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Genomic Hybridization Analysis (genomic + hybridization_analysis)

Distribution by Scientific Domains
Medical Sciences100%

Kinds of Genomic Hybridization Analysis

  • comparative genomic hybridization analysis
    		•

    Selected Abstracts

    Alteration of enhancer of polycomb 1 at 10p11.2 is one of the genetic events leading to development of adult T-cell leukemia/lymphoma

    GENES, CHROMOSOMES AND CANCER, Issue 9 2009
    Shingo Nakahata
    Adult T-cell leukemia/lymphoma (ATLL) is a malignant tumor caused by latent human T-lymphotropic virus 1 (HTLV-1) infection. We previously identified a common breakpoint cluster region at 10p11.2 in acute-type ATLL by spectral karyotyping. Single nucleotide polymorphism array comparative genomic hybridization analysis of the breakpoint region in three ATLL-related cell lines and four patient samples revealed that the chromosomal breakpoints are localized within the enhancer of polycomb 1 (EPC1) gene locus in an ATLL-derived cell line (SO4) and in one patient with acute-type ATLL. EPC1 is a human homologue of the E(Pc) enhancer of polycomb gene of Drosophila. Inappropriate expression of the polycomb group gene family has been linked to the loss of normal gene silencing pathways, which can contribute to the loss of cell identity and malignant transformation in many kinds of cancers. In the case of the SO4 cell line, which carried a der(10)t(2;10)(p23;p11.2) translocation, EPC1 was fused with the additional sex combs-like 2 (ASXL2) gene at 2p23.3 (EPC1/ASXL2). In the case with an acute-type ATLL, who carried a der(10)del(10)(p11.2)del(10)(q22q24) translocation, a putative truncated EPC1 gene (EPC1tr) was identified. Overexpression of EPC1/ASXL2 enhanced cell growth in T-leukemia cells, and a GAL4-EPC1/ASXL2 fusion protein showed high transcriptional activity. Although a GAL4-EPC1tr fusion protein did not activate transcription, overexpression of EPC1tr accelerated cell growth in leukemia cells, suggesting that the EPC1 structural abnormalities in the SO4 cell line and in the patient with acute-type ATLL may contribute to leukemogenesis. © 2009 Wiley-Liss, Inc. [source]

    Genomewide array-based comparative genomic hybridization analysis of acute promyelocytic leukemia

    GENES, CHROMOSOMES AND CANCER, Issue 4 2006
    Sivasundaram Karnan
    Acute promyelocytic leukemia (APL) is typically associated with the t(15;17) that generates the PML,RARA fusion protein. Animal models have shown that although the fusion protein is necessary, it is insufficient for the development of APL, implying that additional mechanisms are responsible for full-blown leukemia. The mutation of specific genes has been implicated in leukemogenesis; however, alterations in gene copy number have not been well investigated. Here, we applied the genomewide array-comparative genomic hybridization technique to 30 APL clinical samples and 2 APL cell lines. It was found that (1) approximately half the clinical samples (14 of 30 APL cases) had no detectable chromosomal imbalances; and (2) the remaining 16 cases, including the cell lines, exhibited recurrent chromosomal imbalances, such as loss of 1p36, 2p11, 16p, and 17p, and gain of 8p, 8q, and 13q. These results suggest that chromosomal imbalances are largely absent in APL, although some nonrandom chromosomal imbalances could be linked to the development of APL in a limited number of cases. © 2006 Wiley-Liss, Inc. [source]

    KIT and RAS signalling pathways in testicular germ cell tumours: new data and a review of the literature

    INTERNATIONAL JOURNAL OF ANDROLOGY, Issue 4 2007
    N. C. Goddard
    Summary Testicular germ cell tumours (TGCTs) are the leading cause of cancer deaths in young male Caucasians. Identifying changes in DNA copy number can pinpoint genes involved in tumour development. We defined the smallest overlapping regions of imbalance in TGCTs using array comparative genomic hybridization analysis. Novel regions, or regions which refined those previously reported, were identified. The expression profile of genes from 12p, which is invariably gained in TGCTs, and amplicons defined at 12p11.2-12.1 and 4q12, suggest KRAS and KIT involvement in TGCT and seminoma development, respectively. Amplification of these genes was not found in intratubular germ cell neoplasia adjacent to invasive disease showing these changes, suggesting their involvement in tumour progression. Activating mutations of RAS genes (KRAS or NRAS) and overexpression of KRAS were mutually exclusive events. These, correlations between the expression levels of KIT, KRAS and GRB7 (which encodes an adapter molecule known to interact with the KIT tyrosine kinase receptor) and other reported evidence reviewed here, are consistent with a role for activation of KIT and RAS signalling in TGCT development. In order to assess a role for KIT in seminomas, we modulated the level of KIT expression in TCam-2, a seminoma cell line. The likely seminomatous origin of this cell line was supported by demonstrating KIT and OCT3/4 overexpression and gain of 12p material. Reducing the expression of KIT in TCam-2 through RNA inhibition resulted in decreased cell viability. Further understanding of KIT and RAS signalling in TGCTs may lead to novel therapeutic approaches for these tumours. [source]

    Genome-wide array-based comparative genomic hybridization analysis of pancreatic adenocarcinoma: Identification of genetic indicators that predict patient outcome

    CANCER SCIENCE, Issue 3 2007
    Panayiotis Loukopoulos
    We analyzed the subchromosomal numerical aberrations of 44 surgically resected pancreatic adenocarcinomas by array-based comparative genomic hybridization. The aberration profile ranged widely between cases, suggesting the presence of multiple or complementary mechanisms of evolution in pancreatic cancer, and was associated with lymph node metastasis and venous or serosal invasion. A large number of small loci, previously uncharacterized in pancreatic cancer, showed non-random loss or gain. Frequent losses at 1p36, 4p16, 7q36, 9q34, 11p15, 11q13, 14q32-33, 16p13, 17p11-13, 17q11-25, 18q21-tel, 19p13, 21q22 and 22q11-12, and gains at 1q25, 2p16, 2q21-37, 3q25, 5p14, 5q11-13, 7q21, 7p22, 8p22, 8q21-23, 10q21, 12p13, 13q22, 15q13-22 and 18q11 were identified. Sixteen loci were amplified recurrently. We identified novel chromosomal alterations that were significantly associated with a range of malignant phenotypes. Gain of LUNX, HCK, E2F1 and DNMT3b at 20q11, loss of p73 at 1p36 and gain of PPM1D at 17q23 independently predicted patient outcome. Expression profiling of amplified genes identified Smurf1 and TRRAP at 7q22.1, BCAS1 at 20q13.2-3, and VCL at 10q22.1 as potential novel oncogenes. Our results contribute to a complete description of genomic structural aberrations and the identification of potential therapeutic targets and genetic indicators that predict patient outcome in pancreatic adenocarcinoma. (Cancer Sci 2007; 98: 392,400) [source]