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Science 29 May 1998:
Vol. 280. no. 5368, pp. 1369 - 1370
DOI: 10.1126/science.280.5368.1369
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News

CELL BIOLOGY:
Uncoupling Proteins Provide New Clue to Obesity's Causes

Trisha Gura

Just over a year ago, researchers identified what appear to be the first human "uncoupling proteins" (UCPs). Originally discovered in the brown fat cells of hibernating animals, UCPs dissociate the reactions that break down food from those that produce the body's chemical energy, thereby raising resting metabolic rate. Although people don't have brown fat, the new work shows that other human tissues, including ordinary fat and muscle, make proteins very similar to the animal UCPs. There's no proof yet that these human UCP relatives work the same way, but if they do, variations in production of activity of the proteins could help explain why some people have lower metabolic rates--and therefore a greater tendency to gain weight--than others. In addition, if drugs could be found that safely boost UCP activity, they could be used to treat obesity.

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THIS ARTICLE HAS BEEN CITED BY OTHER ARTICLES:
Food, Health and Psychology: Competing Recipes for Research and Understanding.
J. L. Smith (2004)
J Health Psychol 9, 483-496
   Abstract »    PDF »
Mitochondrial Uncoupling Protein 2 (UCP2) in the Nonhuman Primate Brain and Pituitary.
S. Diano, H. F. Urbanski, B. Horvath, I. Bechmann, A. Kagiya, G. Nemeth, F. Naftolin, C. H. Warden, and T. L. Horvath (2000)
Endocrinology 141, 4226-4238
   Abstract »    Full Text »    PDF »
Brain Uncoupling Protein 2: Uncoupled Neuronal Mitochondria Predict Thermal Synapses in Homeostatic Centers.
T. L. Horvath, C. H. Warden, M. Hajos, A. Lombardi, F. Goglia, and S. Diano (1999)
J. Neurosci. 19, 10417-10427
   Abstract »    Full Text »    PDF »
Meta-analysis of resting metabolic rate in formerly obese subjects.
A. Astrup, P. C Gotzsche, K. van de Werken, C. Ranneries, S. Toubro, A. Raben, and B. Buemann (1999)
Am. J. Clinical Nutrition 69, 1117-1122
   Abstract »    Full Text »    PDF »


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