Thyrotoxicosis increases endogenous glucose production (EGP) and induces hepatic insulin resistance. We have recently shown that these alterations can be modulated by selective hepatic sympathetic and parasympathetic denervation, pointing to neurally mediated effects of thyroid hormone on glucose metabolism. Here, we investigated the effects of central triiodothyronine (T3) administration on EGP. We used stable isotope dilution to measure EGP before and after i.c.v. bolus infusion of T3 or vehicle in euthyroid rats. To study the role of hypothalamic preautonomic neurons, bilateral T3 microdialysis in the paraventricular nucleus (PVN) was performed for 2 h. Finally, we combined T3 microdialysis in the PVN with selective hepatic sympathetic denervation to delineate the involvement of the sympathetic nervous system in the observed metabolic alterations. T3 microdialysis in the PVN increased EGP by 11 ؎ 4% (P ؍ 0.020), while EGP decreased by 5 ؎ 8% (ns) in vehicle-treated rats (T3 vs. Veh, P ؍ 0.030). Plasma glucose increased by 29 ؎ 5% (P ؍ 0.0001) after T3 microdialysis versus 8 ؎ 3% in vehicle-treated rats (T3 vs. Veh, P ؍ 0.003). Similar effects were observed after i.c.v. T3 administration. Effects of PVN T3 microdialysis were independent of plasma T3, insulin, glucagon, and corticosterone. However, selective hepatic sympathectomy completely prevented the effect of T3 microdialysis on EGP. We conclude that stimulation of T3-sensitive neurons in the PVN of euthyroid rats increases EGP via sympathetic projections to the liver, independently of circulating glucoregulatory hormones. This represents a unique central pathway for modulation of hepatic glucose metabolism by thyroid hormone.deiodinase ͉ hepatic glucose metabolism ͉ hypothalamus ͉ microdialysis ͉ sympathetic nervous system T hyroid hormones are crucial regulators of metabolism, as illustrated by the profound metabolic derangements in patients with thyrotoxicosis or hypothyroidism (1). Thyrotoxicosis is associated with an increase in endogenous glucose production (EGP), hepatic insulin resistance, and concomitant hyperglycemia (1, 2). We have recently shown that selective hepatic sympathetic denervation attenuates the hyperglycemia and increased EGP during thyrotoxicosis, while selective hepatic parasympathetic denervation aggravates hepatic insulin resistance in thyrotoxic rats. By inference, the increase in EGP during thyrotoxicosis may be mediated in part by sympathetic input to the liver, while parasympathetic hepatic input may function to restrain insulin resistance during thyrotoxicosis (3).The central nervous system is emerging as an important target for several endocrine and humoral factors in regulating metabolism. Hormones like insulin (4), estrogen (5), and corticosteroids (6) appear to use dual mechanisms to affect metabolism: that is, by direct actions in the respective target tissue and by indirect actions via the hypothalamus, in turn affecting target tissues via autonomic nervous system projections. For example, it has been convinci...
The hypothalamic control of hepatic glucose production is an evident aspect of energy homeostasis. In addition to the control of glucose metabolism by the circadian timing system, the hypothalamus also serves as a key relay center for (humoral) feedback information from the periphery, with the important role for hypothalamic leptin receptors as a striking example. The hypothalamic biological clock uses its projections to the preautonomic hypothalamic neurons to control the daily rhythms in plasma glucose concentration, glucose uptake, and insulin sensitivity. Euglycemic, hyperinsulinemic clamp experiments combined with either sympathetic-, parasympathetic-, or sham-denervations of the autonomic input to the liver have further delineated the hypothalamic pathways that mediate the control of the circadian timing system over glucose metabolism. In addition, these experiments clearly showed both that next to the biological clock peripheral hormones may "use" the preautonomic neurons in the hypothalamus to affect hepatic glucose metabolism, and that similar pathways may be involved in the control of lipid metabolism in liver and white adipose tissue.
The effects of thyroid hormone (TH) status on energy metabolism and tissue-specific substrate supply in vivo are incompletely understood. To study the effects of TH status on energy metabolism and tissue-specific fatty acid (FA) fluxes, we used metabolic cages as well as (14)C-labeled FA and (3)H-labeled triglyceride (TG) infusion in rats treated with methimazole and either 0 (hypothyroidism), 1.5 (euthyroidism), or 16.0 (thyrotoxicosis) microg per 100 g/d T(4) for 11 d. Thyrotoxicosis increased total energy expenditure by 38% (P = 0.02), resting energy expenditure by 61% (P = 0.002), and food intake by 18% (P = 0.004). Hypothyroidism tended to decrease total energy expenditure (10%; P = 0.064) and resting energy expenditure (12%; P = 0.025) but did not affect food intake. TH status did not affect spontaneous physical activity. Thyrotoxicosis increased fat oxidation (P = 0.006), whereas hypothyroidism decreased glucose oxidation (P = 0.035). Plasma FA concentration was increased in thyrotoxic but not hypothyroid rats. Thyrotoxicosis increased albumin-bound FA uptake in muscle and white adipose tissue (WAT), whereas hypothyroidism had no effect in any tissue studied, suggesting mass-driven albumin-bound FA uptake. During thyrotoxicosis, TG-derived FA uptake was increased in muscle and heart, unaffected in WAT, and decreased in brown adipose tissue. Conversely, during hypothyroidism TG-derived FA uptake was increased in WAT in association with increased lipoprotein lipase activity but unaffected in oxidative tissues and decreased in liver. In conclusion, TH status determines energy expenditure independently of spontaneous physical activity. The changes in whole-body lipid metabolism are accompanied by tissue-specific changes in TG-derived FA uptake in accordance with hyper- and hypometabolic states induced by thyrotoxicosis and hypothyroidism, respectively.
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