Abstract 943: SAR439859, an orally bioavailable selective estrogen receptor degrader (SERD) that demonstrates robust antitumor efficacy and limited cross-resistance in ER+ breast cancer

Despite resistance to endocrine therapies, estrogen receptor-positive (ER+) breast cancers (BC) still rely on ER. Eliminating ER by inducing its degradation with selective ER downregulators (SERD) should induce complete ablation of ER pathways. The clinical SERD fulvestrant, although it has demonstrated clinical benefits, is hampered by its poor drug properties and undesirable pharmacokinetics, undermining its optimal clinical activity. Therefore there is an unmet need for an improved therapy targeting ER. Here we describe SAR439859, a novel, nonsteroidal, orally bioavailable SERD currently in clinical trials. SAR439859 has a potent ER antagonist and ER degrading activity that translates in a robust inhibition of ER signaling in multiple ER+ breast cancer cell lines, including tamoxifen-resistant lines as well as cell lines harboring ER mutations. SAR439859 displays a broad and superior ER degradation activity across a large panel of ER+ cells. Importantly, based on its mechanism of action SAR439859 shows limited cross-resistance with other clinical SERD molecules. SAR439859 induces strong in vivo antitumor activity against a variety of BC cell lines and patient-derived xenografts, including models that harbor ERα mutations. The transcriptional profile analysis highlighted a crosstalk of ER mutant signaling and other oncogenic pathways. Interestingly, CDK4/6 inhibition by palbociclib induces partial activation of ER pathways as potential mechanism of tumor escape, which is completely abolished by the combination of SAR439859 with palbociclib. Finally, we demonstrate that SAR439859 in combination with palbociclib can lead to higher in vivo efficacy. This study highlights novel mechanism of ER degradation by SAR439859 that leads to profound inhibition of ER signaling as well as modulation of other oncogenic pathways and provides rationale for the ongoing clinical investigation of SAR439859 in ER+ breast cancer patients, both as a single agent and in combination with approved agents, such as CDK4 inhibitor. Citation Format: Monsif Bouaboula, Maysoun Shomali, Jane Cheng, Natalia Malkova, Fangxian Sun, Malvika Koundinya, Zhuyan Guo, Stephane Poirier, Mikhail Levit, Dietmar Hoffman, Hui Cao, Laurent Bestret, Francisco Adrian, Christoph Winter, Youssef El-Ahmad, Sylvie Vincent, Frank Halley, Gary McCort, Laurent Schio, Vicky Richon, Hong Cheng, Karl Hsu, Chris Soria, Patrick Cohen, Joanne Lager, Carlos Garcia-Echeverria, Laurent Debussche. SAR439859, an orally bi