Purpose: Uveal melanomas (UM) are genetically simple tumors carrying few copy number alterations (CNA) and a low mutation burden, except in rare MBD4-deficient, hypermutated cases. The genomics of uveal melanoma metastatic progression has not been described. We assessed the genetic heterogeneity of primary and metastatic MBD4-proficient and-deficient uveal melanomas. Experimental Design: We prospectively collected 75 metastatic and 16 primary samples from 25 consecutive uveal melanoma patients, and performed whole-exome sequencing. Results: MBD4-proficient uveal melanomas contained stable genomes at the nucleotide level, acquiring few new single nucleotide variants (SNVs; 16 vs. 13 in metastases and primary tumors, respectively), and no new driver mutation. Five CNAs were recurrently acquired in metastases (losses of 1p, 6q, gains of 1q, 8q, and isodisomy 3). In contrast, MBD4-deficient uveal melanomas carried more than 266 SNVs per sample, with high genetic heterogeneity and TP53, SMARCA4, and GNAS new driver mutations. SNVs in MBD4-deficient contexts were exploited to unveil the timeline of oncogenic events, revealing that metastatic clones arose early after tumor onset. Surprisingly, metastases were not enriched in monosomy 3, a previously defined metastatic risk genomic feature. Monosomy 3 was associated with shorter metastatic-free interval compared with disomy 3 rather than higher rate of relapse. Conclusions: MBD4-proficient uveal melanomas are stable at the nucleotide level, without new actionable alterations when metastatic. In contrast, MBD4 deficiency is associated with high genetic heterogeneity and acquisition of new driver mutations. Monosomy 3 is associated with time to relapse rather than rate of relapse, thus opening avenues for a new genetic prognostic classification of uveal melanomas.
BackgroundThe WW domain-containing oxidoreductase (WWOX) gene, frequently altered in breast cancer, encodes a tumor suppressor whose function is mediated through its interactions with cancer-related proteins, such as the pro-apoptotic protein p73α.ResultsTo better understand the involvement of WWOX in breast tumorigenesis, we performed a yeast two-hybrid screen and co-immunoprecipitation assays to identify novel partners of this protein. We characterized the vesicular overexpressed in cancer pro-survival protein 1 (VOPP1) as a new regulator of WWOX. In breast cancer cells, VOPP1 sequestrates WWOX in lysosomes, impairs its ability to associate with p73α, and inhibits WWOX-dependent apoptosis. Overexpressed VOPP1 potentiates cellular transformation and enhances the growth of transplanted tumors in vivo. VOPP1 is overexpressed in breast tumors, especially in tumors that retain WWOX. Moreover, increased expression of VOPP1 is associated with reduced survival of patients with WWOX-positive, but not with WWOX-negative, tumors.ConclusionsThese findings emphasize the importance of the sequestration of WWOX by VOPP1 in addition to WWOX loss in breast tumors and define VOPP1 as a novel oncogene promoting breast carcinogenesis by inhibiting the anti-tumoral effect of WWOX.Electronic supplementary materialThe online version of this article (10.1186/s12915-018-0576-6) contains supplementary material, which is available to authorized users.
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