Abstract
Leptin receptor (LepRb)-expressing neurons integrate metabolic and reproductive signals, yet the role of insulin-like growth factor 1 receptor (IGF1R) signaling within these neurons remains unclear. Because IGF-1 and insulin can partially activate each other's receptors, we generated mice lacking IGF1R selectively in LepRb neurons (IGF1R(LepRb)) as well as mice lacking both IGF1R and insulin receptor (IR) in LepRb neurons (IGF1R/IR(LepRb)). These models were used to assess body growth, skeletal development, reproductive function, energy balance, and metabolic homeostasis. Deletion of IGF1R alone in LepRb neurons delayed pubertal onset, impaired adult fertility, and accelerated reproductive aging, accompanied by transient postnatal growth retardation. IGF1R deficiency also altered trabecular and cortical bone structural parameters in both sexes, supporting a role for IGF1R signaling in coordinating growth, skeletal physiology, and reproductive function. Despite reduced food intake and increased energy expenditure in females after adjusting for lean mass, IGF1R deletion caused only modest metabolic alterations, with transient decreases in body weight and largely unchanged body composition and locomotor activity. In contrast, combined deletion of IGF1R and IR in LepRb neurons resulted in marked metabolic disturbances, including increased adiposity, reduced lean mass, lower energy expenditure, decreased locomotor activity, and impaired insulin sensitivity in males. These findings indicate cooperative roles of IGF1R and IR signaling within LepRb neurons in regulating body composition, energy balance, and glucose homeostasis. Together, our results demonstrate that IGF1R signaling in LepRb neurons primarily regulates reproductive development, skeletal physiology, and growth, whereas combined IGF1R and IR signaling is required for maintaining metabolic homeostasis. These findings identify LepRb neurons as an important neuroendocrine hub integrating IGF and insulin signaling to coordinate growth, reproduction, and metabolism in a sex-dependent manner.