Critical phenomenon underlies de novo luminogenesis during mammalian follicle development

A key process during mammalian folliculogenesis is the formation of a fluid-filled antrum around the oocyte. While it is known that the antrum is critical for oocyte maturation and the eventual ovulation, the detailed process underlying de novo luminogenesis remains poorly understood. In this study, we investigated the spatiotemporal dynamics of lumen growth and the cellular mechanism driving this process, using advanced microscopy, molecular perturbations and computational modelling. We found that in secondary follicles, the interstitial gaps exist in a near-critical regime, characterised by a highly dynamic and interconnected fluid network with gap size obeying a power-law distribution. Above a critical size of 180 μm, we observed an onset of cell death and the emergence of a stably growing dominant fluid cavity resembling phase separation. By modelling the granulosa cells and the interstitial fluid as a binary fluid, we reproduced the near-critical and phase-separated regimes and found that a spatial gradient of cell-fluid interfacial tension, as observed experimentally, is sufficient to robustly maintain the secondary follicles in a near-critical state. Reducing cell-fluid interfacial tension globally by weakening the cell-cell adhesion between granulosa cells leads to fragmentation of fluid and growth arrest of the dominant cavity, as predicted by the model. Importantly, perturbing the critical state in secondary follicles leads to impaired follicle growth. Altogether, our study reveals how collective spatiotemporal regulation of cell junction mechanics and cell death can contribute to the effective transition between distinct regimes of fluids, which are indispensable for functional maturation of follicles.