Metabolic Association between Leptin and the Corticotropin Releasing Hormone (original) (raw)

The Role of Leptin in the Regulation of Energy Balance and Adiposity

Journal of Neuroendocrinology, 2008

Since its discovery, leptin (a 167-amino acid product of the OB gene) has quickly moved to the forefront as an important hormone for regulation of energy balance. It closes a feedback loop from adipose tissue to hypothalamic neuropeptide-containing neural circuitry involved in regulation of food intake and neuroendocrine/autonomic out¯ow. While increased central leptin signalling reduces adiposity via a reduction in food intake, it also has remarkable metabolic effects that promote leanness, independent of food intake. These include: (i) increased energy expenditure, (ii) in-place degradation of fat, and (iii) increased thermogenesis. Hypothalamic neurones that synthesize corticotropin releasing hormone and melanocortins (i.e. a-melanocyte-stimulating hormone and agouti-related protein) are likely effector pathways that mediate the anorexigenic and metabolic effects of leptin. Activation of sympathetic out¯ow (via neuropeptidergic effector pathways of central leptin) to a number of tissues that store fat might be an important mechanism through which these peripheral metabolic effects are elicited. It is proposed that these peripheral metabolic effects contribute to the satiating properties of leptin.

The Role of Leptin in the Regulation of Energy Balance and Adiposity: Leptin regulation of energy balance and adiposity

J Neuroendocrinol, 2008

Human leptin: from an adipocyte hormone to an endocrine mediator

European Journal of Endocrinology, 2000

Leptin is a mainly adipocyte-secreted protein that was discovered 5 years ago. Most of the research following this discovery focused on the role of leptin in body weight regulation, aiming to illuminate the pathophysiology of human obesity. However, more and more data are emerging that leptin is not only important in the regulation of food intake and energy balance, but that it also has a function as a metabolic and neuroendocrine hormone. It is now clear that it is especially involved in glucose metabolism, as well as in normal sexual maturation and reproduction. Besides this, interactions with the hypothalamic-pituitary-adrenal, thyroid and GH axes and even with haematopoiesis and the immune system have also been described. It has been shown that leptin secretion by the adipocyte is partly regulated by other hormones, such as insulin, cortisol, and sex steroids, mainly testosterone. Also, other hormones like thyroid hormone and GH are possibly involved in leptin synthesis. Leptin ...

The Inhibition of Growth Hormone Secretion Presented in Obesity Is Not Mediated by the High Leptin Levels: A Study in Human Leptin Deficiency Patients

The Journal of Clinical Endocrinology & Metabolism, 2003

GH secretion is regulated by hypothalamic and peripheral hormones under a very complex interplay. Superimposed on this regulation, signals of a metabolic nature connect GH secretion with the metabolic and energetic homeostasis of a given individual. GH secretion is enhanced in malnutrition and is severely impeded in obesity, but no information is available to explain why GH secretion is severely impeded or blocked in excess adiposity. Obesity is associated with high plasma levels of leptin, and leptin participates at the hypothalamic and pituitary levels in the regulation of GH secretion. Thus, it has been postulated that the inhibitory action of obesity on GH discharge may be mediated by excess leptin levels. The only situation in which obesity does not parallel leptin values is the rare case of morbid obesity due to leptin deficiency caused by missense mutation of the leptin gene. To understand the causes of GH blockade presented in obesity, patients with both homozygous and heterozygous mutations of the leptin gene and matched controls for both sex and body mass index (BMI) were studied. Three homozygous and 5 heterozygous patients with leptin gene mutations as well as 13 control subjects were studied. In all subjects basal levels of leptin and GH values stimulated by the combined administration of GHRH plus GH-releasing peptide-6 (GHRP-6) were analyzed. To analyze the effects of obesity and leptin levels, 5 groups were designed, all them matched by sex and adiposity. The number of subjects (n), Abbreviations: BMI, Body mass index; FFA, free fatty acids; GHRP-6, GH-releasing peptide-6.

Insulin and cortisol promote leptin production in cultured human fat cells

Diabetes, 1996

The aim of this study was to investigate the regulation of leptin expression and production in cultured human adipocytes using the model of in vitro differentiated human adipocytes. Freshly isolated human preadipocytes did not exhibit significant leptin mRNA and protein levels as assessed by reverse transcriptase (RT)polymerase chain reaction (PCR) and radioimmunoassay (RIA). However, during differentiation induced by a defined adipogenic serum-free medium, cellular leptin mRNA and leptin protein released into the medium increased considerably in accordance with the cellular lipid accumulation. In fully differentiated human fat cells, insulin provoked a dose-dependent rise in leptin protein. Cortisol at a near physiological concentration of 10" 8 mol/1 was found to potentiate this insulin effect by almost threefold. Removal of insulin and cortisol, respectively, was followed by a rapid decrease in leptin expression, which was reversible after readdition of the hormones. These results clearly indicate that both insulin and cortisol are potent and possibly physiological regulators of leptin expression in human adipose tissue.

Plasma Leptin and Acute Serotoninergic Stimulation of the Corticotropic Axis in Women Who Are Normal Weight or Obese

Obesity Research, 1997

In some recent studies, glucocorticoid treatment was associated with rapid induction of obese (ob) gene expression in adipose tissue of normal rats and in isolated adipocytes. We studied the effect of acute stimulation of the corticotropic axis on plasma leptin, the ob gene product, in 7 women of normal weight and 12 women with obesity. Under double-blind, placebo-controlled conditions, a single 12.5-mg dose of clomipramine, a serotonin uptake inhibitor, was administered intravenously in 15 minutes. Mean basal plasma leptin was increased more than 3-fold in subjects with obesity compared with subjects of normal weight (35.1 +/- 4.9 ng/mL vs. 8.9 +/- 1.4 ng/mL, p = 0.001). Whereas corticotropin (ACTH) and cortisol responses were increased in women who were obese compared with women who were lean, no significant effect of clomipramine infusion was found on plasma leptin concentrations measured during the following 150 minutes in both groups. There was a strong positive correlation between basal plasma leptin concentrations and body mass index (r = 0.92, p < 0.0001). In six subjects with obesity studied after a moderate weight loss, mean basal plasma leptin was significantly decreased (43.7 +/- 6.4 ng/mL before vs. 28.0 +/- 8.1 ng/mL after, p = 0.04), but the hormonal response pattern to clomipramine administration was unchanged. We conclude that, at least in the short term, an acute stimulation of the corticotropic axis does not seem to increase leptin secretion in humans, as shown by the response to the serotoninergic agent clomipramine.

Leptin, Cortisol, and GH Secretion Interactions in Short Normal Prepubertal Children

The Journal of Clinical Endocrinology & Metabolism, 2001

The hormonal regulation of the ob gene and leptin secretion in humans is still unclear. To investigate the interactions among leptin, cortisol, and GH, we analyzed and time-crosscorrelated their spontaneous 24-h secretion in 12 short normal prepubertal children of both sexes (6 females and 6 males). Time-cross-correlation analyses demonstrated that leptin and cortisol were correlated in both a negative and positive fashion. The negative correlation, with cortisol leading leptin by 4 and 3 h for boys and girls, respectively, might reflect the stimulatory effect of CRH on the sympathetic system, which inhibits leptin secretion; the positive correlation, with leptin leading cortisol by 6 and 5 h for boys and girls, respectively, might reflect a direct effect of leptin on CRH secretion in the hypophyseal portal system. Time-cross-correlation analyses also showed a strong positive correlation between GH and leptin concentrations, with GH leading leptin by 5 and 2 h for boys and girls, respectively, suggesting a possible direct leptin-releasing effect of GH on adipocytes. We conclude that cross-correlation analyses of 24-h hormone secretions under baseline physiological conditions suggest that the hypothalamic-pituitary-adrenal axis might have a prevailing inhibitory effect on leptin secretion, whereas leptin might exert a positive effect on the hypothalamic-pituitary-adrenal axis. The relation between GH and leptin could be a direct one and characterized prevalently by a positive effect of GH on leptin secretion. Further investigations using different experimental systems are needed to ascertain the validity of these math-

Leptin levels do not change acutely with food administration in normal or obese subjects, but are negatively correlated with pituitary-adrenal activity

Clinical Endocrinology, 1997

BACKGROUND Leptin is a peptide secreted by white adipose tissue which has been shown to have a major influence on body weight regulation, while animal studies have revealed widespread interconnections between leptin and other endocrine systems, especially with insulin. However, its acute regulation has been little studied in the human. We have therefore investigated the effect of a 1000 kcal meal and fasting on the levels of leptin, insulin and cortisol, in both normal and obese subjects. SUBJECTS AND DESIGN We have studied the effect of food and fasting on circulating leptin levels in 20 subjects of normal body mass index (BMI range 18-25) and in a group of 12 moderately-severely obese subjects (BMI range 34-61). We also studied the effect of food and fastina in a patient both before and after the successful removal of a pancreatic insulinoma as a model of excess insulin secretion. RESULTS Mean leptin levels were significantly higher in the obese than in the lean group (42 . 7 Ϯ 3 . 41 vs 5 . 35 Ϯ 1 . 55 mg/l, mean Ϯ SEM; P < 0 . 001), and showed a positive correlation with body mass index (r ¼ þ0 . 71; P < 0 . 001). Frequent (every 20 minutes) sampling for 3 hours after food did not show any Rapid communication 751 ᭧ 1997

Metabolic Association between Leptin and the Corticotropin Releasing Hormone (original) (raw)

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