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Query: UMLS:C0028754 (obesity)
 124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Several dominant mutations at the murine agouti locus result in the expression of a number of phenotypic changes, including a predominantly yellow coat color, obesity, and hyperinsulinemia. The mutants exhibit ectopic overexpression of normal agouti protein, suggesting that agouti regulates coat coloration by direct antagonism of the alpha-melanocyte-stimulating hormone receptor. We have tested this hypothesis by examining agouti inhibition of both melanocortin-stimulated cyclic adenosine monophosphate production and the binding of a radioactive melanocortin analog in the murine B16F10 melanoma cell line. Inhibition of melanocortin-induced cyclic nucleotide accumulation did not require preincubation of the cells with agouti and was independent of the agonist used. Furthermore, inhibition of both agonist binding to and activation of melanocortin receptor could be described by a simple competitive model with similar inhibition constants of 1.9 and 0.9 nM, respectively. The mutually exclusive binding of agouti and melanocortin was verified by cross-linking experiments using a radiolabeled alpha-melanocyte-stimulating hormone analog. Competitive inhibition of alpha-melanocyte-stimulating hormone binding can account for the effects of agouti on coat coloration and suggests the possibility that the other phenotypic changes observed on agouti overexpression may be due to direct action of agouti at a novel melanocortin receptor(s).
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PMID:Agouti antagonism of melanocortin binding and action in the B16F10 murine melanoma cell line. 754 13

The genetic loci agouti and extension control the relative amounts of eumelanin (brown-black) and phaeomelanin (yellow-red) pigments in mammals: extension encodes the receptor for melanocyte-stimulating hormone (MSH) and agouti encodes a novel 131-amino-acid protein containing a signal sequence. Agouti, which is produced in the hair follicle, acts on follicular melanocytes to inhibit alpha-MSH-induced eumelanin production, resulting in the subterminal band of phaeomelanin often visible in mammalian fur. Here we use partially purified agouti protein to demonstrate that agouti is a high-affinity antagonist of the MSH receptor and blocks alpha-MSH stimulation of adenylyl cyclase, the effector through which alpha-MSH induces eumelanin synthesis. Agouti was also found to be an antagonist of the melanocortin-4 receptor, a related MSH-binding receptor. Consequently, the obesity caused by ectopic expression of agouti in the lethal yellow (Ay) mouse may be due to the inhibition of melanocortin receptor(s) outside the hair follicle.
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PMID:Agouti protein is an antagonist of the melanocyte-stimulating-hormone receptor. 793 41

Several mutations that cause ectopic expression of the agouti gene result in obesity, hyperinsulinemia, and yellow coat color. A candidate pathway for agouti induced obesity and hyperinsulinemia is through altered signaling by melanocortin receptors, as agouti normally regulates coat coloration through antagonism of melanocortin receptor 1. Furthermore, melanocortin peptides mediate functions including steroidogenesis, lipolysis, and thermoregulation. We report apparent inhibition dissociation constants for mouse and human agouti protein inhibition of ligand binding to the melanocortin receptors, to determine which of these receptors might be involved in agouti induced diabetes. The similarity in the apparent K(I) values for agouti inhibition of ligand binding to the brain melanocortin receptors 3 and 4 (mouse: K(I) app = 190 +/- 74 and 54 +/- 18 nM; human: K(I) app = 140 +/- 56 and 70 +/- 18 nM, respectively) suggests that the MC3-R is a potential candidate for a receptor mediating the effects of agouti protein overexpression. Agouti residues important for melanocortin receptor inhibition were identified through the analysis of deletion constructs and site-specific variants. Val83 is important for inhibition of binding to MC1-R (K(I) app for Val83Ala agouti increased 13-fold relative to wild-type protein). Arg85, Pro86, and Pro89 are important for selective inhibition of binding between MC1-R and MC3-R and MC4-R as their apparent K(I) values are essentially unchanged at MC1-R, while they have increased 6-10-fold relative to wild-type protein at MC3-R and MC4-R.
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PMID:Mutations in the carboxyl terminus of the agouti protein decrease agouti inhibition of ligand binding to the melanocortin receptors. 904 7

Melanocortins, melanocyte-stimulating hormones (MSH) and adrenocorticotropic hormone (ACTH) are homologous natural peptides derived from pro-opiomelanocortin (POMC). Recent breakthroughs in melanocortin receptor (MCR) biology are relevant to neuroimmunomodulation because melanocortins are known to modulate fever, inflammation and immunity, by acting both on peripheral targets and within the brain. During fever, endogenous melanocortins exert antipyretic effects by acting on MCR located within the brain, suggesting a protective counterregulatory role of the central melanocortin system. MCR are also found in melanocytic cells and adrenal cortical cells, the classical targets for alpha-MSH and ACTH, respectively, in myelogenous and lymphoid tissues, and in various endocrine and exocrine glands, adipocytes, and in autonomic ganglia. In the CNS, MCR are prominently distributed in close proximity to the terminal fields of melanocortinergic neurons that innervate neuroendocrine and autonomic motor nuclei as well as other subcortical brain regions important in neuroendocrine and autonomic regulation, sensory processing and various aspects of behavior. Furthermore, the presence of MCR in circumventricular organs of the brain provides direct access of systemic melanocortin hormones to central MCR. Together, these attributes provide an anatomical basis for bidirectional MCR-mediated communication between brain and periphery. A group of five G-protein-associated MCR subtypes, each of which is positively coupled to adenylate cyclase, has been identified. Among these, the adrenal ACTH receptor (MC2-R) is selectively activated by ACTH. In contrast, the other MCR subtypes (MC1-R, MC3-R, MC4-R, MC5-R) recognize a common group of ligands that includes various forms of MSH as well as ACTH; nevertheless they do exhibit important differences in ligand selectivity. MCR concentrations and MCR mRNA levels are influenced by availability of cognate ligands, by drugs, and by pathological stimuli. Two types of endogenous MCR antagonist proteins have been discovered: agouti protein and the corticostatins. Agouti protein dramatically alters coat color in mammals by antagonizing melanocytic MC1-R. Moreover, spontaneous dominant mutations of the agouti gene in several strains of mice lead to its ubiquitous overexpression and produces not only yellow coat color, but also obesity and insulin resistance, perhaps as a result of its antagonism of other MCR subtypes. The recent emergence of synthetic MCR antagonists, and the feasibility of molecular approaches for targeted inactivation of individual MCR subtypes, should facilitate elucidation of the roles and mechanisms of neuroimmunomodulation by endogenous melanocortins, and the determination of whether selective pharmacological targeting of MCR may ultimately have therapeutic utility.
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PMID:Receptor biology of the melanocortins, a family of neuroimmunomodulatory peptides. 921 48

Expression of Agouti protein is normally limited to the skin where it affects pigmentation, but ubiquitous expression causes obesity. An expressed sequence tag was identified that encodes Agouti-related protein, whose RNA is normally expressed in the hypothalamus and whose levels were increased eightfold in ob/ob mice. Recombinant Agouti-related protein was a potent, selective antagonist of Mc3r and Mc4r, melanocortin receptor subtypes implicated in weight regulation. Ubiquitous expression of human AGRP complementary DNA in transgenic mice caused obesity without altering pigmentation. Thus, Agouti-related protein is a neuropeptide implicated in the normal control of body weight downstream of leptin signaling.
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PMID:Antagonism of central melanocortin receptors in vitro and in vivo by agouti-related protein. 931 20

The agouti protein plays an important role in the development of diabetes and obesity in rodents and has been shown to be a potent antagonist of melanocortin receptors. For this reason alanine-scanning mutagenesis was performed on the agouti protein carboxyl terminus to locate residues important for melanocortin receptor binding inhibition. When agouti residues Arg116 and Phe118 are changed to alanine, very large decreases in agouti affinity for melanocortin receptor 1, 3, and 4 result. Mutation of Phe117 to alanine causes a similar increase in agouti KI app at melanocortin receptor 4. Substitution of agouti residue Asp108 with alanine results in large increases in KI app for all three melanocortin receptors examined. All of these residues are conserved in the agouti-related transcript, ART, whose expression is up-regulated in animal models of obesity. The three-dimensional structure of the agouti carboxyl terminus was modeled, and residues which decrease receptor binding by a factor of > or = 15 when mutated to alanine localize to one side of the structure. These agouti variants with altered receptor selectivity may be useful in determining the role of melanocortin receptors in diabetes and obesity.
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PMID:Melanocortin receptor binding determinants in the agouti protein. 945 89

The application of molecular and genetic techniques to the study of body weight regulation have produced exciting new insights into the physiological systems governing energy expenditure, appetite, and metabolic signaling. A number of new peptides have been identified that play important roles in these regulatory systems. These include the hormone leptin, the short and long forms of the leptin receptor, uncoupling proteins, agouti protein, melanocortin receptor isoforms, melanin-concentrating hormone, and the proteins responsible for tub and fat, two monogenic mouse models of obesity. This article reviews some of the new insights gained from studies of these peptides. Although much of this new knowledge has come from studies of obesity, there may be implications for the clinical syndromes associated with weight loss. As more is learned about these systems, potential new targets for therapeutic intervention will likely become evident. These interventions may develop first as obesity treatments, but investigators and clinicians involved in the care of cachectic patients should follow these scientific developments as well.
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PMID:Recently identified peptides involved in the regulation of body weight. 962 80

The cloning of mouse obesity genes and their human homologues provides unique opportunities to identify novel cellular targets for therapeutic intervention. The first of these to be cloned, agouti, antagonizes central nervous system melanocortin receptor (MCR) binding, resulting in hyperphagia and an obesity/hyperinsulinemia syndrome. There appears to be significant cross-talk between the agouti and leptin signaling systems. Agouti antagonism of central nervous system (CNS) MCR binding inhibits the anorexic effects of leptin, whereas agouti up-regulates adipocyte leptin expression, serving to limit the magnitude of agouti-induced obesity. The effects of agouti and leptin mutations on obesity, however, are independent and additive. Agouti also regulates adipocyte lipid metabolism, functioning both to increase the expression and activity of lipogenic genes and to inhibit lipolysis. Both of these actions occur via a Ca(2+)-dependent mechanism, suggesting that modulation of adipocyte Ca2+ transport may be a key target for further investigation.
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PMID:Agouti/melanocortin interactions with leptin pathways in obesity. 976 77

The regulation of body fat stores is a problem of energy and nutrient balance that can be most readily viewed as a feedback system. Several elements are involved in any feedback system, including afferent signals, a controller that senses the afferent signals and transduces their information and then activates efferent controls that regulate the controlled system. The recent discovery of leptin has provided a major missing link in the feedback control system. This afferent signal is produced exclusively in fat cells of nonpregnant mammals but can be produced in the placenta as well. This circulating peptide has a very strong relationship to the level of body fat and its absence experimentally and clinically produces massive obesity. In the controller, or brain, several anatomic regions play a central role in regulating fat stores. Damage to the ventromedial nucleus (VMH) or the paraventricular nucleus (PVN) in the hypothalamus produces massive obesity in mammals and birds. Injury to the central nucleus of the amygala will also produce obesity. In contrast, damage to the lateral hypothalamus reduces body fat. The syndrome of leptin deficiency or defects in the leptin receptors produce a massive obesity that is metabolically similar to the VMH or PVN lesion syndromes of obesity, suggesting that leptin may have its metabolic effects through these medial hypothalamic centers. Support for this idea has come from studies showing that damage to the PVN or VMH will block the effects of leptin. A number of neuropeptides and monoamines are involved with modulating of food intake and fat stores. Both serotonin, acting through 5-HT2C receptors, and norepinephrine, acting through beta 2 and/or beta 3 receptors, reduce food intake. A variety of peptides also influence food intake and body fat. Neuropeptide Y, dynorphin, galanin, and melanocyte-stimulating hormone all increase food intake. In contrast, a large number of peptides--including cholecystokinin, corticotrophin-releasing hormone/urocortin, enterostatin, insulin, leptin, alpha-MSH, and TRH--reduce food intake. Chronic administration of neuropeptide Y, acting through Y-5 receptors, can produce chronically increased food intake and obesity. This syndrome is similar to the VMH syndrome and suggests that NPY must be acting as an inhibitor of a feeding system. The melanocortin receptor system may be particularly important because a mouse that does not express MC4 receptors is massively overweight. These central systems modulate food intake and fat stores by the controlled system. Glucocorticoids from the adrenal gland are important in obesity, since adrenalectomy will reverse or prevent the development of all forms of obesity. The sympathetic nervous system is also important because low sympathetic activity is associated with experimental and clinical obesity. The reciprocal relationship between food intake and sympathetic activity has been a robust relationship, suggesting that beta receptors in the periphery or brain may be involved in feeding control. In one model of dietary obesity resulting when animals eat a high-fat diet, the syndrome is blocked by inhibitory adrenal steroid activity. These animals show a lower level of sympathetic activity and a low level of brain serotonin. Finally, they show an enhanced sensitivity to essential fatty acids when these are applied to the tongue or given into the gut. In this chapter, the control of energy stores as fat is viewed as a feedback system. Leptin is perceived as a key afferent signal and glucocorticoids and the sympathetic nervous system through beta receptors as essential elements of this control system.
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PMID:The MONA LISA hypothesis in the time of leptin. 976 5

Melanocortinergic neurons are believed to play a role in the control of food intake. Melanocortin receptor agonists and antagonists modulate feeding in several mouse models of chemically and genetically induced hyperphagia. To date, little information is available describing the role of this neurological system in the control of the natural feeding cycle in genetically intact rats. To evaluate the involvement of melanocortins in spontaneous nocturnal feeding, the synthetic melanocortin receptor agonist, MTII and the antagonist, SHU9119 were administered ICV (third ventricle) alone and in combination. Dose-dependent inhibition or stimulation of food intake was observed with MTII or SHU9119, respectively. Co-injections containing equal concentrations of MTII and SHU9119 resulted in food intake that was indistinguishable from controls. Food intake patterns observed in studies in which various dose combinations of MTII and SHU9119 were co-injected are consistent with the concept that both affect feeding by acting on similar melanocortin receptors. The hypothesis that effects of melanocortins on feeding may be mediated via an NPY related pathway was tested by co-injecting MTII and NPY in a 2-h satiated food intake paradigm. MTII inhibited food intake induced by 5.0 microg hNPY in a dose dependent manner with the highest dose tested abolishing the NPY feeding response. The studies suggest that melanocortins act via specific receptors to control food intake in rats, possibly via an NPY related pathway. If similar neurochemical processes operate in humans, selectively modulating specific melanocortin receptor signaling may be an approach to the treatment of human obesity.
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PMID:Melanocortin mediated inhibition of feeding behavior in rats. 992 Apr 46


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