RESUMO
Breast cancer remains a leading cause of cancer-related death in women, and triple negative breast cancer (TNBC) lacks clinically actionable therapeutic targets. Death in mitosis is a tumor suppressive mechanism that occurs in cancer cells experiencing a defective M phase. The orphan estrogen-related receptor beta (ERRß) is a key reprogramming factor in murine embryonic and induced pluripotent stem cells. In primates, ERRß is alternatively spliced to produce several receptor isoforms. In cellular models of glioblastoma, short form (ERRßsf) and beta2 (ERRß2) splice variants differentially regulate cell cycle progression in response to the synthetic agonist DY131, with ERRß2 driving arrest in G2/M.The goals of the present study are to determine the cellular function(s) of ligand-activated ERRß splice variants in breast cancer and evaluate the potential of DY131 to serve as an antimitotic agent, particularly in TNBC. DY131 inhibits growth in a diverse panel of breast cancer cell lines, causing cell death that involves the p38 stress kinase pathway and a bimodal cell cycle arrest. ERRß2 facilitates the block in G2/M, and DY131 delays progression from prophase to anaphase. Finally, ERRß2 localizes to centrosomes and DY131 causes mitotic spindle defects. Targeting ERRß2 may therefore be a promising therapeutic strategy in breast cancer.