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)

Uncoupling proteins are mitochondrial carrier proteins which are able to dissipate the proton gradient of the inner mitochondrial membrane. This uncoupling process reduces the amount of ATP generated through an oxidation of fuels. The hypothesis that uncoupling proteins (UCPs) are candidate genes for human obesity or Type II (non-insulin-dependent) diabetes mellitus is based on the finding that a chemical uncoupling of the mitochondrial membrane reduces body adiposity, and that lower metabolic rates predict weight gain. It is straightforward to hypothesize that common polymorphisms of UCP1, UCP2 and UCP3 genes lower metabolic rate by a more efficient energy coupling in the mitochondria. Furthermore, genetically engineered mice over expressing different UCP homologues are lean and resistant to diet-induced obesity. The three uncoupling protein homologue genes UCP1, UCP2, and UCP3 have been investigated for polymorphisms and mutations and their impact on Type II diabetes mellitus, obesity, and body weight gain or BMI. The main conclusion is that variation in the UCP1, UCP2 or UCP3 genes is not associated with major alterations of body weight gain. The contribution of UCP genes towards polygenic obesity and Type II diabetes is evaluated and discussed.
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PMID:Uncoupling proteins: functional characteristics and role in the pathogenesis of obesity and Type II diabetes. 1148 71

During the past few years, there have been two major developments, if not revolutions, in the field of energy balance and weight regulation. The first at the molecular level, which was catalysed by developments in DNA screening technology together with the mapping of the human genome, has been the tremendous advances made in the identification of molecules that play a role in the control of food intake and metabolic rate. The second, at the systemic level, which centered upon the use of modern technologies or more robust analytical techniques for assessing human energy expenditure in response to starvation and overfeeding, has been the publication of several papers providing strong evidence that adaptive thermogenesis plays a much more important role in the regulation of body weight and body composition than previously thought. Within these same few years, several new members of the mitochondrial carrier protein family have been identified in a variety of tissues and organs. All apparently possess uncoupling properties in genetically-modified systems, with two of them (uncoupling protein (UCP) 2 and UCP3) being expressed in adipose tissues and skeletal muscles, which are generally recognised as important sites for variations in thermogenesis and/or in substrate oxidation. Considered as breakthrough discoveries, the cloning of these genes has generated considerable optimism for rapid advances in our molecular understanding of adaptive thermogenesis, and for the identification of new targets for pharmacological management of obesity and cachexia. The present paper traces first, from a historical perspective, the landmark events in the field of thermogenesis that led to the identification of these genes encoding candidate UCP, and then addresses the controversies and on-going debate about their physiological importance in adaptive thermogenesis, in lipid oxidation or in oxidative stress. The general conclusion is that UCP2 and UCP3 may have distinct primary functions, with UCP3 implicated in regulating the flux of lipid substrates across the mitochondria and UCP2 in the control of mitochondrial generation of reactive oxygen species. The distinct functions of these two UCP1 homologues have been incorporated in a conceptual model to illustrate how UCP2 and UCP3 may act in concert in the overall regulation of lipid oxidation concomitant to the prevention of lipid-induced oxidative damage.
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PMID:Uncoupling proteins: their roles in adaptive thermogenesis and substrate metabolism reconsidered. 1150 24

Uncoupling proteins are located in the inner mitochondria membrane. Their name is derived from their function: they uncouple oxidative procesess of the respiratory chain from ATP synthesis. Hitherto several members of the family have been described, the best known being UCP1. UCP1 can be expressed exclusively in brown adipose tissue and it is responsible for the heat production. In humans the brown fat disappears during the early childhood. In adults another members of the UCP family can be found--UCP2 and UCP3. It is widely accepted that these proteins affect lipid metabolism and energy expenditure. They are intensively studied owing to their possible use in the therapy of obesity. However, their physiological function has not been yet fully established.
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PMID:[Uncoupling proteins]. 1150 48

Adaptive nonshivering thermogenesis may have profound effects on energy balance and is therefore therefore is a potential mechanism for counteracting the development of obesity. The molecular basis for adaptive nonshivering thermogenesis has remained a challenge that sparked acute interest with the identification of proteins (UCP2, UCP3, etc.) with high-sequence similarity to the original uncoupling protein-1 (UCP1), which is localized only in brown adipose tissue. Using UCP1-ablated mice, we examined whether any adaptive nonshivering thermogenesis could be recruited by acclimation to cold. Remarkably, by successive acclimation, the UCP1-ablated mice could be made to subsist for several weeks at 4C during which they had to constantly produce heat at four times their resting levels. Despite these extreme requirements for adaptive nonshivering thermogenesis, however, no substitution of shivering by any adaptive nonshivering thermogenic process occurred. Thus, although the existence of, for example, muscular mechanisms for adaptive nonshivering thermogenesis has recurrently been implied, we did not find any indication of such thermogenesis. Not even during prolonged and enhanced demand for extra heat production was any endogenous hormone or neurotransmitter able to recruit any UCP1-independent adaptive nonshivering thermogenic process in muscle or in any other organ, and no proteins other than UCP1-not even UCP2 or UCP3-therefore have the ability to mediate adaptive nonshivering thermogenesis in the cold.
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PMID:Only UCP1 can mediate adaptive nonshivering thermogenesis in the cold. 1151 9

Docosahexaenoic acid [DHA, 22:6(n-3)] prevents cardiovascular disease by decreasing obesity. It also prevents cancer and other geriatric diseases. We studied the chronic pleiotropic effects of DHA on transcription including that of mRNAs for uncoupling proteins (UCP). Male and female mice (9 mo old) were fed high (n-6) or high (n-3) fatty acid diets for 4 mo. Compared with controls fed high (n-6) fatty acid diets [high (n-6) group], the livers of male and female mice fed DHA [high (n-3) group] contained six- (P < 0.001) and fivefold (P < 0.001) more DHA, respectively. The high (n-3) group had less white adipose tissue [35.3% in males (P < 0.001) and 27.3% in females (P < 0.001)]. The high (n-3) group expressed more uncoupling protein 3 (UCP3) in the gastrocnemius, 108% higher (P < 0.001) and 104% higher (P < 0.001) in males and females, respectively, than those in the high (n-6) group. However, the prevention of many diseases by DHA is not explained by UCP3. Thus, the gene expression profiles of both high (n-3) and high (n-6) groups were analyzed in skeletal muscle using cDNA expression array. Of 588 genes surveyed in the array, the high (n-3) group showed 12 genes (2%) including those for glucose regulators (e.g., CD38) and tumor suppressors (e.g., CTCF) that were expressed 100-340% more than those of the high (n-6) group. Furthermore, 28 genes (4.8%), including growth factors (e.g., ErbB-2 receptor) and immune regulators (e.g., interleukin-1 beta precursor) were expressed 50-90% less in the high (n-3) group than in the high (n-6) group. These results explain in part the important pleiotropic effects of DHA, which are independent of obesity control by UCP3 suppression.
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PMID:Chronic docosahexaenoic acid intake enhances expression of the gene for uncoupling protein 3 and affects pleiotropic mRNA levels in skeletal muscle of aged C57BL/6NJcl mice. 1158 83

The physiological function of uncoupling protein 3 (UCP3) is as yet unknown. Based on its 57% homology to UCP1 whose physiologic function is uncoupling and thermogenesis, UCP3 was attributed with the function of mitochondrial uncoupling through proton-leak reactions. UCP3 is expressed selectively in muscle, a tissue in which it has been estimated that proton leak accounts for approx. 50% of resting energy metabolism. Genetic linkage, association and variant studies suggest a role for UCP3 in obesity and/or diabetes. Studies of the heterologous expression of UCP3 in yeast provide support for the idea that UCP3 can uncouple mitochondrial oxidative phosphorylation, but the physiological relevance of these results is questionable. In vitro studies of mitochondria from Ucp3(-/-) mice provide support, but there are no changes in resting metabolic rate (RMR) of mice. In vivo studies demonstrate increased ATP synthesis, but estimates of substrate oxidation rate indicate no change. Mice that greatly overexpress Ucp3 in muscle have increased RMR. Inconsistent with the function of uncoupling are the observations that fasting results in increased expression of UCP3, but no change in muscle proton leak. Moreover, fasting decreases energy expenditure in muscle. Expression patterns for Ucp3 and lipid-metabolism genes support a physiological role in fatty acid oxidation. Overall, findings support a role for Ucp3 in fatty acid metabolism that may have implications for obesity and/or Type II diabetes.
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PMID:UCP3 and its putative function: consistencies and controversies. 1170 72

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

The uncoupling protein 3 (UCP3) is a mitochondrial membrane transporter mainly expressed in skeletal muscle that we have shown to be associated with obesity. We have analyzed UCP3 polymorphisms, Val102Ile, Tyr210Tyr, and a new microsatellite GAIVS6 located in the sixth intron, among 276 black and 503 white subjects from the HERITAGE Family Study. Linkage and association studies were undertaken with body composition variables measured in a sedentary state (baseline) and after 20 wk of endurance training (changes). Allele and genotype frequencies were found to be significantly different between whites and blacks. Suggestive linkages (0.009 < or = P < or = 0.033) with Tyr210Tyr were found in blacks and whites for baseline body mass index, fat mass, or leptin level and with GAIVS6 in whites for changes in fat mass and percent body fat. Associations were also found in whites between GAIVS6 and changes in the sum of eight skinfold thicknesses (P = 0.0006), with a borderline result for body mass index (P = 0.06). We concluded that UCP3 could be involved in body composition changes after regular exercise.
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PMID:Uncoupling protein 3 gene is associated with body composition changes with training in HERITAGE study. 1184 47

Uncoupling proteins are mitochondrial carrier proteins that catalyse a regulated proton leak across the inner mitochondrial membrane, diverting free energy from ATP synthesis by the mitochondrial F0F1-ATP synthase to the production of heat. Uncoupling protein 1 (UCP1), which is exclusively expressed in brown adipose tissue, is the mediator of thermogenesis in response to beta-adrenergic stimulation. Using gene a knockout mouse model, UCP1 has been shown to be required for cold acclimation. Two homologues of UCP1, UCP2 and UCP3, have been identified recently and show a much wider tissue distribution. UCP2 and UCP3 have been postulated to play a role in the regulation of cold acclimation, energy expenditure and diet-induced thermogenesis in humans, who, in contrast to rodents, have very little brown fat in adult life. However, evidence is accumulating that thermogenesis and regulation of body weight may not be the physiological functions of UCP2 and UCP3. For instance, mice deficient for UCP2 or UCP3 are not cold-intolerant and do not develop obesity. Alternative functions were suggested, primarily based on findings in UCP2 and UCP3 gene knockout mice. Both UCP2- and UCP3-deficient mice were found to overproduce reactive oxygen species and UCP2-deficient mice to hypersecrete insulin. Thus, the UCP1 homologues may play a role in regulating mitochondrial production of reactive oxygen species and b-cell function. In this review, we discuss the role of UCP1, UCP2 and UCP3 in human physiology and disease, primarily based on findings from the various animal models that have been generated.
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PMID:Mitochondrial uncoupling proteins in human physiology and disease. 1185 Jun 13

The uncoupling protein 1 homologue, uncoupling protein 3, is able to uncouple adenosine triphosphate production from mitochondrial respiration, thereby dissipating energy as heat and affecting the efficiency of energy metabolism. Uncoupling protein 3 is expressed predominantly in skeletal muscle, and has been associated with whole-body energy metabolism. However, on the basis of present evidence it has been concluded that the primary function of uncoupling protein 3 is not in the regulation of energy expenditure. For example, fasting, an energy expenditure attenuating condition, upregulates uncoupling protein 3 expression, and uncoupling protein 3 knockout mice have a normal metabolic rate. The exact function of uncoupling protein 3 remains to be elucidated, but at present putative roles for uncoupling protein 3 include involvement in the regulation of the production of reactive oxygen species, mitochondrial fatty acid transport and the regulation of glucose metabolism in skeletal muscle. Because all these putative functions assume that uncoupling protein 3 affects mitochondrial coupling, a secondary effect of the function of uncoupling protein 3 might still be that it influences (but not regulates) energy metabolism, consistent with observations in linkage and association studies. Therefore, uncoupling protein 3 remains an interesting target for pharmacological upregulation in the treatment of obesity and diabetes.
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PMID:Skeletal muscle uncoupling protein 3 (UCP3): mitochondrial uncoupling protein in search of a function. 1195 51

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