Egyszerű nézet

dc.contributor.author Mathieu V
dc.contributor.author Pirker C
dc.contributor.author Schmidt WM
dc.contributor.author Spiegl-Kreinecker S
dc.contributor.author Lotsch D
dc.contributor.author Heffeter P
dc.contributor.author Hegedűs, Balázs
dc.contributor.author Grusch M
dc.contributor.author Kiss R
dc.contributor.author Berger W
dc.date.accessioned 2016-06-29T13:13:57Z
dc.date.available 2016-06-29T13:13:57Z
dc.date.issued 2012
dc.identifier.citation pagination=399-413; journalVolume=3; journalIssueNumber=4; journalTitle=ONCOTARGET;
dc.identifier.uri http://repo.lib.semmelweis.hu//handle/123456789/3504
dc.description.abstract Melanoma is a devastating skin cancer characterized by distinct biological subtypes. Besides frequent mutations in growth- and survival-promoting genes like BRAF and NRAS, melanomas additionally harbor complex non-random genomic alterations. Using an integrative approach, we have analysed genomic and gene expression changes in human melanoma cell lines (N=32) derived from primary tumors and various metastatic sites and investigated the relation to local growth aggressiveness as xenografts in immuno-compromised mice (N=22). Although the vast majority >90% of melanoma models harbored mutations in either BRAF or NRAS, significant differences in subcutaneous growth aggressiveness became obvious. Unsupervised clustering revealed that genomic alterations rather than gene expression data reflected this aggressive phenotype, while no association with histology, stage or metastatic site of the original melanoma was found. Genomic clustering allowed separation of melanoma models into two subgroups with differing local growth aggressiveness in vivo. Regarding genes expressed at significantly altered levels between these subgroups, a surprising correlation with the respective gene doses (>85% accordance) was found. Genes deregulated at the DNA and mRNA level included well-known cancer genes partly already linked to melanoma (RAS genes, PTEN, AURKA, MAPK inhibitors Sprouty/Spred), but also novel candidates like SIPA1 (a Rap1GAP). Pathway mining further supported deregulation of Rap1 signaling in the aggressive subgroup e.g. by additional repression of two Rap1GEFs. Accordingly, siRNA-mediated down-regulation of SIPA1 exerted significant effects on clonogenicity, adherence and migration in aggressive melanoma models. Together our data suggest that an aneuploidy-driven gene expression deregulation drives local aggressiveness in human melanoma.
dc.relation.ispartof urn:issn:1949-2553
dc.title Aggressiveness of human melanoma xenograft models is promoted by aneuploidy-driven gene expression deregulation.
dc.type Journal Article
dc.date.updated 2016-06-09T11:45:17Z
dc.language.rfc3066 en
dc.identifier.mtmt 2177764
dc.identifier.wos 000304522700007
dc.identifier.pubmed 22535842
dc.contributor.department SE/AOK/I/II. Sz. Patológiai Intézet
dc.contributor.institution Semmelweis Egyetem


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