Abstract
The uterine endometrium is capable of scarless regeneration under coordinated estrogen and progesterone signaling across the menstrual cycle. Obesity suppresses progesterone production, leading to chronic estrogen exposure and increased endometrial hyperplasia (EH) risk. To define how obesity alters endometrial cell states, endometrial tissues from control and EH-predisposed mice fed either a control diet or a high-fat diet (HFD) were analyzed by single-cell RNA sequencing and tissue phenotyping. HFD reprogrammed endometrial stroma towards an inflammatory, pro-fibrotic state, reducing progesterone receptor-network-associated Aldh1a2 (+) fibroblasts and expanding estrogen receptor-network-associated Gsn⁺ fibroblasts. HFD further impaired macrophage recruitment and promoted hyperplastic epithelial signatures, consistent with increased disease severity in an EH mouse model. Stromal deletion of Estrogen Receptor α established stromal estrogen signaling as a driver of HFD-induced extracellular matrix (ECM) accumulation. Collectively, these findings identify HFD-driven fibroblast reprogramming as a central mechanism linking estrogen dominance to stromal fibrosis, defective immune clearance, and heightened EH susceptibility. We propose that, in response to progesterone, fibroblast-mediated ECM remodeling is vital to normal endometrial homeostasis.