SHP (short heterodimer partner) is an orphan nuclear receptor, first described for its interaction with nuclear receptors. This study explores a new way of inhibiting the androgen-signaling pathway. We demonstrated that SHP inhibited up to 97% of AR-induced activity. Characterization of AR/SHP interaction provided evidence of a clear ligand dependency. We also showed that the LXXI/LL motifs previously found on SHP mediated the interaction with the AR ligand-binding domain (AR-LBD), the motif responsible for the interaction being slightly different from that found with ER. The AR N-terminal domain (AR-NTD), in contrast to that of other nuclear receptors, accounts for most of the entire receptor transactivation potential. SHP also interacted with AR-NTD, thus stabilizing the interaction with AR. We demonstrated that SHP inhibited both AR-LBD and NTD-dependent transactivation, which evidenced for the first time a protein capable of inhibiting a steroid receptor amino-terminal-dependent transactivation. We further characterized the SHP mechanism of action by showing that SHP reversed AR coactivator-mediated activation. Conversely, FHL2 and TIF2 counteracted SHP-mediated inhibition of AR. SHP evidences a new way of inhibiting AR activity by competing with AR coactivators. This new type of inhibitor could dictate the activity of nuclear receptors, depending on the equilibrium between activators and inhibitors.
The androgen receptor (AR) is a ligand-activated transcription factor that controls growth and survival of prostate cancer cells. In the present study, we investigated the regulation of AR activity by the receptor-interacting protein 140 (RIP140). We first showed that RIP140 could be coimmunoprecipitated with the receptor when coexpressed in 293T cells. This interaction appeared physiologically relevant because chromatin immunoprecipitation assays revealed that, under R1881 treatment, RIP140 could be recruited to the prostate-specific antigen encoding gene in LNCaP cells. In vitro glutathione S-transferase pull-down assays provided evidence that the carboxy-terminal domain of AR could interact with different regions of RIP140. By means of fluorescent proteins, we demonstrated that ligand-activated AR was not only able to translocate to the nucleus but also to relocate RIP140 from very structured nuclear foci to a diffuse pattern. Overexpression of RIP140 strongly repressed AR-dependent transactivation by preferentially targeting the ligand binding domain-dependent activity. Moreover, disruption of RIP140 expression induced AR overactivation, thus revealing RIP140 as a strong AR repressor. We analyzed its mechanism of transrepression and first demonstrated that different regions of RIP140 could mediate AR-dependent repression. We then showed that the carboxy-terminal end of RIP140 could reverse transcriptional intermediary factor 2-dependent overactivation of AR. The use of mutants of RIP140 allowed us to suggest that C-terminal binding protein played no role in RIP140-dependent inhibition of AR activity, whereas histone deacetylases partly regulated that transrepression. Finally, we provided evidence for a stimulation of RIP140 mRNA expression in LNCaP cells under androgen treatment, further emphasizing the role of RIP140 in androgen signaling.
The orphan receptor short heterodimer partner (SHP) is a common partner for a great number of nuclear receptors, and it plays an important role in many diverse physiological events. In a previous study, we described SHP as a strong repressor of the androgen receptor (AR). Herein, we addressed the mechanism of action of its negative activity on transcription. We first investigated the intrinsic repressive potential of SHP and mapped two core repressive domains to the amino acids 170-210 and 210-240. From GST pull-down assays, we demonstrated a direct interaction between SHP and diverse histone deacetylases (HDACs) as well as a strong interaction between HDAC1 and SHP inhibitory domains. We further supported the evidence for an interaction between SHP and HDAC1 by showing their co-immunoprecipitation and provided evidence for the existence of a ternary complex comprising AR, SHP, and HDAC1. The use of trichostatin A (TSA), a specific inhibitor of HDAC activity, confirmed that HDACs significantly contribute to the intrinsic transrepressive activity of SHP. Finally, we showed that TSA reversed SHP-induced repression of AR, further emphasizing the relevance of the interaction between SHP and HDACs. This latter action affected in a very similar manner SHP-mediated repression of estrogen receptor alpha (ERalpha) transactivation. Altogether, our results indicate that SHP mediates most of its repressive effect through recruitment of HDACs and suggest that the physiological actions of SHP could be affected by HDAC inhibitors.
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