Growth hormone/STAT5 signaling in proopiomelanocortin neurons regulates glucoprivic hyperphagia.

Several hypothalamic neuronal populations are directly responsive to growth hormone (GH) and central GH action regulates glucose and energy homeostasis. However, the potential role of GH signaling in proopiomelanocortin (POMC) neurons has not been studied yet. Thus, we investigated whether POMC neurons are responsive to GH and if ablation of GH receptor (GHR) or STAT5 in POMC cells leads to metabolic imbalances. Approximately 60% of POMC neurons of the arcuate nucleus exhibited STAT5 phosphorylation after intracerebroventricular GH injection. Ablation of GHR or STAT5 in POMC cells did not affect energy or glucose homeostasis. However, glucoprivic hyperphagia was blunted in male and female GHR knockout mice, and in male POMC-specific STAT5 knockout mice. Additionally, the absence of GHR in POMC neurons decreased glycemia during prolonged food restriction in male mice. Thus, GH action in POMC neurons regulates glucoprivic hyperphagia as well as blood glucose levels during prolonged food restriction.

Neonatal overfeeding causes higher adrenal catecholamine content and basal secretion and liver dysfunction in adult rats.

PURPOSE: Rats that are overfed during lactation exhibit neonatal hyperleptinemia and higher visceral adiposity, hypertension, higher liver oxidative stress and insulin resistance in the liver as adults. Previously, we demonstrated that neonatal hyperleptinemia is associated with adrenal medullary hyperfunction, hypertension and liver steatosis in adulthood. Therefore, we hypothesised that adrenal and liver functions are altered in adult obese rats that were overfed during lactation, which would underlie their hypertension and liver alterations. METHODS: The litter size was reduced from ten to three male pups on the third day of lactation until weaning (SL) to induce early overfeeding in Wistar rats. The control group had ten rats per litter (NL). Rats had free access to standard diet, and water after weaning until the rats were 180 days old. RESULTS: The SL group exhibited higher adrenal catecholamine content (absolute: +35% and relative: +40%), tyrosine hydroxylase (+31%) and DOPA decarboxylase (+90%) protein contents and basal catecholamine secretion in vitro (+57%). However, the hormones of the hypothalamic-pituitary-adrenal cortex axis were unchanged. ß3-adrenergic receptor content in visceral adipose tissue was unchanged in SL rats, but the ß2-adrenergic receptor content in the liver was lower in this group (-45%). The SL group exhibited higher glycogen and triglycerides contents in the liver (+79 and +49%, respectively), which suggested microesteatosis. CONCLUSIONS: Neonatal overfeeding led to higher adrenomedullary function, but the liver ß2-adrenergic receptor content was reduced. These results may contribute to the hepatic dysfunction characteristic of liver obesity complications.

Obesity-programmed mice are rescued by early genetic intervention.

Obesity is a chronic metabolic disorder affecting half a billion people worldwide. Major difficulties in managing obesity are the cessation of continued weight loss in patients after an initial period of responsiveness and rebound to pretreatment weight. It is conceivable that chronic weight gain unrelated to physiological needs induces an allostatic regulatory state that defends a supranormal adipose mass despite its maladaptive consequences. To challenge this hypothesis, we generated a reversible genetic mouse model of early-onset hyperphagia and severe obesity by selectively blocking the expression of the proopiomelanocortin gene (Pomc) in hypothalamic neurons. Eutopic reactivation of central POMC transmission at different stages of overweight progression normalized or greatly reduced food intake in these obesity-programmed mice. Hypothalamic Pomc rescue also attenuated comorbidities such as hyperglycemia, hyperinsulinemia, and hepatic steatosis and normalized locomotor activity. However, effectiveness of treatment to normalize body weight and adiposity declined progressively as the level of obesity at the time of Pomc induction increased. Thus, our study using a novel reversible monogenic obesity model reveals the critical importance of early intervention for the prevention of subsequent allostatic overload that auto-perpetuates obesity.

Alpha1 receptor antagonist in the median raphe nucleus evoked hyperphagia in free-feeding rats.

Serotonergic neurons in the median raphe nucleus (MnR) are stimulated by α(1)-adrenergic agonists and inhibited by α(2)-agonists. This study investigated the effect of the blockade of the MnR α(1)-adrenergic receptors of free feeding rats as an attempt to elucidate the functional role of these receptors in the control of feeding behavior. In addition, an α(2)-receptor antagonist was also administered in the MnR in order to strengthen the previous suggestion that α(2)-adrenergic receptors participate in the control of feeding behavior, probably decreasing the facilitatory influence on MnR serotonergic neurons. The α(1)-adrenergic antagonist prazosin (PRA, 40 nmol) or vehicle was injected into the MnR 15 min before treatment with phenylephrine (PHE, 0.2 nmol). The α(2)-adrenergic antagonist yohimbine (YOH, 40 nmol) was administered 15 min before clonidine (CLO, 20 nmol) or vehicle in free-feeding rats. After the injections, the animals were placed in the feeding chamber for 30 min to evaluate the ingestive and non-ingestive behaviors. At the end of the experiment the quantity of food and water consumed were measured. While treatment with PRA in the MnR followed by PHE did not change the feeding behavior, PRA injection alone into the MnR caused hyperphagia accompanied by a reduction in the latency to start eating, an increase in feeding frequency and an increase in the feeding duration. Pretreatment with YOH in the MnR blocked the hyperphagic effect induced by CLO. The present data reinforce our previous suggestion that the MnR α(2)-adrenergic receptors participate in the control of feeding behavior, probably decreasing the facilitatory influence on MnR serotonergic neurons of free-feeding animals. Furthermore, these results indicate that this influence is tonically mediated by α(1)-adrenergic receptors upon MnR neurons, which inhibit food intake.

Low expression of insulin signaling molecules impairs glucose uptake in adipocytes after early overnutrition.

Experimental and clinical studies have demonstrated that early postnatal overnutrition represents a risk factor for later obesity and associated metabolic and cardiovascular disturbance. In the present study, we assessed the levels of glucose transporter 4 (GLUT-4), GLUT-1, insulin receptor (IR), IR substrate 1 (IRS-1), phosphatidylinositol 3-kinase (PI3K) and Akt expression, as well as insulin-stimulated glucose transport and Akt activity in adipocytes from adult rats previously raised in small litters (SL). The normal litter (NL) served as control group. We also investigated glycemia, insulinemia, plasma lipid levels, and glucose tolerance. Our data demonstrated that early postnatal overfeeding induced a persistent hyperphagia accompanied by a significant increase in body weight until 90 days of age. The SL group also presented a significant increase ( approximately 42%) in epidydimal fat weight. Blood glucose, plasma insulin, and lipid levels were similar among the animals from the SL and NL groups. While insulin-stimulated glucose uptake was approximately twofold higher in adipocytes from the NL group, no stimulatory effect was observed in the SL group. The impaired insulin-stimulated glucose transport in adipose cells from the SL rats was associated with a significant decrease in GLUT-4, IRS-1 and PI3K expression, and Akt activity. In contrast, IR and Akt expression in adipocytes was not different between the SL and NL groups. Despite these alterations, our results showed no differences in glucose tolerance test in rats raised under different feeding conditions. Our findings reinforce a potent and long-term effect of neonatal overfeeding, which can program major changes in the metabolic regulatory mechanisms.

Toxicity of ad lib. overfeeding: effects on cardiac tissue.

The aim of the present study was to determine the effects of ad lib. overfeeding and of dietary restriction (DR) on oxidative stress in cardiac tissue. Lipoperoxide concentrations were decreased and antioxidant enzymes were increased in moderate-DR-fed rats. Severe-DR induced increased lipoperoxide concentrations. Overfeeding increased lipoperoxide levels in cardiac tissue. Total superoxide dismutase (SOD) and Cu-Zn superoxide dismutase (Cu-Zn SOD) activities were decreased in cardiac tissue at 35 days of overfeeding. As no changes in glutathione peroxidase (GSH-Px) were observed in overfed rats, while SOD and Cu-Zn SOD activities were decreased in these animals, it is assumed that superoxide anion is an important intermediate in the toxicity of ad lib. overfeeding. Overfeeding induced alterations in markers of oxidative stress in cardiac tissue.