LAUSR

The balance between hepatic lipogenesis and gluconeogenesis is tightly regulated by complex signaling pathways to retain whole body energy homeostasis. As a key anabolic hormone, insulin promotes de novo lipogenesis to store excessive energy through SREBP1c activation. Simultaneously, insulin inhibits hepatic glucose production to prevent unnecessary glucose supply. FOXO1 is one of the key transcription activators that stimulate the expression of gluconeogenic genes including PEPCK and G6Pase during fasting. For an acute response, insulin rapidly suppresses hepatic gluconeogenesis through repression of FOXO1 by AKT-mediated phosphorylation. Intriguingly, lipogenic activator SREBP1c has been implicated in the suppression of hepatic glucose production although underlying mechanisms have not been clearly understood. Our recent study reveals a novel signaling pathway engaging in the inhibition of hepatic gluconeogenesis by SREBP1c. In liver, CRY1, one of the circadian clock genes, was identified as a direct target gene of SREBP1c. The expression of CRY1 was upregulated by feeding or insulin through activation of SREBP1c. To investigate whether SREBP1c-dependent CRY1 induction might repress hepatic glucose production, the gluconeogenic capacity of SREBP1c¡/¡ and CRY1¡/¡ mice was assessed by pyruvate tolerance test. Compared to wild type mice, both SREBP1c¡/¡ and CRY1¡/¡ mice showed high levels of blood glucose upon pyruvate challenge. On the other hand, CRY1-overexpresion in SREBP1c-deficient mice resulted in a decrement in pyruvate-induced blood glucose levels. Moreover, ectopic expression of CRY1 reduced the levels of blood glucose in STZ-treated diabetic mice, accompanied with decreases in gluconeogenic gene expression. These results indicate that insulin-induced SREBP1c stimulates CRY1 expression, leading to suppression of hepatic gluconeogenesis. Although CRY1 has been reported as a potential suppressor of gluconeogenesis activated by glucocorticoid receptor and glucagon signaling pathways, the roles of CRY1 in the regulation of gluconeogenesis under nutrient-rich conditions are largely unknown. In our study, we found that CRY1 accelerated the degradation of nuclear FOXO1 protein in response to insulin. While FOXO1 degradation was rapidly stimulated by AKT-mediated phosphorylation in the early phase of insulin action, CRY1-induced FOXO1 degradation was induced in the late phase of insulin action. Given our observations that CRY1induced FOXO1 degradation was independent of AKT activity, we propose that CRY1 could sustainably downregulate nuclear FOXO1 protein in late postprandial state. We also have further investigated factor(s) governing CRY1dependent FOXO1 degradation. Among several FOXO1 E3 ubiquitin ligases, we elucidated that MDM2 participated in CRY1-mediated FOXO1 degradation. CRY1 formed the protein complex with FOXO1 and MDM2, and the physical interaction between FOXO1 and MDM2 was augmented by CRY1. These findings demonstrating that CRY1-mediated FOXO1 degradation was attenuated in the absence of MDM2 prompted us to suggest that increased CRY1 by insulin-activated SREBP1c could stimulate FOXO1 ubiquitination and subsequent degradation by formingMDM2-CRY1-FOXO1 protein complex (Fig. 1). Hepatic circadian clock gene expression is regulated by daynight cycle as well as feeding-fasting cycle. Moreover, numerous metabolic processes such as gluconeogenesis and lipogenesis are controlled by circadian clock. Interestingly, peak time point of CRY1 expression was the same as the trough time point of FOXO1 expression during 24 hours, implying that CRY1 might be involved in the control of gluconeogenesis in not only feeding-dependent but also diurnal circadian dependent manner. In obese and diabetic animals, insulin fails to inhibit hepatic gluconeogenesis but activates lipogenesis, termed “selective insulin resistance," leading to hyperglycemia as well as hyperlipidemia. Furthermore, increased SREBP1c activity is closely associated with hyperlipidemia in obesity. However, unlike SREBP1c, the level of hepatic CRY1 protein was decreased in obese and diabetic animals. Notably, hepatic CRY1 overexpression relieved hyperglycemia through repressing hepatic gluconeogenic apparatus including FOXO1, G6Pase and PEPCK in db/db mice. Although it remains to be elucidated by which elevated SREBP1c fails to elevate CRY1 protein in obese and diabetic animals, it seems that