OR11-02 Structural Determinants of Pure Antiestrogenic Activity

Abstract

Abstract Disclosure: A. Vallet: None. M. Diennet: None. K. Thiombane: None. A. Vivet: None. S. Weber: None. M. El Ezzy: None. F. Shaikh: None. J. Poupart: None. R. Mendoza-Sanchez: None. D. Schuetz: None. A. Marinier: None. G.L. Greene: None. S.W. Fanning: None. S.N. Mader: None. Inhibitory activities of antiestrogens on estrogen receptor alpha (ERα) range from mixed antagonism/agonism (selective ER modulators; SERMs) to complete antiestrogenicity associated with accelerated ERα turnover (selective ER degraders; SERDs). Using a panel of SERMs, SERDs and PROTACs, we show that antiestrogens induce variable degrees of SUMOylation of ERα and that efficient induction of SUMOylation, rather than increased suppression of coactivator recruitment or accelerated ERα degradation, correlates with suppression of ERα basal and induced transcriptional activity in reporter assays. Antiestrogens did not induce SUMOylation of ERβ and did not suppress its basal transcriptional activity in the same assays. Chimeras between the two receptors identified ERα-specific residues required for induction of SUMOylation by antiestrogens and revealed differences according to the antiestrogen structure. In addition, induction of ERα SUMOylation by antiestrogens depended on the hydrophobicity of N-terminal residues of ligand binding domain (LBD) helix H12. L536 mutations, including those occurring in endocrine therapy-resistant breast cancer, abolished both induction of ERα SUMOylation and pure antiestrogenicity. Structures of the L536S human ERα LBD bound to fulvestrant analogs and molecular dynamics simulations revealed dynamic side chain interactions with ERα H12 in the coactivator-binding groove, and predict the impact of SUMOylation-suppressing L536 mutations on these interactions. Together, our results show that antiestrogen-induced ERα SUMOylation is associated with complete suppression of its transcriptional activity and provide insights into the structural determinants of pure antiestrogenicity. Presentation Date: Friday, June 16, 2023