CHAN, JEAN L., EDWARD C. MUN, VIOLETA STOYNEVA, CHRISTOS S. MANTZOROS, AND ALLISON B. GOLDFINE. Peptide YY levels are elevated after gastric bypass surgery. Obesity. 2006;14:194 -198. Objective: Mechanisms that promote effective and sustained weight loss in persons who have undergone Rouxen-Y gastric bypass surgery are incompletely understood but may be mediated, in part, by changes in appetite. Peptide YY (PYY) is a gut-derived hormone with anorectic properties. We sought to determine whether gastric bypass surgery alters PYY levels or response to glucose. Research Methods and Procedures: PYY and ghrelin levels after a 75-gram oral glucose tolerance test were measured in 6 morbidly obese patients 1.5 Ϯ 0.7 (SE) years after gastric bypass compared with 5 lean and 12 obese controls. Results: After substantial body weight loss (36.8 Ϯ 3.6%) induced by gastric bypass, the PYY response to an oral glucose tolerance test was significantly higher than in controls (p ϭ 0.01). PYY increased ϳ10-fold after a 75-gram glucose load to a peak of 303.0 Ϯ 37.0 pg/mL at 30 minutes (p ϭ 0.03) and remained significantly higher than fasting levels for all subsequent time-points. In contrast, PYY levels in obese and lean controls increased to a peak of ϳ2-fold, which was only borderline significant. Ghrelin levels decreased in a symmetric but opposite fashion to that of PYY. Discussion: Gastric bypass results in a more robust PYY response to caloric intake, which, in conjunction with decreased ghrelin levels, may contribute to the sustained efficacy of this procedure. The findings provide further evidence for a role of gut-derived hormones in mediating appetite changes after gastric bypass and support further efforts to determine whether PYY 3-36 replacement could represent an effective therapy for obesity.
.-Resistin is an adipocyte-secreted hormone proposed to link obesity with insulin resistance and diabetes, but no previous study has performed a joint quantitative evaluation of white adipose tissue (WAT) resistin mRNA expression and serum levels in relation to insulinemia and glycemia in mice. We have thus comparatively assessed WAT resistin mRNA expression and serum resistin levels in lean C57BL/6J mice and various mouse models of obesity, including diet-induced obese (DIO) C57BL/6J mice, high fat-fed TNF-␣ Ϫ/Ϫ mice, and brown adipose tissue (BAT)-deficient uncoupling proteindiphtheria toxin A chain (UCP1-DTA) mice. We also studied whether treatment with the weight-reducing and insulin-sensitizing compounds, MTII, an ␣-melanocyte-stimulating hormone analog, or CNTFAx15, a ciliary neurotrophic factor analog, alters resistin mRNA expression and/or circulating levels in lean and DIO C57BL/6J mice. We find that resistin mRNA expression is similar in DIO and lean C57BL/6J mice, as well as in TNF-␣ Ϫ/Ϫ and wild-type (WT) mice. Circulating resistin levels, however, are higher in DIO C57BL/6J, high fat-fed TNF-␣ Ϫ/Ϫ , and UCP1-DTA mice compared with lean controls. Moreover, although resistin mRNA expression is upregulated by MTII treatment for 24 h and downregulated by CNTFAx15 treatment for 3 or 7 days, circulating resistin levels are not altered by MTII or CNTFAx15 treatment. In addition, serum resistin levels, but not resistin mRNA expression levels, are correlated with body weight, and neither resistin mRNA expression nor serum resistin levels are correlated with serum insulin or glucose levels. We conclude that transcriptional regulation of resistin in WAT does not correlate with circulating resistin levels and that circulating resistin is unlikely to play a major endocrine role in insulin resistance or glycemia in mice.obesity; diet-induced obesity; MTII; ciliary neurotrophic factor analog; uncoupling protein-diphtheria toxin A chain; tumor necrosis factor-␣; RESISTIN is a 12.5-kda cysteine-rich protein secreted by adipocytes, which has been proposed to link obesity with insulin resistance and diabetes (14,17,38). Initial studies in mice suggested that resistin induces insulin resistance, but subsequent animal studies revealed conflicting data regarding whether resistin expression is increased (38, 39) or decreased (16, 19, 25, 26, 43) in obesity, and decreased (12, 27, 36, 38, 39) or increased (8, 43) by thiazolidinediones (TZDs), drugs known to improve insulin resistance. Moreover, although serum resistin levels measured by Western blot appeared to be elevated in genetic (ob/ob and db/db) and diet-induced models of obesity and decreased after TZD treatment or fasting (38), only a limited number of mice were studied, and thus no statistical evaluation of this difference could be performed. Furthermore, data from another study showed decreased serum resistin levels in obese mice by use of an ELISA with low accuracy and sensitivity (22). Thus the relevance and physiological role of circulating resistin in mice ...
A role for high leptin levels in the proinflammatory state associated with obesity has been proposed on the basis of observational studies, but a recent interventional study employing administration of long-acting pegylated leptin resulting in very high pharmacologic levels in obese subjects did not support this idea. These interventional studies have not yet been independently confirmed, however, and varying levels and duration of hyperleptinemia as well as the presence of comorbidities such as diabetes have not yet been investigated as potential effect modifiers. We performed three interventional studies involving administration of recombinant methionyl human leptin (r-metHuLeptin) to lean, otherwise healthy obese, and obese diabetic subjects to investigate whether increasing circulating leptin levels over a wide spectrum of values (from low physiologic to high pharmacologic) would alter serum levels of inflammatory markers and other cytokines important in the T helper cell response. Increasing leptin levels from low physiologic to high physiologic in lean men and from higher physiologic to low pharmacologic in obese men over 3 d did not alter serum interferon-gamma, IL-10, TNF-alpha, monocyte chemoattractant protein-1, or soluble intercellular adhesion molecule-1. In obese subjects with type 2 diabetes mellitus, the administration of r-metHuLeptin for 4 or 16 wk, resulting in high pharmacologic leptin levels, did not activate the TNF-alpha system or increase cytokines or inflammatory markers, including IL-10, IL-6, C-reactive protein, monocyte chemoattractant protein-1, and soluble intercellular adhesion molecule-1. These findings do not support an etiopathogenic role for leptin in proinflammatory states associated with leptin excess such as obesity and have direct relevance for the potential future therapeutic use of r-metHuLeptin in humans.
Aims/hypothesis: Peptide YY (PYY) is a gutderived hormone that has been shown to reduce short-term food intake in animals and humans. It has been proposed that deficiency of PYY contributes to obesity in humans. However, the physiology of PYY regulation by factors such as caloric restriction, or by other molecules important in energy homeostasis, e.g. leptin, remains to be fully elucidated. Materials and methods: We evaluated the effect on PYY levels of: (1) caloric ingestion (a mixed meal) in five healthy normal-weight subjects; (2) fasting for 2 or 3 days in eight lean men and seven lean women respectively; and (3) recombinant human leptin administration at physiological replacement and pharmacological doses. Results: PYY levels increased 50% after a mixed meal (p=0.01), and shortterm complete fasting for 2 or 3 days decreased leptin and PYY levels to 20-30% and 40-60% of baseline, respectively (both p<0.05). However, recombinant human leptin administration at physiological doses to restore the fasting-induced decrease of leptin levels and at pharmacological doses over the short term had no effect on PYY levels. Conclusions/interpretation: PYY increases after meal ingestion and decreases after fasting in a manner consistent with a meal-related signal of energy homeostasis. Importantly, circulating levels of this gut-secreted molecule are independent of regulation by leptin over the short term. These findings contribute towards our understanding of the homeostatic systems that regulate appetite in humans, including the possible redundancy of gastrointestinally secreted and adipocyte-secreted signals. This may be of importance for the future development of medications to treat obesity.
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