A single-copy Sleeping Beauty transposon mutagenesis screen identifies new PTEN-cooperating tumor suppressor genes.

The overwhelming number of genetic alterations identified through cancer genome sequencing requires complementary approaches to interpret their significance and interactions. Here we developed a novel whole-body insertional mutagenesis screen in mice, which was designed for the discovery of Pten-cooperating tumor suppressors. Toward this aim, we coupled mobilization of a single-copy inactivating Sleeping Beauty transposon to Pten disruption within the same genome. The analysis of 278 transposition-induced prostate, breast and skin tumors detected tissue-specific and shared data sets of known and candidate genes involved in cancer. We validated ZBTB20, CELF2, PARD3, AKAP13 and WAC, which were identified by our screens in multiple cancer types, as new tumor suppressor genes in prostate cancer. We demonstrated their synergy with PTEN in preventing invasion in vitro and confirmed their clinical relevance. Further characterization of Wac in vivo showed obligate haploinsufficiency for this gene (which encodes an autophagy-regulating factor) in a Pten-deficient context. Our study identified complex PTEN-cooperating tumor suppressor networks in different cancer types, with potential clinical implications.

Identification of somatic VHL gene mutations in sporadic head and neck paragangliomas in association with activation of the HIF-1α/miR-210 signaling pathway.

CONTEXT: Head and neck paragangliomas (HNPGLs) arise from parasympathetic paraganglias and 35% to 45% are hereditary caused by mutations in succinate dehydrogenase (SDH) genes. The connection between SDH and tumor development is unclear. The most accepted hypothesis proposes a central role for the pseudohypoxic (pHx) pathway activated by hypoxia-inducible factor (HIF). Paradoxically, we showed that activation of HIF in HNPGLs is restricted to a subset of HNPGLs lacking SDH mutations. These tumors overexpress HIF-1α protein and target genes and the HIF-inducible microRNA miR-210 (pHx-HNPGLs). OBJECTIVE: The present study aimed at unraveling the SDH-independent mechanisms involved in the activation of HIF in HNPGLs. DESIGN: The VHL gene was analyzed in 53 tumors by gene sequencing, multiplex-ligation-dependent probe amplification, and quantitative PCR. The miR-210, HIF-1α, and CA9 levels were used as markers of the pHx gene signature. Meta-analysis of the transcriptome of pHx-HNPGLs was performed using the Oncomine platform. Assays in cells lacking functional pVHL and HIF-1α were performed to analyze the role of pVHL/HIF-1α on miR-210 expression. RESULTS: We identified, for the first time, somatic VHL mutations in HNPGLs. These were found in 2 of 4 pHx-HNPGLs with concomitant loss of heterozygosity in one of them; but not in non-pHx-HNPGLs. Meta-analysis of the transcriptome of pHx-HNPGLs revealed that these tumors are highly related to clear cell renal cell carcinoma. Cell-based assays showed that loss of pVHL lead to upregulation of miR-210 mainly via HIF-1α activation. CONCLUSIONS: VHL, involved in tumorigenesis of PGLs and clear cell renal cell carcinomas, may be an important player in the pathogenesis of sporadic HNPGLs via activation of an HIF-1α/miR-210 pHx pathway.

Identification of a signaling axis HIF-1α/microRNA-210/ISCU independent of SDH mutation that defines a subgroup of head and neck paragangliomas.

BACKGROUND: Head and neck paragangliomas (HNPGLs) are rare tumors associated with the parasympathetic nervous system. Most are sporadic, but about one third result from germline mutations in succinate dehydrogenase (SDH) genes (SDHB, SDHC, SDHD, SDHA, or SDHAF2). Although a molecular connection between SDH dysfunction and tumor development is still unclear, the most accepted hypothesis proposes a central role of the pseudohypoxic pathway. SDH dysfunction induces abnormal stabilization of the hypoxia-inducible factors (HIFs) that regulate target genes involved in proliferation, apoptosis, angiogenesis, and metabolism. The involvement of these pathways in the development of sporadic HNPGLs is presently unknown. OBJECTIVE: To get some insights into the hypoxic/pseudohypoxic molecular basis of HNPGLs, we attempted to define the gene, microRNA (miRNA), and HIF-1α expression patterns that distinguish tumors from normal paraganglia tissue. DESIGN: Genome microarray and TaqMan low-density arrays were used to analyze gene and miRNA expression, respectively, in 17 HNPGL tumor tissues and three normal human carotid bodies. Twelve HNPGLs were used for validation of data. HIF-1α, SDHB, and iron-sulfur cluster scaffold protein (ISCU) protein expression was analyzed by immunohistochemistry. RESULTS: We found activation of a canonical HIF-1α-related gene expression signaling only in a subset of HNPGLs from patients that did not harbor germline or somatic SDH mutations. The pseudohypoxic signature consisted in the overexpression of both HIF-1α-target genes and the HIF-1α-inducible miRNA, miR-210, and down-regulation of the miR-210 target gene, ISCU1/2. A decreased level of the iron-sulfur-containing protein SDHB was found by immunohistochemical analysis performed in two of these tumors. CONCLUSIONS: Collectively, this study unveiled a putative signaling axis of HIF-1α/miRNA-210/ISCU in a subset of HNPGLs that could have an impact on SDHB protein stability by a mechanism independent of SDH mutations, thus providing a foundation to better understand the functional interplay between HIF, miR-210, and mitochondria and its relevance in the pathogenesis of HNPGLs.

MAX mutations cause hereditary and sporadic pheochromocytoma and paraganglioma.

PURPOSE: Pheochromocytomas (PCC) and paragangliomas (PGL) are genetically heterogeneous neural crest-derived neoplasms. Recently we identified germline mutations in a new tumor suppressor susceptibility gene, MAX (MYC-associated factor X), which predisposes carriers to PCC. How MAX mutations contribute to PCC/PGL and associated phenotypes remain unclear. This study aimed to examine the prevalence and associated phenotypic features of germline and somatic MAX mutations in PCC/PGL. DESIGN: We sequenced MAX in 1,694 patients with PCC or PGL (without mutations in other major susceptibility genes) from 17 independent referral centers. We screened for large deletions/duplications in 1,535 patients using a multiplex PCR-based method. Somatic mutations were searched for in tumors from an additional 245 patients. The frequency and type of MAX mutation was assessed overall and by clinical characteristics. RESULTS: Sixteen MAX pathogenic mutations were identified in 23 index patients. All had adrenal tumors, including 13 bilateral or multiple PCCs within the same gland (P < 0.001), 15.8% developed additional tumors at thoracoabdominal sites, and 37% had familial antecedents. Age at diagnosis was lower (P = 0.001) in MAX mutation carriers compared with nonmutated cases. Two patients (10.5%) developed metastatic disease. A mutation affecting MAX was found in five tumors, four of them confirmed as somatic (1.65%). MAX tumors were characterized by substantial increases in normetanephrine, associated with normal or minor increases in metanephrine. CONCLUSIONS: Germline mutations in MAX are responsible for 1.12% of PCC/PGL in patients without evidence of other known mutations and should be considered in the genetic work-up of these patients.