UMLS:C0028754 - FACTA Search

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

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

Neuropeptide Y (NPY), a 36 amino acid neuromodulator that is secreted by neurons throughout the peripheral and central nervous system, has been implicated in the control of many physiological processes. We have begun to examine its role in regulation of appetite, behavior, and excitotoxicity by examining mice that are unable to produce NPY as a consequence of gene inactivation. These mutant mice are remarkably normal when reared under standard vivarium conditions. Despite considerable evidence that NPY plays a central role in stimulating appetite, NPY-deficient mice eat normally, grow normally, and refeed after a fast normally. Furthermore, all of their endocrine responses to fasting are normal. The response of NPY-null mice to diet-induced obesity, chemically induced obesity (monosodium glutamate and gold thioglucose), and genetic-based obesity (lethal yellow agouti, Ay; uncoupling protein-diphtheria toxin transgenics, UCP-DT) were all normal. However, NPY deficiency does partially ameliorate the obesity and all of the adverse endocrine effects of leptin deficiency in ob/ob mice. NPY-null mice as well as mice deficient in both NPY and leptin are more sensitive to leptin, suggesting that NPY may normally have a tonic inhibitory action on leptin-mediated satiety signals. NPY-null mice display the normal voracious feeding response to injected NPY. Thus, the only condition where we have observed a role for NPY in body-weight regulation is in the context of complete leptin deficiency--where absence of NPY is beneficial. The activity and general behavior of NPY-null mice are normal. They appear to have normal spatial and contextual learning ability; however, they manifest more anxiety under some conditions. NPY-null mice occasionally display spontaneous, seizure-like events. They also are less able to terminate seizures induced by GABA receptor antagonists or glutamate receptor agonists. These observations are consistent with previous data suggesting that NPY plays an important role in dampening excitotoxicity.
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PMID:Life without neuropeptide Y. 976 8

The mahogany (mg) locus originally was identified as a recessive suppressor of agouti, a locus encoding a skin peptide that modifies coat color by antagonizing the melanocyte-stimulating hormone receptor or MC1-R. Certain dominant alleles of agouti cause an obesity syndrome when ectopic expression of the peptide aberrantly antagonizes the MC4-R, a related melanocyte-stimulating hormone receptor expressed in hypothalamic circuitry and involved in the regulation of feeding behavior and metabolism. Recent work has demonstrated that mg, when homozygous, blocks not only the ability of agouti to induce a yellow coat color when expressed in the skin of the lethal yellow mouse (AY), but also the obesity resulting from ectopic expression of agouti in the brain. Detailed analysis of mg/mg AY/a animals, presented here, demonstrates that mg/mg blocks the obesity, hyperinsulinemia, and increased linear growth induced by ectopic expression of the agouti peptide. Remarkably, however, mg/mg did not reduce hyperphagia in the AY/a mouse. Furthermore, mg/mg induced hyperphagia and an increase in basal metabolic rate in the C57BL/6J mouse in the absence of AY. Consequently, although mahogany is broadly required for agouti peptide action, it also appears to be involved in the control of metabolic rate and feeding behavior independent of its suppression of agouti.
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PMID:Mahogany (mg) stimulates feeding and increases basal metabolic rate independent of its suppression of agouti. 977 May 50

Genetic obesity is associated with increased neuropeptide Y (NPY) messenger RNA (mRNA) and decreased POMC mRNA in the hypothalamus of ob/ob and db/db mice, or impaired sensitivity to alphaMSH (derived from POMC) in the yellow agouti mouse. Acquired obesity can be produced by chemically lesioning the hypothalamus with either monosodium glutamate (MSG) in neonates or gold thioglucose (GTG) in adult mice. The present study examined whether elevated NPY mRNA and/or decreased POMC mRNA in the hypothalamus are associated with obesity due to hypothalamic lesions. GTG injection into adult mice produced a profound obese phenotype, including hyperphagia, increased body weight, and increased leptin mRNA and peptide, in association with reduced hypothalamic NPY mRNA and POMC mRNA. MSG treatment produced virtual elimination of NPY mRNA in the arcuate nucleus and a reduction of hypothalamic POMC mRNA, and led to elevated leptin. MSG pretreatment did not attenuate GTG-induced hyperphagia and obese phenotype. These results do not support a role for NPY-synthesizing neurons in the arcuate nucleus in mediating hypothalamic acquired obesity, but are consistent with the hypothesis that decreased activity of hypothalamic neurons synthesizing POMC play a role in mediating hypothalamic obesity.
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PMID:Hyperphagia and weight gain after gold-thioglucose: relation to hypothalamic neuropeptide Y and proopiomelanocortin. 979 56

The agouti-related protein gene (Agrp) is a novel gene implicated in the control of feeding behavior. The hypothalamic expression of Agrp is regulated by leptin, and overexpression of Agrp in transgenic animals results in obesity and diabetes. By analogy with the known actions of agouti, these data suggest a role for the Agrp gene product in the regulation of melanocortin receptors expressed in the central nervous system. The availability of recombinant, highly purified protein is required to fully address this potential interaction. A nearly full-length form of AGRP (MKd5-AGRP) was expressed in the cytosolic or soluble fraction of Escherichia coli and appeared as large intermolecular disulfide-bonded aggregates. Following oxidation, refolding, and purification, this protein was soluble, and eluted as a single symmetric peak on RP-HPLC. Circular dichroism studies indicated that the purified protein contains primarily random coil and beta-sheet secondary structure. Sedimentation velocity studies at neutral pH demonstrated that MKd5-AGRP is monomeric at low micromolar concentrations. Mobility shifts observed using SDS-PAGE under reducing and nonreducing conditions for bacterially expressed and mammalian expressed AGRP were identical, an indication of a similar disulfide structure. The purification to homogeneity of a second, truncated form of AGRP (Md65-AGRP) which was expressed in the insoluble or inclusion body fraction is also described. Both forms act as competitive antagonists of alpha-melanocyte stimulating hormone (alpha-MSH) at melanocortin-3 (MC-3) and melanocortin-4 receptors (MC-4). The demonstration that AGRP is an endogenous antagonist with respect to these receptors is a unique mechanism within the central nervous system, and has important implications in the control of feeding.
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PMID:Biochemical, biophysical, and pharmacological characterization of bacterially expressed human agouti-related protein. 981 97

Regulation of intracellular Ca2+ ([Ca2+]i) plays a key role in obesity, insulin resistance and hypertension, and [Ca2+]i disorders may represent a fundamental factor linking these three conditions. We have shown insulin to be a direct vasodilator, attenuating voltage-gated Ca2+ influx and stimulating Ca(2+)-ATPase transcription via a glucose-6-phosphate response element. These result in a net decrease in [Ca2+]i and thereby decrease vascular resistance, while these effects are blunted in insulin resistance, leading to increased vascular resistance. Consistent with this concept, pharmacological amplification of peripheral insulin sensitivity results in reduced arterial pressure. While insulin regulates [Ca2+]i, Ca2+ also regulates insulin signaling, as increasing [Ca2+]i impairs insulin signaling in some systems, possibly due to Ca2+ inhibition of insulin-regulated dephosphorylation. Finally, in recent studies of the mouse agouti gene, we have also demonstrated increased [Ca2+]i to play a key role in adipocyte lipogenesis, as follows. We have found dominant agouti mutants to exhibit increased [Ca2+]i in most tissues, leading to increased vascular reactivity and insulin resistance in vascular smooth muscle and skeletal muscle cells, respectively. Further, we have found recombinant agouti protein to directly increase [Ca2+]i in a variety of cells, including murine and human adipocytes, and to stimulate both the expression and activity of adipocyte fatty acid synthase and increase triglyceride accumulation in a Ca(2+)-dependent manner. These effects can be mimicked by stimulation of Ca2+ influx and blocked by Ca2+ channel inhibition, while treatment of mice with a Ca2+ antagonist attenuates agouti-induced obesity. Since humans express agouti in adipose tissue, it may similarly exert paracrine effects on [Ca2+]i and thereby stimulate de novo lipogenesis and promote obesity. Thus, Ca2+ signaling represents a target for therapeutic intervention in obesity as well as hypertension and insulin resistance.
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PMID:Nutritional and endocrine modulation of intracellular calcium: implications in obesity, insulin resistance and hypertension. 982 18

It has been reported that intraventricular administration of the melanocortin 4 receptor (MC4-R) agonist MT II and antagonist SHU9119 alter food intake. We found that MT II and SHU9119 have extremely potent effects on feeding when injected in the paraventricular nucleus (PVN), a site where MC4-R gene expression is very high. Our finding provides direct evidence that MC4-R signaling is important in mediating food intake and that melanocortin neurons in the PVN exert a tonic inhibition of feeding behavior. Chronic disruption of this inhibitory signal is a possible explanation of the agouti-obesity syndrome.
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PMID:Feeding effects of hypothalamic injection of melanocortin 4 receptor ligands. 985 24

Mutations reducing the functional activity of leptin, the leptin receptor, alpha-melanocyte stimulating hormones (alpha-MSH) and the melanocortin-4 receptor (Mc4r) all lead to obesity in mammals. Moreover, mutant mice that ectopically express either agouti (Ay/a mice) or agouti-related protein (Agrp), antagonists of melanocortin signalling, become obese. These data suggest that alpha-MSH signalling transduced by Mc4r tonically inhibits feeding; however, it is not known to what extent this pathway mediates leptin signalling. We show here that Mc4r-deficient (Mc4r-/-) mice do not respond to the anorectic actions of MTII, an MSH-like agonist, suggesting that alpha-MSH inhibits feeding primarily by activating Mc4r. Obese Mc4r-/-mice do not respond significantly to the inhibitory effects of leptin on feeding, whereas non-obese Mc4r-/- mice do. These data demonstrate that melanocortin signalling transduced by Mc4r is not an exclusive target of leptin action and that factors resulting from obesity contribute to leptin resistance. Leptin resistance of obese Mc4r-/- mice does not prevent their response to the anorectic actions of ciliary neurotrophic factor (CNTF), corticotropin releasing factor (CRF), or urocortin; or the orexigenic actions of neuropeptide Y (NPY) or peptide YY (PYY), indicating that these neuromodulators act independently or downstream of Mc4r signalling.
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PMID:Response of melanocortin-4 receptor-deficient mice to anorectic and orexigenic peptides. 991 4

Agouti-related protein (AGRP) is a homologue of the agouti gene product and, when overexpressed, promotes obesity. Like neuropeptide Y (NPY) messenger RNA (mRNA), AGRP mRNA is produced in the hypothalamic arcuate nucleus and is elevated in leptin-deficient ob/ob and leptin-resistant db/db mice. These data suggest that AGRP mRNA might be affected by leptin and nutritional status in parallel with NPY mRNA. To test this hypothesis, we examined if AGRP mRNA would be, like NPY mRNA, inhibited by leptin injections and stimulated by fasting. AGRP mRNA was elevated in ob/ob mice about 5-fold compared with wild-type controls and was significantly inhibited by leptin treatment, as assessed by Northern blot analysis. In wild-type mice, AGRP mRNA was increased at least 13-fold by a 2-day fast, as assessed both by Northern blot analysis and in situ hybridization. In ad lib fed db/db mice, AGRP mRNA was elevated about 8-fold compared with ad lib fed wild-type controls, and was further increased by fasting in db/db mice. These data suggest that AGRP mRNA and NPY mRNA respond similarly to leptin and fasting.
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PMID:Hypothalamic agouti-related protein messenger ribonucleic acid is inhibited by leptin and stimulated by fasting. 992 10

Genetic studies have shown that mutations within the mahogany locus suppress the pleiotropic phenotypes, including obesity, of the agouti-lethal-yellow mutant. Here we identify the mahogany gene and its product; this study, to our knowledge, represents the first positional cloning of a suppressor gene in the mouse. Expression of the mahogany gene is broad; however, in situ hybridization analysis emphasizes the importance of its expression in the ventromedial hypothalamic nucleus, a region that is intimately involved in the regulation of body weight and feeding. We present new genetic studies that indicate that the mahogany locus does not suppress the obese phenotype of the melanocortin-4-receptor null allele or those of the monogenic obese models (Lep(db), tub and Cpe(fat)). However, mahogany can suppress diet-induced obesity, the mechanism of which is likely to have implications for therapeutic intervention in common human obesity. The amino-acid sequence of the mahogany protein suggests that it is a large, single-transmembrane-domain receptor-like molecule, with a short cytoplasmic tail containing a site that is conserved between Caenorhabditis elegans and mammals. We propose two potential, alternative modes of action for mahogany: one draws parallels with the mechanism of action of low-affinity proteoglycan receptors such as fibroblast growth factor and transforming growth factor-beta, and the other suggests that mahogany itself is a signalling receptor.
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PMID:The mahogany protein is a receptor involved in suppression of obesity. 1008 55

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