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 coupling of oxygen consumption to ADP phosphorylation is incomplete, as is particularly evident in brown adipocyte mitochondria which use a regulated uncoupling mechanism to dissipate heat produced by substrate oxidation. In brown adipose tissue, uncoupling is effected by a specific protein in the inner mitochondrial membrane referred to as uncoupling protein-1 (UCP1). UCP1 gene disruption in mice has confirmed UCP1's role in cold-induced thermogenesis. Genetic analysis of human cohorts has suggested that UCP1 plays a minor role in the control of fat content and body weight. The recent cloning of UCP2 and UCP3, two homologues of UCP1, has boosted research on the importance of respiration control in metabolic processes, metabolic diseases and energy balance. UCP2 is widely expressed in different organs whereas UCP3 is mainly present in skeletal muscle. The chromosomal localization of UCP2 as well as UCP2 mRNA induction by a lipid-rich diet in obesity-resistant mice suggested that UCP2 is involved in diet-induced thermogenesis. A strong linkage between markers in the vicinity of human UCP2 and UCP3 (which are adjacent genes) and resting metabolic rate was calculated. UCPs are known or supposed to participate in basal and regulatory thermogenesis, but their exact biochemical and physiological functions have yet to be elucidated. UCPs may constitute novel targets in the development of drugs designed to modulate substrate oxidation. However, very recent data suggest an important role for the UCPs in the control of production of free radicals by mitochondria, and in response to oxidants.
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PMID:Mitochondrial uncoupling proteins: from mitochondria to the regulation of energy balance. 1108 Feb 46

Exposure of rat pancreatic islets to 20 mM leucine for 24 h reduced insulin release in response to glucose (16.7 and 22.2 mM). Insulin release was normal when the same islets were stimulated with leucine (40 mM) or glyburide (1 microM). To investigate the mechanisms responsible for the different effect of these secretagogues, we studied several steps of glucose-induced insulin secretion. Glucose utilization and oxidation rates in leucine-precultured islets were similar to those of control islets. Also, the ATP-sensitive K(+) channel-independent pathway of glucose-stimulated insulin release, studied in the presence of 30 mM K(+) and 250 microM diazoxide, was normal. In contrast, the ATP-to-ADP ratio after stimulation with 22.2 mM glucose was reduced in leucine-exposed islets with respect to control islets. The decrease of the ATP-to-ADP ratio was due to an increase of ADP levels. In conclusion, prolonged exposure of pancreatic islets to high leucine levels selectively impairs glucose-induced insulin release. This secretory abnormality is associated with (and might be due to) a reduced ATP-to-ADP ratio. The abnormal plasma amino acid levels often present in obesity and diabetes may, therefore, affect pancreatic islet insulin secretion in these patients.
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PMID:Chronic exposure to high leucine impairs glucose-induced insulin release by lowering the ATP-to-ADP ratio. 1159 66

Metabolism of white adipose tissue is involved in the control of body fat content. In vitro experiments indicated a dependence of lipogenesis on mitochondrial ATP production, as well as a reciprocal link between hormonal effects on metabolism and energetics of adipocytes. Therefore, mitochondrial uncoupling in adipocytes that results in stimulation of energy dissipation and depression of ATP synthesis may contribute to control of lipid metabolism and adiposity. This is supported by the expression of protonophoric proteins in adipocytes, e.g. uncoupling proteins (UCPs) 2 and 5, and some anion transporters, and induction of UCP1 and UCP3 in white fat by pharmacological treatments that reduce adiposity. Negative correlation between expression of UCPs in adipocytes and accumulation of white fat was also found. Expression of UCP1 from the adipose-specific promoter in aP2-Ucp1 transgenic mice mitigated obesity induced by genetic or dietary factors. The obesity resistance, accompanied by mitochondrial uncoupling in adipocytes and increased energy expenditure, resulted from ectopic expression of UCP1 in white but not in brown fat. Probably due to depression of ATP/ADP ratio in white fat of transgenic mice, both fatty acid synthesis and lipolytic action of noradrenaline in adipocytes were relatively low. These results support the role of protonophoric proteins in adipocytes in the control of adiposity. The main function of these proteins in white fat may be modulation of lipogenesis and intracellular hormone signalling. Augmentation of energy expenditure may be of relatively small importance, in accordance with the low oxidative capacity of white adipocytes.
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PMID:Mitochondrial uncoupling and lipid metabolism in adipocytes. 1170 76

It is becoming evident that insulin resistance of white adipose tissue is a major factor underlying the cardiovascular risk of obesity. Impaired fat storage rather than altered glucose metabolism in adipocytes probably contributes to development of insulin resistance in muscle and other tissues, in particular via increased delivery of nonesterified fatty acids into circulation. Lipid metabolism of adipose tissue is affected by the energy status of fat cells. In vitro experiments indicated the dependence of both lipogenesis and lipolysis on ATP levels in adipocytes. Thus, respiratory uncoupling in adipocytes that results in stimulation of energy dissipation and depression of ATP synthesis may contribute to the control of lipid metabolism, adiposity, and insulin sensitivity. This notion is supported by the expression of UCPs in adipocytes, for example, UCP2, UCP5, as well as some protonophoric anion transporters, and by induction of UCP1 and UCP3 in white fat by pharmacological treatments that reduce adiposity. A negative correlation between expression of UCPs in adipocytes and accumulation of white fat was also found. Expression of UCP1 from the adipose-specific promoter in the aP2-Ucp1 transgenic mice mitigated obesity induced by genetic or dietary factors. The obesity resistance, accompanied by respiratory uncoupling in adipocytes and increased energy expenditure, resulted from ectopic expression of UCP1 in white, but not brown fat. Probably due to depression of the ATP/ADP ratio, both fatty acid synthesis and lipolytic action of norepinephrine in adipocytes of transgenic mice were relatively low. Expression of regulatory G-proteins, which are essential for both catecholamine and insulin signaling in adipocytes, was also altered by ectopic UCP1. These results support the role of protonophoric proteins in adipocytes in the control of adiposity and insulin sensitivity. Antidiabetic effects of thiazolidinediones, fibrates, beta(3)-adrenoreceptor agonists, dietary n-3 PUFAs, and leptin may be explained at least partially by their effects on the energy and hence also the lipid metabolism of fat cells.
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PMID:Modulation of lipid metabolism by energy status of adipocytes: implications for insulin sensitivity. 1207 39

Specialized neurons utilize glucose as a signaling molecule to alter their firing rate. Glucose-excited (GE) neurons increase and glucose-inhibited (GI) neurons reduce activity as ambient glucose levels rise. Glucose-induced changes in the ATP-to-ADP ratio in GE neurons modulate the activity of the ATP-sensitive K(+) channel, which determines the rate of cell firing. The GI glucosensing mechanism is unknown. We postulated that glucokinase (GK), a high-Michaelis constant (K(m)) hexokinase expressed in brain areas containing populations of GE and GI neurons, is the controlling step in glucosensing. Double-label in situ hybridization demonstrated neuron-specific GK mRNA expression in locus ceruleus norepinephrine and in hypothalamic neuropeptide Y, pro-opiomelanocortin, and gamma-aminobutyric acid neurons, but it did not demonstrate this expression in orexin neurons. GK mRNA was also found in the area postrema/nucleus tractus solitarius region by RT-PCR. Intracarotid glucose infusions stimulated c-fos expression in the same areas that expressed GK. At 2.5 mmol/l glucose, fura-2 Ca(2+) imaging of dissociated ventromedial hypothalamic nucleus neurons demonstrated GE neurons whose intracellular Ca(2+) oscillations were inhibited and GI neurons whose Ca(2+) oscillations were stimulated by four selective GK inhibitors. Finally, GK expression was increased in rats with impaired central glucosensing (posthypoglycemia and diet-induced obesity) but was unaffected by a 48-h fast. These data suggest a critical role for GK as a regulator of glucosensing in both GE and GI neurons in the brain.
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PMID:Glucokinase is the likely mediator of glucosensing in both glucose-excited and glucose-inhibited central neurons. 1208 33

The uncoupling protein-1 (UCP1) homologues UCP2 and UCP3 are able to uncouple ATP production from mitochondrial respiration, thereby dissipating energy as heat and affecting energy metabolism efficiency. In contrast to UCP1, which plays an important role in adaptive thermogenesis, UCP2 and UCP3 do not have a primary role in the regulation of energy metabolism. UCP2, which is expressed in a wide variety of tissues, including white adipose tissue, skeletal muscle and tissues of the immune system, has been suggested to affect the production of reactive oxygen species. UCP2 has also been suggested to regulate the [ATP]/[ADP] ratio and was recently shown to influence insulin secretion in the beta-cells of the pancreas. UCP3, in contrast, is expressed predominantly in skeletal muscle and has been associated with whole-body energy metabolism. However, the primary function of UCP3 is not the regulation of energy metabolism. For example, fasting, a condition attenuating energy expenditure, upregulates UCP3 expression. Moreover, UCP3-knockout mice have a normal metabolic rate. The exact function of UCP3 therefore remains to be elucidated, but putative roles for UCP3 include involvement in the regulation of ROS, in mitochondrial fatty acid transport and in the regulation of glucose metabolism in skeletal muscle. Whatever the primary function of these novel uncoupling proteins, a secondary effect via uncoupling might allow them to influence (but not to regulate) energy metabolism, which would be consistent with the observations from linkage and association studies. Therefore, UCP2 and UCP3 remain interesting targets for pharmacological upregulation in the treatment of obesity and diabetes.
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PMID:UCP2 and UCP3 in muscle controlling body metabolism. 1211 Jun 61

Uncoupling proteins(UCP) are carrier proteins in mitochondria. In eukaryotic cells, ATP is generated by oxidative phosphorylation, an energetic coupling at mitochondria level. The oxidative reactions occurring in the respiratory chain generate an electrochemical proton gradient at both sides of the inner membrane of mitochondria. This gradient is used by the ATP synthase to phosphorylate ADP into ATP. The coupling of cell respiration with ADP phosphorylation is only partial in brown adipose tissue (BAT) mitochondria, where UCP causes a reentry of protons into the matrix and abolishes the electrochemical proton gradient. The liberated energy is then dissipated as heat and the synthesis of ATP is reduced. Recently, the cloning of new UCPs expressed in other tissues revealed the importance of this kind of regulation of respiratory control in metabolism and energy expenditure. The newly characterized UCPs are potential target drugs for obesity treatment, which could be favor of energy expenditure and diminish the metabolic efficiency.
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PMID:[Characters of uncoupling protein and its relation with obesity]. 1256 30

K cells are a subpopulation of enteroendocrine cells that secrete glucose-dependent insulinotropic polypeptide (GIP), a hormone that promotes glucose homeostasis and obesity. Therefore, it is important to understand how GIP secretion is regulated. GIP-producing (GIP/Ins) cell lines secreted hormones in response to many GIP secretagogues except glucose. In contrast, glyceraldehyde and methyl pyruvate stimulated hormone release. Measurements of intracellular glucose 6-phosphate, fructose 1,6-bisphosphate, and pyruvate levels, as well as glycolytic flux, in glucose-stimulated GIP/Ins cells indicated that glycolysis was not impaired. Analogous results were obtained using glucose-responsive MIN6 insulinoma cells. Citrate levels increased similarly in glucose-treated MIN6 and GIP/Ins cells. Thus pyruvate entered the tricarboxylic acid cycle. Glucose and methyl pyruvate stimulated 1.4- and 1.6-fold increases, respectively, in the ATP-to-ADP ratio in GIP/Ins cells. Glyceraldehyde profoundly reduced, rather than increased, ATP/ADP. Thus nutrient-regulated secretion is independent of the ATP-dependent potassium (K(ATP)) channel. Antibody staining of mouse intestine demonstrated that enteroendocrine cells producing GIP, glucagon-like peptide-1, CCK, or somatostatin do not express detectable levels of inwardly rectifying potassium (Kir) 6.1 or Kir 6.2, indicating that release of these hormones in vivo may also be K(ATP) channel independent. Conversely, nearly all cells expressing chromogranin A or substance P and approximately 50% of the cells expressing secretin or serotonin exhibited Kir 6.2 staining. Compounds that activate calcium mobilization were potent secretagogues for GIP/Ins cells. Secretion was only partially inhibited by verapamil, suggesting that calcium mobilization from intracellular and extracellular sources, independent from K(ATP) channels, regulates secretion from some, but not all, subpopulations of enteroendocrine cells.
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PMID:Studies with GIP/Ins cells indicate secretion by gut K cells is KATP channel independent. 1267 50

Energy exists as organic molecules and heat in living organisms. In adult mammals, body weight and fat content remain unchanged if energy intake is strictly equivalent to energy expenditure. In other words, regulation of body weight requires energy of foods to be entirely dissipated as heat. Imbalance between ingested energy and thermogenesis induces obesity or thinness. Alterations of food intake or energy expenditure represent the two causes of body weight disturbance. It is accepted that individuals differ in food efficiency i.e. ability to metabolize foods and store fat or totally burn nutrients. Mechanisms of food efficiency and futile cycles are presented. I started my research work analysing thermogenic mechanism in brown adipose tissue. Actually, in addition to white adipose tissue which is the major type of adipose tissue, mammals own another type of adipose tissue referred to as brown adipose tissue. This later tissue is an activatable thermogenic organ which oxidizes fatty acids and releases heat in blood stream. Brown fat is activated during exposure to the cold (in rodents), at birth, and during arousal in hibernators. My initial work helped to characterize a mitochondrial protein named uncoupling protein or UCP which is responsible for activation of fatty acid oxidation and heat production in brown adipocytes. Actually, in most cells, fifty per cent of oxidation energy is recovered as ATP in mitochondria through the process of coupling of respiration to ADP phosphorylation. In contrast to mitochondria of most tissues, brown adipocyte mitochondria can escape the obligatorily coupling of respiration and waste almost ninety per cent of respiration energy as thermogenesis. UCP characterization and its molecular cloning as well as antibodies obtention were used to better understand cellular thermogenesis. Brown adipocytes were identified in babies and adult patients with pheochromocytoma. More recently, research on the brown fat UCP helped us to identify UCP2, a UCP homolog present in most human and animal tissues. A family of UCPs exist in animals and plants. These UCPs may function as mitochondrial uncouplers. However, the ancient function of the UCPs may be rather associated to adaptation to oxygen and control of free radicals than to thermogenesis. Further studies of UCPs will improve the knowledge of mitochondrial metabolism and substrate oxidation. In other respects, analysis of molecular mechanisms controlling respiration uncoupling may contribute to new strategies of treatment of metabolic disorders such as obesity.
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PMID:[To burn or to store]. 1273 25

The antiatherogenic effect of a herbal formulation, Caps HT2, was evaluated as antioxidant, anticoagulant, platelet antiaggregatory, lipoprotein lipase releasing, anti-inflammatory and hypolipidaemic activity in rats. The formulation contained the methanolic extracts of selected parts of plants, Commiphora mukul, Allium sativum, Plumbago indica, Semecarpus anacardium, Hemidesmus indicus, Terminalia arjuna, Tinospora cordifolia, Withania somnifera and Ocimum sanctum. The formulation, Caps HT2 was found to scavenge superoxide and hydroxyl radicals; the IC50 required being 55.0 and 610.0 microg/ml respectively. The lipid peroxidation was found inhibited (50%) by 48.5 microg/ml of Caps HT2. The intravenous administration of the formulation (5 mg/kg) delayed the plasma recalcification time in rabbits and enhanced the release of lipoprotein lipase enzyme significantly (p < 0.001). The formulation also inhibited ADP induced platelet aggregation in vitro, which was comparable to commercial heparin. The anti-inflammatory action of the formulation was significant (p < 0.001) with acute and chronic inflammations induced by carrageenan and formalin respectively in rats. The hypolipidaemic effect of Caps HT2 was significant (p < 0.001) with the administration of the formulation, in diet-induced hyperlipidaemia of rats for a period of 30 days. Oral administration of the formulation, Caps HT2 (100, 200, 300 and 400 mg/kg) significantly raised HDL cholesterol levels. The atherogenic index and the reduction in body weight were significant indicating the effectiveness against hyperlipidaemia and obesity. All these results revealed the therapeutic potential of Caps HT2 against vascular intimal damage and atherogenesis leading to various types of cardiovascular problems.
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PMID:Antiatherogenic effect of Caps HT2, a herbal Ayurvedic medicine formulation. 1367 30

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