Abstract P5-04-05: Glucocorticoid receptor activation inhibits proliferation of endoxifen resistant breast cancer cells and resensitizes cells to hormonal therapy

Abstract

Abstract Background: Despite the prevalent treatment options for ERα-positive breast cancer patients, and their initial efficacy for many women, ERα-positive disease still accounts for more breast cancer related deaths than any other subtype. Relapse in these patients is largely due to the development of resistance to anti-estrogen therapies such as tamoxifen. While tamoxifen and its resistance mechanisms have been extensively studied from both the bench and the bedside, relatively little is known about its active metabolite endoxifen. Our group has provided evidence that endoxifen is the most potent and clinically relevant metabolite of tamoxifen, suggesting that its characterization may be crucial to understanding tamoxifen resistance. Methods: We have developed novel endoxifen resistant MCF7 and T47D cell lines through chronic exposure to endoxifen during a period of 12-24 months. Using these models and their respective controls, we compared global gene expression profiles of endoxifen resistant cells to tamoxifen resistant cells and found marked differences between the two models. Additionally, we subjected treatment naïve cells to a genome-wide, CRISPR-mediated knockout screen to identify genes, and their associated pathways, that are likely involved in mediating endoxifen resistance. Results: Analysis of CRISPR guide RNAs enriched or depleted in response to chronic endoxifen treatment revealed that disruption of genes regulated by dexamethasone (Dex), a potent glucocorticoid receptor (GR) agonist, enhanced cells' ability to survive and proliferate in the presence of endoxifen. These data suggest that GR activation may inhibit endoxifen resistance, and that treatment of resistant cells with Dex may restore endoxifen efficacy. Indeed, Dex treatment significantly inhibited the proliferation rates of endoxifen resistant cells by 50-60% with little to no inhibitory effects in endoxifen sensitive models. Further, Dex was shown to synergize with endoxifen in resistant cells to further suppress cell proliferation, implying that Dex treatment could be utilized as an effective therapy for endocrine resistant disease. Conditioned media harvested from cells chronically exposed to Dex also resulted in substantial inhibition of endoxifen resistant cell proliferation rates. To explore potential mechanisms of these effects, we performed RNA-seq on both treatment-naïve and endoxifen resistant cells following Dex treatment. Out of 246 genes significantly regulated by Dex in endoxifen resistant cells, we identified 61 genes that were not differentially regulated in treatment naïve cells. These genes may provide insights into the mechanisms of GR activity specific to endoxifen resistant cells. Conclusions: To our knowledge, we have developed the first models of endoxifen resistance and have demonstrated that global transcriptomic changes that occur during this process are substantially different than those observed in tamoxifen resistant models. We have shown that activation of GR signaling elicits significant growth-inhibitory effects specifically in the setting of endoxifen resistance. These data identify the GR pathway as a potential novel therapeutic target for the treatment of endocrine resistant breast cancer. Citation Format: Jones CJ, Goetz MP, Ingle JN, Hawse JR. Glucocorticoid receptor activation inhibits proliferation of endoxifen resistant breast cancer cells and resensitizes cells to hormonal therapy [abstract]. In: Proceedings of the 2018 San Antonio Breast Cancer Symposium; 2018 Dec 4-8; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2019;79(4 Suppl):Abstract nr P5-04-05.