Santiago Panesso-Gómez

Quiescent Ovarian Cancer Cells Secrete Follistatin to Induce Chemotherapy Resistance in Surrounding Cells in Response to Chemotherapy

Abstract Purpose: We recently reported that the transcription factor NFATC4, in response to chemotherapy, drives cellular quiescence to increase ovarian cancer chemoresistance. The goal of this work was to better understand the mechanisms of NFATC4-driven ovarian cancer chemoresistance. Experimental Design: We used RNA sequencing to identify NFATC4-mediated differential gene expression. CRISPR-Cas9 and FST (follistatin)-neutralizing antibodies were used to assess impact of loss of FST function on cell proliferation and chemoresistance. ELISA was used to quantify FST induction in patient samples and in vitro in response to chemotherapy. Results: We found that NFATC4 upregulates FST mRNA and protein expression predominantly in quiescent cells and FST is further upregulated following chemotherapy treatment. FST acts in at least a paracrine manner to induce a p-ATF2–dependent quiescent phenotype and chemoresistance in non-quiescent cells. Consistent with this, CRISPR knockout (KO) of FST in ovarian cancer cells or antibody-mediated neutralization of FST sensitizes ovarian cancer cells to chemotherapy treatment. Similarly, CRISPR KO of FST in tumors increased chemotherapy-mediated tumor eradication in an otherwise chemotherapy-resistant tumor model. Suggesting a role for FST in chemoresistance in patients, FST protein in the abdominal fluid of patients with ovarian cancer significantly increases within 24 hours of chemotherapy exposure. FST levels decline to baseline levels in patients no longer receiving chemotherapy with no evidence of disease. Furthermore, elevated FST expression in patient tumors is correlated with poor progression-free, post–progression-free, and overall survival. Conclusions: FST is a novel therapeutic target to improve ovarian cancer response to chemotherapy and potentially reduce recurrence rates.

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.