The autonomic nervous system plays a significant role in the regulation of hepatic metabolism. Activation of hepatic sympathetic nerves increases hepatic glucose production (HGP) and glycogenolysis, and increased HGP largely contributes to the pathogenesis of type 2 diabetes mellitus. Therefore, without a full understanding of the neural circuits involved in the regulation of the liver, there is a barrier to develop strategies to control glucose levels via the brain-liver pathway. The overall long-term goal of this proposal is to elucidate the fundamental relationship between central autonomic control and hepatic carbohydrate metabolism. The paraventricular nucleus (PVN) of the hypothalamus is a critical command center controlling autonomic outflow and, thereby, influencing glucose and energy homeostasis. Since impaired glucose homeostasis in diabetic patients involves central circuits controlling autonomic output, the immediate objective of this proposal is to investigate the contribution of pre-sympathetic, liver-related PVN and ventral brainstem neurons to the maintenance of HGP and insulin action using in vivo and in vitro approaches. Our preliminary observations from diet-induced obese (DIO) mice demonstrate an overall shift toward excitation in liver-related PVN neurons and a diminished suppression of excitatory neurotransmission by insulin in pre-sympathetic ventral brainstem projecting PVN neurons. Furthermore, our data also show that liver-related brainstem neurons receive excitatory inputs from PVN neurons. These observations lead to the central hypothesis that monosynaptic connections between pre-sympathetic, liver-related PVN and ventral brainstem neurons are necessary for the regulation of hepatic carbohydrate metabolism. The proposed studies will define hypothalamic and ventral brainstem circuits involved in the sympathetic control of the liver using retrograde viral tracing and circuit mapping in combination with immunostaining. The electrophysiological studies will determine the cellular properties of liver-related neurons in control and DIO mice. Functional connections between PVN and liver-related ventral brainstem neurons will be revealed with optogenetics. The proposed in vivo studies will determine the contribution of liver-related neurons to hepatic glucose production and insulin action. Pharmacogenetic stimulation and inhibition of neurons will be used in combination with hyperinsulinemic-euglycemic clamp studies in conscious intact and adrenalectomized mice. Sympathetic activity will be assessed in a variety of organs and tissues. The outcomes of the proposed studies will establish the contribution of hypothalamic and ventral brainstem circuits to hepatic carbohydrate metabolism, advance our knowledge of sympathetic control of the liver, and may provide new strategies for the improvement of glycemic status in diabetic patients via autonomic control.
This research is relevant to public health because of the increasing prevalence of type 2 diabetes. The liver plays an important role in the maintenance of systemic glucose levels and the proposed studies focus on the regulation of the liver via the brain. Exploring neural circuits and mechanisms may lead to novel strategies to improve glucose management in diabetic patients.
