Identification of the MRTFA/SRF pathway as a critical regulator of quiescence and chemotherapy resistance in cancer
Chemoresistance is a major cause of cancer deaths. One understudied mechanism of chemoresistance is quiescence. We used single-cell culture to identify and isolate patient-derived proliferating and quiescent ovarian cancer cells (qOvCa). RNA-seq analysis indicated that hundreds of genes that are differentially expressed in qOvCa cells are transcriptional targets of the Myocardin-Related Transcription Factor-A/Serum Response Factor (MRTFA/SRF) pathway, and both genetic disruption and pharmacologic inhibition of MRTFA/SRF interaction (with the inhibitor CCG257081) induced quiescence across multiple cancer types. MRTFA/SRF inhibition-mediated quiescence is p27/Kip1 dependent and associated with a downregulation of cell cycle regulators, NCL, MYH9, and alterations in the proteasome. We show that the MRTFA/SRF axis plays a dual role in chemotherapy resistance, with both pathway inhibition and activation contributing to chemotherapy resistance in vitro and in patient samples. CCG081 treatment results in a proteasome-dependent downregulation of the stem-cell marker CD133. Suggesting a critical role for the proteasome in quiescent cells, CCG081 therapy sensitized OvCa cells to proteasome inhibitors. In vivo, we found that CCG257081 therapy could be used to induce tumor growth-arrest and delay disease growth to improve overall survival. Moreover, we found that dual therapy with CCG081 and proteasome inhibition further improved outcomes, leading to undetectable tumors in ∼20% of mice. Together, these data suggest that the MRTFA/SRF pathway is a critical regulator of quiescence in cancer and a potential therapeutic target.