UMLS:C0023473 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

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

The Philadelphia (Ph) translocation in CML is molecular-genetically characterized by a rearrangement of the c-abl oncogene with sequences of the bcr gene on the Ph chromosome. In leukemic cells this recombination results in the transcription of a 8.5 kb bcr/c-abl hybrid RNA which is translated into a p210 abl protein. The p210 abl protein contains, in contrast to its normal 145 abl counterpart, associated tyrosine kinase activity which is not physiologically controlled. Both genes do not participate in the acceleration of CML from chronic state into blast crisis. The majority of CML patients without cytogenetically detectable Ph chromosome also lack a bcr/abl rearrangement. However, some cases of Ph-negative CML could be reclassified into the group of Ph-positive CML by demonstration of a bcr gene rearrangement. One patient exhibited a bcr gene recombination without translocation of c-abl sequences. A similar heterogenous pattern is observed in Ph-positive acute leukemias. About 50% of cases are characterized by a bcr/abl rearrangement, as is likewise observed in Ph-positive CML. It is tempting to speculate that these patients represent Ph-positive CML cases that initially presented themselves for treatment with CML blast crisis. Particularly in pediatric Ph-positive ALL, the majority of cases show a c-abl oncogene translocation without bcr rearrangement. Precise molecular-genetic analyses of those cases are still pending. Molecular-genetic analyses have already been proven to be of clinical value 1) in the diagnosis of Ph-positive CML in the absence of cytogenetic methods, 2) in the subclassification of Ph-negative CML or Ph-positive acute leukemias.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:[Molecular genetics of the pathogenesis and classification of chronic myelocytic leukemia]. 330 31

It is clear that there are at least two classes of cancer-related genes. The more characterized of these are the oncogenes, whose activation appears to play a major role in human neoplasia. There are now two families of oncogenes, the myc and ras families, whose cooperation seems capable of transforming normal cells in culture to tumorigenic cells. As such, they appear to form complementation groups with immortalizing and transforming properties, respectively. Moreover, the oncogenes can be subclassified as tyrosine kinases or kinase related, GTP binding proteins, growth factors or growth factor receptors or nuclear proteins. More than 20 viral oncogenes have been identified, for which more than 30 proto-oncogenes or pseudogenes exist in the human genome. Many of these have been cloned, characterized to some extent, and mapped to particular chromosomes or regions of chromosomes. Further, more than 20 additional putative oncogenes or transforming genes have been identified by tumor DNA transfection studies or at sites of integration or translocation for which no viral transforming gene cognates exist. Oncogenes can be activated by increased or unregulated expression, increased copy number (duplication, amplification), or somatic mutation resulting in a protein with increased oncogenic potential. Examples of all of these mechanisms can be found in several specific human cancers or leukemias. The cytogenetic correlate of enhanced expression is a translocation between two chromosomes at specific breakpoints with no net loss of genetic material (e.g., increased c-myc expression resulting from the 8;14 translocation in Burkitt's lymphoma). The phenomenon of increased gene copy number can sometimes be visualized as trisomy or tetrasomy for a particular chromosome but more dramatically as the development of extrachromosomal DMs or as chromosomally integrated HSRs (e.g., the N-myc gene amplification seen in neuroblastoma). Finally, certain somatic mutations can be associated with translocations (e.g., the bcr/abl fusion product created as a result of the 9;22 translocation in chronic myelogenous leukemia), but they are more commonly submicroscopic (as characterized by point mutations in the ras gene family). Evidence is accumulating for a second class of cancer-related genes whose absence or inactivation is associated with tumorigenesis. These genes are associated at the cytogenetic level with chromosomal deletions, in which the breakpoints may be variable, but specific, common regions are consistently deleted.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:The involvement of oncogenes and suppressor genes in human neoplasia. 331 93

A DNA region on chromosome 22, designated M-BCR, contains the chromosomal breakpoint of the Philadelphia (Ph) translocation in all Ph positive CML patients studied to date. M-BCR is part of a gene, BCR, oriented with its 5' end towards the centromere of chromosome 22. All of the CML DNAs analysed have a breakpoint within introns of the BCR gene. As a consequence of the Ph translocation the 3' end of the BCR gene has been translocated to chromosome 9, while the 5' part remains on the Ph chromosome. The remaining BCR sequences act as an acceptor for a chromosome 9 gene, the ABL oncogene: the ABL oncogene is fused in a head-to-tail fashion to the chromosome 22 sequences. This genomic configuration results in the transcription of a novel chimeric mRNA consisting of 5' BCR sequences and 3' ABL oncogene sequences. In K562, a cell line derived from a CML patient, and in five CML patients such chimeric BCR/ABL transcripts have been demonstrated. An abnormally sized ABL protein has been detected in the cell line K562 and in leukaemic cells from patients. This protein represents the translational product of the chimeric mRNA. The role of the BCR part of the fusion protein is unknown; it is possible that the BCR moiety could alter the structure of the ABL protein and unmask its tyrosine kinase activity. By analogy with the gag/v-abl polyprotein, the CML-specific BCR/ABL protein might have transforming activity and could play an essential role in the generation and/or maintenance of CML.
...
PMID:The BCR/ABL hybrid gene. 333 59

The Philadelphia chromosome (Ph1) of chronic myelogenous leukemia (CML) contains sequences from chromosome 9, including the ABL protooncogene, that have been translocated to the breakpoint cluster region (bcr) of chromosome 22, giving rise to a bcr-ABL fusion gene, whose product has been implicated in the genesis of CML. Although chromosome 22 translocation breakpoints in CML virtually always occur within the 5.8-kilobase (kb) bcr, chromosome 9 breakpoints have been identified within the known limits of ABL in only a few instances. For a better understanding of the variability of the breakpoints on chromosome 9, we studied the CML cell line BV173. Using pulsed-field gel electrophoresis (PFGE), large-scale maps of the t(9;22) junctions were constructed. The chromosome 9 breakpoint was shown to have occurred within an ABL intron, 160 kb upstream of the v-abl homologous sequences, but still 35 kb downstream of the 5'-most ABL exon. bcr-ABL and ABL-bcr fusion genes were demonstrated on the Ph1 and the 9q+ chromosomes, respectively; both of these genes are expressed. These results suggest that the 9;22 translocation breakpoints in CML consistently occur within the limits of the large ABL gene. RNA splicing, sometimes of very large regions, appears to compensate for the variability in breakpoint location. These studies show that PFGE is a powerful new tool for the analysis of chromosomal translocations in human malignancies.
...
PMID:Long-range mapping of the Philadelphia chromosome by pulsed-field gel electrophoresis. 342 29

Chronic myelogenous leukemia (CML) is a human disease associated with a consistent chromosomal translocation that results in sequences from the c-abl locus on chromosome 9 being fused to sequences in a breakpoint cluster region (bcr) on chromosome 22. CML cells have two novel products: an 8.5-kilobase RNA transcript containing both abl and bcr and a 210-kilodalton phosphoprotein (P210) recognized by v-abl-specific antisera. To test whether the P210 is the product of the novel 8.5-kilobase bcr/abl fusion transcript, antibodies were prepared against c-abl and bcr determinants. By using these reagents and v-abl-specific antisera, it was demonstrated that the P210 in CML cells is indeed the protein product of the 8.5-kilobase transcript. By analogy to the gag/abl fusion protein of Abelson murine leukemia virus, the replacement of amino terminal c-abl sequences by bcr sequences in P210 may create a transforming protein involved in CML. A 190-kilodalton phosphoprotein that is a candidate for the normal bcr protein was identified in both HeLa and K562 cells.
...
PMID:The chronic myelogenous leukemia-specific P210 protein is the product of the bcr/abl hybrid gene. 346 Jan 76

The breakpoint regions of both translocation products of the (9;22) Philadelphia translocation of CML patient 83-H84 and their normal chromosome 9 and 22 counterparts have been cloned and analysed. Southern blotting with bcr probes and DNA sequencing revealed that the breaks on chromosome 22 occurred 3' of bcr exon b3 and that the 88 nucleotides between the breakpoints in the chromosome 22 bcr region were deleted. Besides this small deletion of chromosome 22 sequences a large deletion of chromosome 9 sequences (greater than 70 kb) was observed. The chromosome 9 sequences remaining on the 9q+ chromosome (9q+ breakpoint) are located at least 100 kb upstream of the v-abl homologous c-abl exons whereas the translocated chromosome 9 sequences (22q-breakpoint) could be mapped 30 kb upstream of these c-abl sequences. The breakpoints were situated in Alu-repetitive sequences either on chromosome 22 or on chromosome 9, strengthening the hypothesis that Alu-repetitive sequences can be hot spots for recombination.
...
PMID:Molecular analysis of both translocation products of a Philadelphia-positive CML patient. 346 34

We report on the first Philadelphia chromosome (Ph) positive chronic myelogenous leukemia (CML) characterized by a rearrangement within the 5' part of the bcr gene on chromosome 22, but outside the restricted breakpoint cluster region. In situ hybridization studies revealed a translocation of the c-abl oncogene to the Ph chromosome and Northern blot analysis identified a chimeric 8 kb bcr/abl RNA transcript in leukemic cells. These data suggest that 1. less bcr coding sequences than previously assumed may be essential for the putative transforming activity of the rearranged bcr/abl gene and 2. the bcr probes currently used for diagnostic purposes could miss Ph-positive CML cases.
...
PMID:Philadelphia-positive chronic myelogenous leukemia with breakpoint 5' of the breakpoint cluster region but within the bcr gene. 348 9

Analysis of v-abl-homologous transcripts in peripheral blood leukocytes from 20 leukemia patients revealed a 5-kb species as the major abl-mRNA present. Elevated levels of this 5-kb transcript, together with detectable levels of 2- and 10-kb abl-homologous species, were observed in mRNA samples from two patients, one with Philadelphia chromosome (Ph')-positive chronic myeloid leukemia (CML) in lymphoid blast crisis, and the other with childhood Burkitt-type B-lymphoblastic leukemia. These abl-homologous transcripts differed from the aberrant 8-kb abl-mRNA reported by others in Ph'-positive CML patients in both size and extent of v-abl-homology. No alteration in the organization of v-abl-homologous sequences was detected in the genomic DNA of the Ph'-positive CML patient. Karyotypic analysis of the Burkitt-type B-lymphoblastic leukemia patient revealed the presence of an 8,14 translocation together with a number of other chromosomal aberrations. However, no abnormality of chromosome 9 could be detected. Hence, the observed increase in c-abl transcription is not consistently associated with either gross gene rearrangement or presence of the Ph'. The high levels of c-abl mRNA may be a function of the cell type involved (early lymphoid blast), suggesting that failure to down-regulate c-abl may be a factor in the onset of pre- or early B-lymphoid leukemias.
...
PMID:Elevation of c-abl-mRNA in human leukemic B lymphoblasts. 349 35

In a patient with chronic myelocytic leukemia chromosome analysis showed a translocation (22;22) (q13;q11). Chromosomes 9 were apparently not involved. Using somatic cell hybrids and a v-abl probe, we demonstrated the translocation of c-abl sequences from chromosome 9 to chromosome 22q-. This confirms the hypothesis that the translocation of c-abl oncogene is essential for the development of Ph1 positive CML.
...
PMID:Involvement of chromosomal region 9q34 in a case of variant Ph1 translocation t(22;22). 353 33

The v-abl transforming protein P160v-abl and the P210c-abl gene product of the translocated c-abl gene in Philadelphia chromosome-positive chronic myelogenous leukemia cells have tyrosine-specific protein kinase activity. Under similar assay conditions the normal c-abl gene products, murine P150c-abl and human P145c-abl, lacked detectable kinase activity. Reaction conditions were modified to identify conditions which would permit the detection of c-abl tyrosine kinase activity. It was found that the Formalin-fixed Staphylococcus aureus formerly used for immunoprecipitation inhibits in vitro abl kinase activity. In addition, the sodium dodecyl sulfate and deoxycholate detergents formerly used in the cell lysis buffer were found to decrease recovered abl kinase activity. The discovery of assay conditions for c-abl kinase activity now makes it possible to compare P150c-abl and P145c-abl kinase activity with the altered abl proteins P160v-abl and P210c-abl. Although all of the abl proteins have in vitro tyrosine kinase activity, they differ in the way they utilize themselves as substrates in vitro. Comparison of in vitro and in vivo tyrosine phosphorylation sites of the abl proteins suggests that they function differently in vivo. The development of c-abl kinase assay conditions should be useful in elucidating c-abl function.
...
PMID:Detection of c-abl tyrosine kinase activity in vitro permits direct comparison of normal and altered abl gene products. 387 12

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>