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Query: UMLS:C0027819 (
neuroblastoma
)
27,800
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In
neuroblastoma
, the most frequent genetic alteration is gain of chromosome arm 17q, which arises from unbalanced translocations. To document these genetic events more precisely, we performed an extensive study of chromosome 17 breakpoints in 27
neuroblastoma
cell lines by using a combination of fluorescence in situ hybridization mapping with BAC/PAC clones and allele analysis with polymorphic markers. All cases exhibited one or more unbalanced chromosome 17 translocations, and 15 distinct breakpoint regions could be mapped. This high variability indicates that gene fusion or disruption events are extremely unlikely to account for the underlying oncogenic role of these translocations. However, breakpoints were not randomly distributed, most of them mapping to the proximal part of 17q. As a result of translocations, all cell lines but one exhibited gain of the 53.5 Mb-->qter fragment, bordered proximally by the clone CTC-462L7. The most telomeric breakpoint, flanked by the clone
RP11
-443M10, defined the 70.9 Mb-->qter fragment as a region of additional gain. In addition to chromosome gains, loss of heterozygosity for the short arm of chromosome 17 was observed in close to half the cases. It was either related to a chromosome 17 monosomy or to a uniparental isodisomy. Finally, in cases with a single normal chromosome 17, we show that the parental origin of the translocated chromosome 17 can be either distinct or identical to that of the normal chromosome. Similarly, multiple translocations within the same cell line can either involve the same or different chromosome 17 homologues, indicating the likely absence of parental origin bias in the generation of these alterations.
...
PMID:Variety and complexity of chromosome 17 translocations in neuroblastoma. 1469 94
Polycomb group proteins are implicated in embryogenesis and carcinogenesis through transcriptional regulation of target genes. ASXL1 and ASXL2 genes, encoding Polycomb group protein with ASXN and ASXM domains, are human homologs of Drosophila additional sex combs (asx) gene. Exons 2-13 of the ASXL2 gene are fused to exons 1-14 of the MYST3 gene in a case of therapy-related myelodysplastic syndrome due to t(2;8)(p23.3;p11.2). Here, we identified the ASXL3 gene, a novel human homolog of Drosophila asx, by using bioinformatics. ASXL3 gene, consisting of 12 exons, was located within human genome sequences
RP11
-562H1 (AC023192.8),
RP11
-265C19 (AC090989.8), and
RP11
-470B24 (AC010798.9). Complete coding sequence of human ASXL3 cDNA was determined by assembling EST BE145544, exons 4-11, and 5'-truncated KIAA1713 cDNA (AB051500.2). Partial coding sequence of mouse Asxl3 cDNA was derived from 3'-truncated C230079D11 cDNA (AK082659.1). Human ASXL3 mRNA was expressed in pancreatic islet, testis as well as in
neuroblastoma
, head and neck tumor. Human ASXL3 protein (2248 aa) with ASXN, ASXM and PHD domains was the third member of the human ASXL family. The region between ASXM and PHD domains was divergent among ASXL family members. Proline-rich domain was located within the divergent region of ASXL3, but not within that of ASXL1 and ASXL2. ASXL3-DTNA locus at chromosome 18q12.1 and ASXL2-DTNB locus at 2p23.3 were paralogous regions within the human genome. ASXL3 was a predicted cancer-associated gene, just like ASXL1 and ASXL2. This is the first report on identification and characterization of the ASXL3 gene.
...
PMID:Identification and characterization of ASXL3 gene in silico. 1513 7
