Brain GLP-1 signaling regulates femoral artery blood flow and insulin sensitivity through hypothalamic PKC-δ.

OBJECTIVE: Glucagon-like peptide 1 (GLP-1) is a gut-brain hormone that regulates food intake, energy metabolism, and cardiovascular functions. In the brain, through a currently unknown molecular mechanism, it simultaneously reduces femoral artery blood flow and muscle glucose uptake. By analogy to pancreatic ß-cells where GLP-1 activates protein kinase C (PKC) to stimulate insulin secretion, we postulated that PKC enzymes would be molecular targets of brain GLP-1 signaling that regulate metabolic and vascular function. RESEARCH DESIGN AND METHODS: We used both genetic and pharmacological approaches to investigate the role of PKC isoforms in brain GLP-1 signaling in the conscious, free-moving mouse simultaneous with metabolic and vascular measurements. RESULTS: In normal wild-type (WT) mouse brain, the GLP-1 receptor (GLP-1R) agonist exendin-4 selectively promotes translocation of PKC-δ (but not -ßII, -α, or -ε) to the plasma membrane. This translocation is blocked in Glp1r(-/-) mice and in WT mice infused in the brain with exendin-9, an antagonist of the GLP-1R. This mechanism coordinates both blood flow in the femoral artery and whole-body insulin sensitivity. Consequently, in hyperglycemic, high-fat diet-fed diabetic mice, hypothalamic PKC-δ activity was increased and its pharmacological inhibition improved both insulin-sensitive metabolic and vascular phenotypes. CONCLUSIONS: Our studies show that brain GLP-1 signaling activates hypothalamic glucose-dependent PKC-δ to regulate femoral artery blood flow and insulin sensitivity. This mechanism is attenuated during the development of experimental hyperglycemia and may contribute to the pathophysiology of type 2 diabetes.

Brain glucagon-like peptide-1 regulates arterial blood flow, heart rate, and insulin sensitivity.

OBJECTIVE: To ascertain the importance and mechanisms underlying the role of brain glucagon-like peptide (GLP)-1 in the control of metabolic and cardiovascular function. GLP-1 is a gut hormone secreted in response to oral glucose absorption that regulates glucose metabolism and cardiovascular function. GLP-1 is also produced in the brain, where its contribution to central regulation of metabolic and cardiovascular homeostasis remains incompletely understood. RESEARCH DESIGN AND METHODS: Awake free-moving mice were infused with the GLP-1 receptor agonist exendin-4 (Ex4) into the lateral ventricle of the brain in the basal state or during hyperinsulinemic eu-/hyperglycemic clamps. Arterial femoral blood flow, whole-body insulin-stimulated glucose utilization, and heart rates were continuously recorded. RESULTS: A continuous 3-h brain infusion of Ex4 decreased femoral arterial blood flow and whole-body glucose utilization in the awake free-moving mouse clamped in a hyperinsulinemic-hyperglycemic condition, only demonstrating that this effect was strictly glucose dependent. However, the heart rate remained unchanged. The metabolic and vascular effects of Ex4 were markedly attenuated by central infusion of the GLP-1 receptor (GLP-1R) antagonist exendin-9 (Ex9) and totally abolished in GLP-1 receptor knockout mice. A correlation was observed between the metabolic rate and the vascular flow in control and Ex4-infused mice, which disappeared in Ex9 and GLP-1R knockout mice. Moreover, hypothalamic nitric oxide synthase activity and the concentration of reactive oxygen species (ROS) were also reduced in a GLP-1R-dependent manner, whereas the glutathione antioxidant capacity was increased. Central GLP-1 activated vagus nerve activity, and complementation with ROS donor dose-dependently reversed the effect of brain GLP-1 signaling on peripheral blood flow. CONCLUSIONS: Our data demonstrate that central GLP-1 signaling is an essential component of circuits integrating cardiovascular and metabolic responses to hyperglycemia.

Central insulin regulates heart rate and arterial blood flow: an endothelial nitric oxide synthase-dependent mechanism altered during diabetes.

OBJECTIVE: Central neural insulin regulates glucose homeostasis, but less is known about its cardiovascular effects. Endothelial nitric oxide synthase (eNOS)-derived nitric oxide (NO) represents a molecular link between metabolic and cardiovascular disease. Its role in the central nervous system remains to be determined. We studied the effects of central insulin infusion on femoral arterial blood flow and heart rate in normal chow-fed, high-fat diet-fed diabetic, and eNOS-null mice. RESEARCH DESIGN AND METHODS: We recorded heart rate and femoral blood flow (ultrasonic flow probe) during 3-h central insulin infusion in conscious, freely moving mice. To study the role of NO in this setting, we assessed total and phosphorylated eNOS in the hypothalamus and examined the effects of brain infusion of NO donors/NOS inhibitors on cardiovascular responsiveness to central insulin in these experimental mouse models. RESULTS: In normal mice, central insulin rapidly increased heart rate by 30% and more progressively increased blood flow by 40%. In high-fat diet-fed mice, the cardiovascular effects of insulin were blunted and associated with a 50% reduction of the total and phosphorylated eNOS expression in the hypothalamus, suggesting a causal link. In line with this hypothesis, in eNOS-null mice and central N(G)-monomethyl-L-arginine-infused normal mice, the cardiovascular effects of insulin were abolished, whereas central NO donor infusion restored these effects in eNOS-null mice. In high-fat diet-fed mice, central NO donor infusion mimicked the cardiovascular responses evoked by central insulin in normal mice. CONCLUSIONS: Central insulin has cardiovascular effects in conscious, freely moving mice that are mediated, at least in part, by central neural eNOS. These effects are impaired in insulin-resistant high-fat diet-fed mice.