CLCA2 promoted PCa cell adhesion inhibiting epithelial-mesenchymal transition (EMT) and activating CTNNB1 together with epithelial marker (CDH1) induction, and mesenchymal markers (SNAI2 and TWIST1) repression.
Mining of publicly available human prostate cancer oligoarray datasets revealed that the expression of numerous genes (e.g., CCND1, CD44) under the control of beta-catenin transcription is down-regulated.
The β-catenin:TCF interaction plays a critical role in the Wnt signaling pathway which is over-activated in multiple cancers, including prostate cancer.
For the first time we provide experimental evidence that the C-terminus of p53 plays an important role in the down-regulation of beta-catenin-mediated TCF-signalling in PCa-cell lines possibly via p53 transrepressional function.
Although the cellular origin of CaP in patients cannot be easily determined at present, the results imply that β-catenin inhibition is a potential therapeutic option for a subset of patients with basal-derived CaP.
In this study, we explore the relationship of p68 and β-Catenin in PCa to assess their potential co-operation in AR-dependent gene expression, which may be of importance in the development of castrate resistant prostate cancer (CRPCa).
Expression rates driven by osteoblast- specific fragments from the collagen1A1-promoter, the human Osteocalcin-promoter, the bone-sialoprotein promoter and the beta-catenin promoter depending on vitamin supplementation were analysed in five OS cell lines, in normal lung fibroblasts and in a non-osteoblastic prostate cancer cell line (LNCaP) by dual luciferase assays.
These studies indicate the involvement of AMPK in TRAIL-TZD-mediated apoptosis and β-catenin cleavage and suggest the possibility of utilizing AMPK as a therapeutic target in apoptosis-resistant prostate cancer.
Abnormal expression of Wnt5a and beta-catenin was observed in 27 (28%) and 49 (50%) of 98 prostate cancer cases, respectively, by immunohistochemical analyses.
Therefore, introducing δ-catenin mutations is an important milestone in prostate cancer metabolic adaptation by modulating β-catenin and HIF-1α signaling under glucose shortage to amplify its tumor-promoting potential.
Interestingly, C3 treatment resulted in decreased AR binding to target genes accompanied by decreased recruitment of an AR and β-catenin cofactor, coactivator-associated arginine methyltransferase 1 (CARM1), providing insight into the unrecognized function of β-catenin in prostate cancer.
Preclinical studies have demonstrated the potential of inhibitors that target WNT receptor complexes at the cell membrane or that block the interaction of β-catenin with lymphoid enhancer-binding factor 1 and the androgen receptor, in preventing prostate cancer progression.
The fat-1 gene expression inhibited prostate cancer cell proliferation via reduction of GSK-3beta phosphorylation and subsequent down-regulation of both beta-catenin and cyclin D1.
These findings demonstrate that AR can suppress beta-catenin signaling, that the AR-beta-catenin interaction can be regulated by Pin1, and that abrogation of this interaction can enhance beta-catenin/Tcf4 signaling and contribute to aggressive biological behavior in PCa.
Pharmacological inhibition of β-catenin nuclear translocation using compounds ICG001 and IWR-1 restored HLEC tight-junction integrity and inhibited prostate cancer cell transendothelial migration in vitro and lung metastasis in vivo.