A transient epithelial plasticity state defines the developmental window for uterine gland specification

Uterine gland development and function is essential for reproduction and womens health, yet the epithelial cell states and signaling interactions that govern gland fate specification are not well understood. Here, integration of single cell and spatial transcriptomics with organoid culture, lineage tracing, and genetic and hormonal perturbation models were used to define mechanisms regulating postnatal uterine epithelial differentiation. A developmentally restricted epithelial plasticity state was identified that precedes luminal and glandular cell lineage segregation and is accompanied by dynamic reorganization of stromal-epithelial communication during uterine differentiation. Pseudotime analysis revealed progressive acquisition of gland-associated programs, including forkhead box A2 (Foxa2), retinoic acid metabolic genes, and epithelial estrogen receptor alpha (Esr1) expression. Functional studies revealed that ESR1 acquisition and retinoic acid signaling suppress the multilayered organoid phenotype associated with epithelial plasticity, thereby promoting epithelial specification and lineage commitment. Moreover, neonatal hormonal perturbation of adenogenesis and conditional deletion of Foxa2 abolished this organoid phenotype. Together, these findings demonstrate that ESR1 acquisition, retinoic acid signaling and FOXA2-dependent glandular differentiation each restrict a transient epithelial plasticity state, coupling the loss of developmental plasticity to the emergence of the glandular lineage.