Melatonin can contribute to glucose homeostasis either by decreasing gluconeogenesis or by counteracting insulin resistance in distinct models of obesity. However, the precise mechanism through which melatonin controls glucose homeostasis is not completely understood. Male Wistar rats were administered an intracerebroventricular (icv) injection of melatonin and one of following: an icv injection of a phosphatidylinositol 3-kinase (PI3K) inhibitor, an icv injection of a melatonin receptor (MT) antagonist, or an intraperitoneal (ip) injection of a muscarinic receptor antagonist. Anesthetized rats were subjected to pyruvate tolerance test to estimate in vivo glucose clearance after pyruvate load and in situ liver perfusion to assess hepatic gluconeogenesis. The hypothalamus was removed to determine Akt phosphorylation. Melatonin injections in the central nervous system suppressed hepatic gluconeogenesis and increased hypothalamic Akt phosphorylation. These effects of melatonin were suppressed either by icv injections of PI3K inhibitors and MT antagonists and by ip injection of a muscarinic receptor antagonist. We conclude that melatonin activates hypothalamus-liver communication that may contribute to circadian adjustments of gluconeogenesis. These data further suggest a physiopathological relationship between the circadian disruptions in metabolism and reduced levels of melatonin found in type 2 diabetes patients. melatonin; gluconeogenesis; melatonin receptors; liver MELATONIN (5-methoxy-N-acetyltryptamine) is produced and secreted by the pineal gland in a circadian fashion, with peak levels during the dark phase of the light-dark cycle. The canonical function of melatonin is to transmit environmental information (i.e., the length of the dark period) to the living organism, thereby synchronizing the circadian clock in the hypothalamic suprachiasmatic nucleus (22). In vivo and in vitro experiments have demonstrated that melatonin also plays a role in energy homeostasis by regulating body mass and adiposity and leptin expression by adipocytes (1, 40). Glucose homeostasis is also altered by the absence of melatonin in such a way that pinealectomized rats display glucose intolerance and desynchronized circadian pattern of gluconeogenesis, hallmarked by increased nighttime glucose levels (17,18,23). Moreover, chronic melatonin administration has been shown to improve glucose homeostasis not only in pinealectomized rats but also in rats rendered insulin resistant by diet manipulation (16,33,34).Although it has been demonstrated that melatonin stimulates glucose uptake in adipocytes and skeletal muscle cells in vitro (10, 19), the precise mechanism by which this hormone reduces whole body glucose intolerance has not been determined precisely. In mammals, the effects of melatonin are mediated in part by specific high-affinity G protein-coupled receptors known as melatonin receptor 1 (MT1) and melatonin receptor 2 (MT2) (31). We have demonstrated previously that melatonin acts locally in the hypothalamus to activate the p...
The our objective was to investigate the adaptations induced by a low-protein, high-carbohydrate (LPHC) diet in growing rats, which by comparison with the rats fed a control (C) diet at displayed lower fasting glycemia and similar fasting insulinemia, despite impairment in insulin signaling in adipose tissues. In the insulin tolerance test the LPHC rats showed higher rates of glucose disappearance (30%) and higher tolerance to overload of glucose than C rats. The glucose uptake by the soleus muscle, evaluated in vivo by administration of 2-deoxy-[(14)C]glucose, increased by 81%. The phosphoenolpyruvate carboxykinase content and the incorporation of [1-(14)C]pyruvate into glucose was also higher in the slices of liver from the LPHC rats than in those from C rats. The LPHC rats showed increases in l-lactate as well as in other gluconeogenic precursors in the blood. These rats also had a higher hepatic production of glucose, evaluated by in situ perfusion. The data obtained indicate that the main substrates for gluconeogenesis in the LPHC rats are l-lactate and glycerol. Thus, we concluded that the fasting glycemia in the LPHC animals was maintained mainly by increases in the hepatic gluconeogenesis from glycerol and l-lactate, compensating, at least in part, for the higher glucose uptake by the tissues.
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