USP8 Mutations and Cell Cycle Regulation in Corticotroph Adenomas.

Corticotroph adenomas frequently harbor somatic USP8 mutations. These adenomas also commonly exhibit underexpression of P27, a cell cycle regulator. The present study aimed to determine the influence of USP8 mutations on clinical features of Cushing's disease and to elucidate the relationship between USP8 mutations and P27 underexpression in these tumors. Retrospective study with 32 patients with Cushing's disease was followed at the Ribeirao Preto Medical School University Hospital. We evaluated the patients' clinical data, the USP8 mutation status and the gene expression of cell cycle regulators P27/CDKN1B, CCNE1, CCND1, CDK2, CDK4, and CDK6 in tumor tissue in addition to the protein expression of P27/CDKN1B. We observed somatic mutations in the exon 14 of USP8 in 31.3% of the patients. Larger tumor size was observed in patients harboring USP8 mutations (p=0.04), with similar rates of remission, age of presentation, salivary cortisol at 23:00 h and after 1 mg dexamethasone, ACTH levels, and early postoperative plasma cortisol. We observed no differences regarding the gene or protein expression of the cell cycle regulators according to USP8 mutation status. In this Brazilian series, the observed frequency of USP8 somatic mutations was similar to that reported in European ancestry populations. Although it was reasonable that USP8 mutations could contribute to cell cycle dysregulation and P27 underexpression in corticotroph adenomas, our data did not confirm this hypothesis. It is possible that increased deubiquitinase activity observed in mutated USP8 might influence other pathways related to cell growth and proliferation.

Components of the canonical and non-canonical Wnt pathways are not mis-expressed in pituitary tumors.

INTRODUCTION: Canonical and non-canonical Wnt pathways are involved in the genesis of multiple tumors; however, their role in pituitary tumorigenesis is mostly unknown. OBJECTIVE: This study evaluated gene and protein expression of Wnt pathways in pituitary tumors and whether these expression correlate to clinical outcome. MATERIALS AND METHODS: Genes of the WNT canonical pathway: activating ligands (WNT11, WNT4, WNT5A), binding inhibitors (DKK3, sFRP1), ß-catenin (CTNNB1), ß-catenin degradation complex (APC, AXIN1, GSK3ß), inhibitor of ß-catenin degradation complex (AKT1), sequester of ß-catenin (CDH1), pathway effectors (TCF7, MAPK8, NFAT5), pathway mediators (DVL-1, DVL-2, DVL-3, PRICKLE, VANGL1), target genes (MYB, MYC, WISP2, SPRY1, TP53, CCND1); calcium dependent pathway (PLCB1, CAMK2A, PRKCA, CHP); and planar cell polarity pathway (PTK7, DAAM1, RHOA) were evaluated by QPCR, in 19 GH-, 18 ACTH-secreting, 21 non-secreting (NS) pituitary tumors, and 5 normal pituitaries. Also, the main effectors of canonical (ß-catenin), planar cell polarity (JNK), and calcium dependent (NFAT5) Wnt pathways were evaluated by immunohistochemistry. RESULTS: There are no differences in gene expression of canonical and non-canonical Wnt pathways between all studied subtypes of pituitary tumors and normal pituitaries, except for WISP2, which was over-expressed in ACTH-secreting tumors compared to normal pituitaries (4.8x; p = 0.02), NS pituitary tumors (7.7x; p = 0.004) and GH-secreting tumors (5.0x; p = 0.05). ß-catenin, NFAT5 and JNK proteins showed no expression in normal pituitaries and in any of the pituitary tumor subtypes. Furthermore, no association of the studied gene or protein expression was observed with tumor size, recurrence, and progressive disease. The hierarchical clustering showed a regular pattern of genes of the canonical and non-canonical Wnt pathways randomly distributed throughout the dendrogram. CONCLUSIONS: Our data reinforce previous reports suggesting no activation of canonical Wnt pathway in pituitary tumorigenesis. Moreover, we describe, for the first time, evidence that non-canonical Wnt pathways are also not mis-expressed in the pituitary tumors.