Description
Lineage plasticity plays an important role in the development of basal-like breast cancer (BLBC), an aggressive cancer subtype. Although studies suggest BLBC is likely to originate from luminal progenitor cells, it acquires substantial basal cell features and contains a heterogenous collection of cells exhibiting basal, luminal and bipotent phenotypes. Why luminal progenitors are prone to BLBC transformation and what drives luminal-to-basal/bipotent reprogramming remains unclear. Here we show that the transcription factor SOX9 acts as a determinant for ER– luminal stem/progenitor cells (LSPCs). SOX9 controls LSPC activity in part by activating both canonical and non-canonical NF-KB signaling. Inactivation of p53 and Rb in a BLBC mouse tumor model leads to upregulation of SOX9, which drives luminal-to-bipotent reprogramming in vivo. SOX9 deletion inhibits the progression of benign, neoplastic lesions to invasive carcinoma. Furthermore, SOX9 is overexpressed and correlated with shorter relapse-free survival in human BLBC. These data show that ER– LSPC determinant SOX9 acts as a lineage-specific driver for BLBC transformation.