Gene fusions of the AR-regulated gene TMPRSS2 with the ETS family transcription factor ERG characterize about 40% of castration resistant prostate cancer (CRPC) - an advanced and lethal stage of prostate cancer. AR-mediated overexpression of ERG hijacks AR inhibiting lineage-specific differentiation and increases cell invasion and migration. In vivo work revealed a causal role of ERG in initiating prostate cancer. Notably, in vitro and in vivo models of CRPC endogenously bearing T2ERG depend on ERG activity for proliferation and survival. Thus, pursuing the development of ERG-based therapeutic strategies represents a promising route for CRPC treatment, although major challenges in targeting transcription factors such as ERG have been reported. Yet, synthetic lethality approaches including genome-wide loss-of-function screens can be employed to avoid direct ERG targeting. Here, we used metastatic PCa cell lines (LNCaP, 22Rv1 and DU145) engineered with inducible systems to overexpress ERG to show that high levels of ERG expression lead to an apparent reduction in the fitness of AR-positive and negative cells. Prolonged overexpression of a mutant form of ERG, which is not able to bind DNA, does not affect cell viability indicating that ERG DNA binding and transcriptional activity are necessary for the induction of this phenotype. The ERG-mediated reduction in cellular fitness is influenced by cell adhesion and is characterized by cell cycle arrest mediated by several cell cycle inhibitors induced by ERG. As revealed by gene expression analyses and functional assays, ERG induces a less proliferative, more dedifferentiated and invasive phenotype, which lead to an apparent reduction of cellular fitness in vitro, but is characteristic of more aggressive tumor cells in vivo. Altogether, these results underscore the reliability of the developed in vitro models for ERG activity, which will be used for screening to identify therapeutic vulnerabilities unlocked by ERG in CRPC. Importantly, we also uncovered confounding factors (i.e. loss of ERG-positive cells not due to screen selection) that could impinge on the results arising from in vitro screens.

Citation Format: Francesca Lorenzin, Giulia Fracassi, Yari Ciani, Paola Gasperini, David Rickman, Francesca Demichelis. Molecular insight into ERG transcriptional activity to unravel novel therapeutic options for ERG-positive castration resistant prostate cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr LB036.