Theca cell mechanosensing and regulation of follicular extracellular matrix during ovarian follicle development

Mammalian folliculogenesis is essential for female hormonal regulation and successful reproduction. While the steroidogenic functions of theca cells (TCs) have been implicated in ovarian diseases and infertility, the physico-structural properties of TCs and their associated extracellular matrix (ECM), or theca matrix, remain poorly understood. Using murine ovaries, we show that a stiff basement membrane (BM) and theca matrix constitute a mechanically instructive niche that modulates TC proliferation and Yes-associated protein (YAP) signalling in secondary follicles. We identify hyaluronic acid (HA) as a key matrix component that is actively secreted by contractile TCs. The HA scaffold, in turn, regulates TC proliferation, YAP signalling and motility, and is required for overall follicle growth. We showed that stiffer substrates enhance YAP nuclear transport in TCs, while mechanical stretch, cell packing, and curvature affect TC proliferation. In addition, TCs exhibit directed migration towards regions of positive curvature. Together, this study reveals a mechanochemical feedback mechanism that establishes TC mechanics and HA as key regulators of theca matrix formation that is essential for mammalian folliculogenesis. SIGNIFICANCEThe structural properties and mechanical functions of the basement membrane and theca cell-matrix encapsulating mammalian ovarian follicles are poorly understood. Our findings reveal that during early stage of follicle development, the basement membrane remains thin and stiff, while the theca cells actively secrete hyaluronic acid in a contractility-dependent manner. The hyaluronic acid scaffold, in turn, regulates theca cell YAP signalling, proliferation and motility that are required for functional growth of follicles. We further showed that the theca cells are mechanosensitive and fine-tune their proliferative capacity and Hippo pathways in response to substrate stiffness, stretch and curvature. Together, our study uncovers mechanoregulatory feedback between theca cells and associated extracellular matrix, offering new insights into environmental control of folliculogenesis in female reproduction.