Single-cell sequencing reveals suppressive transcriptional programs regulated by MIS/AMH in neonatal ovaries

Significance This study improves our understanding of the role of Müllerian inhibiting substance (MIS/AMH) in antagonizing primordial follicle activation. By applying scRNA-seq methods to neonatal mouse ovaries, we revealed transcriptional signatures associated with MIS treatment in ovarian cell types present during the first wave of folliculogenesis and follicle development. We showed that MIS inhibits pregranulosa cell differentiation and the proliferation of ovarian surface epithelium and stromal cells. MIS also uncoupled granulosa and germ cell maturation, leading to abnormal development of activated follicles. These findings identify markers and pathways related to primordial follicle quiescence that could be targeted in contraception, preservation of ovarian reserve during aging or chemotherapy, or synchronization of preantral follicle growth for IVF.
Müllerian inhibiting substance (MIS/AMH), produced by granulosa cells of growing follicles, is an important regulator of folliculogenesis and follicle development. Treatment with exogenous MIS in mice suppresses follicle development and prevents ovulation. To investigate the mechanisms by which MIS inhibits follicle development, we performed single-cell RNA sequencing of whole neonatal ovaries treated with MIS at birth and analyzed at postnatal day 6, coinciding with the first wave of follicle growth. We identified distinct transcriptional signatures associated with MIS responses in the ovarian cell types. MIS treatment inhibited proliferation in granulosa, surface epithelial, and stromal cell types of the ovary and elicited a unique signature of quiescence in granulosa cells. In addition to decreasing the number of growing preantral follicles, we found that MIS treatment uncoupled the maturation of germ cells and granulosa cells. In conclusion, MIS suppressed neonatal follicle development by inhibiting proliferation, imposing a quiescent cell state, and preventing granulosa cell differentiation.