia (Ph) chromosome can be detected in the vast majority of patients with chronic myelogenous leukemia (CML). We performed a long-range analysis of chromosomal translocation junction by pulsed-field gel electrophoresis (PFGE) techniques, to examine whether molecular evidence of a reciprocal Ph translocation exists in Ph-positive CML as well as Ph-negative, M-BCR rearrangement-positive CML. The rearrangement within M-BCR and ABL was detected in all patients including nine Ph-positive CML, and three Ph-negative CML. The rearranged 3'-abl fragments showed comigration with rearranged 5'-bcr fragment in rare-cutting restriction enzyme digests in all patients with Ph-positive CML. Thus, the physical linkage of the 3' part of ABL to the 5' side of M-BCR on 22q-chromosome was shown. The same linkage was also demonstrated in all three patients with Ph-negative CML. Meanwhile, the rearranged 3'-bcr fragments showed comigration with rearranged pHabl5' (or T39-1-2) fragments in all patients with Ph-positive CML, indicating the linkage of the 5' end of ABL to the 3' part of M-BCR on 9q+ chromosome. However, this linkage was absent in two Ph-negative CML patients who could be studied. The results suggest that a genomic insertion of 3' ABL into M-BCR in Ph-negative CML occurs by a single cytogenetic event rather than a two-translocation mechanism.
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PMID:Absence in Ph-negative, M-BCR rearrangement-positive chronic myelogenous leukemia of linkage between 5' ABL and 3' M-BCR sequences in Philadelphia translocation. 159 4

Pulsed field gel electrophoresis was used to construct a long-range map of the normal BCR gene. A single BssHII restriction fragment encompasses all the known exons of the BCR gene (except a small 5' part of exon one). MIuI has one restriction site within the first intron of the BCR gene and another 250 kb downstream. This MIuI fragment contains most of the BCR gene coding sequences apart from the first exon and contains more sequences downstream of the BCR gene than the BssHII fragment. The NarI restriction sites are very close to the BssHII sites in the BCR gene, but they differ in the ABL gene, so that NarI digests could theoretically provide additional information in chronic myeloid leukaemia (CML) patients. This map was used to confirm BCR gene involvement in two CML patients in whom results of conventional Southern blotting of DNA were ambiguous. It was also used in a third patient to demonstrate the presence of a breakpoint apparently outside the BCR gene. Preliminary evidence from the use of PFGE confirms the presence of three BCR-related genes homologous to 3' sequences in the classical BCR gene (BCR-1). These BCR-related genes are located at a considerable distance from BCR-1.
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PMID:Long-range mapping of the normal BCR gene. 164 56

Sequences encoded by the first exon of BCR that bind to the ABL SH2 domain are essential for the activation of the ABL tyrosine kinase and transforming potential of the chimeric BCR-ABL oncogene. The normal cellular BCR gene encodes a 160,000 dalton phosphoprotein associated with a serine/threonine kinase activity, but it shows only weak dispersed homologies to protein kinases. p160c-BCR was purified to apparent homogeneity as an oligomer of greater than 600,000 daltons that contains autophosphorylation activity and transphosphorylation activity for several protein substrates. A region containing paired cysteine residues within the 426 amino acids encoded by the first exon of BCR is essential for its novel phosphotransferase activity, which overlaps with the strong SH2-binding regions. The recent demonstration of a GTPase-activating function within the C-terminal portion of BCR suggests that the protein kinase and SH2-binding domains may work in concert with other regions of the molecule in intracellular signalling processes.
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PMID:The BCR gene encodes a novel serine/threonine kinase activity within a single exon. 165 98

The t(9;22) Philadelphia chromosome translocation fuses 5' regulatory and coding sequences of the BCR gene to the c-ABL proto-oncogene. This results in the formation of hybrid BCR-ABL mRNAs and proteins. The shift in ABL transcriptional control to the BCR promoter may play a role in cellular transformation mediated by this rearrangement. We have functionally localized the BCR promoter to a region 1 kb 5' of BCR exon 1 coding sequences by using a chloramphenicol acetyltransferase reporter gene assay. Nucleotide sequence analysis of this region revealed many consensus binding sequences for transcription factor SP1 as well as two potential CCAAT box binding factor sites and one putative helix-loop-helix transcription factor binding site. No TATA-like or "initiator" element sequences were found. Because of low steady-state levels of BCR mRNA and the high GC content (78%) of the promoter region, definitive mapping of transcription start sites required artificial amplification of BCR promoter-directed transcripts. Overexpression from the BCR promoter in a COS cell system was effective in demonstrating multiple transcription initiation sites. In order to assess the effects of chromosomal translocation on the transcriptional control of the BCR gene, we determined S1 nuclease protection patterns of poly(A)+ RNA from tumor cell lines. No differences were observed in the locations and levels of BCR transcription initiation sites between those lines that harbored the t(9;22) translocation and those that did not. This demonstrates that BCR promoter function remains intact in spite of genomic rearrangement. The BCR promoter is structurally similar to the ABL promoters. Together, this suggests that the structural fusion of BCR-ABL and not its transcriptional deregulation is primarily responsible for the transforming effect of the t(9;22) translocation.
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PMID:Characterization of the BCR promoter in Philadelphia chromosome-positive and -negative cell lines. 190 Sep 18

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