Brown fat thermogenesis and body weight regulation in mice: relevance to humans.

Physiological, pharmacological and genetic studies in dogs, mice and rats have established that the uncoupling protein-1 (UCP1)-based brown adipose tissue system has an important role in the regulation of body temperature. Although it may be possible to create laboratory conditions in which mice with inactivated Ucp1 can survive in a modestly cooled environment, data overwhelmingly support the conclusion that the UCP1/BAT system has evolved to maintain body temperature at 37 °C. The corollary to this conclusion is that any influence UCP1/BAT might have on body weight regulation is a secondary function. The idea that BAT prevents obesity by burning off excess energy to maintain energy balance seems incompatible with evolutionary biology. Premodern humans spent an enormous amount of energy either running to catch their meal or avoiding becoming a meal themselves; consequently, there was no obesity. Nevertheless, although secondary to body temperature regulation, UCP1/BAT is extraordinarily effective at reducing adiposity and insulin resistance in mice and rats. Variation among mice in susceptibility to diet-induced obesity is correlated with the induction of brown adipocytes in traditional white fat depots (wBAT). Both genetic and cell biology-based experimentation have shown that the cellular origins of wBAT are different from those of interscapular-like brown adipocytes (iBAT). Do they have different functions? We have analyzed the effects of the early nutritional environment on the induction of brown adipocytes in inguinal fat to test the hypothesis that wBAT is primarily involved in body weight regulation. Although undernutrition during lactation severely suppresses wBAT at 21 days of age, undernourished mice fed a normal chow diet ad libitum at weaning recovered their normal wBAT and iBAT systems as young adults. The function of wBAT does not seem to be uniquely devoted to body weight regulation.

UCP1: its involvement and utility in obesity.

Energy balance to prevent the development of obesity is dependent on energy expenditure. Although physical activity is the dominant mechanism for dissipating excess energy, a system of thermogenesis that evolved to protect the body from hypothermia is based upon the uncoupling of oxidative phosphorylation in brown adipocytes by the mitochondrial uncoupling protein (UCP1). It has been shown that upregulation of UCP1 by genetic manipulations or pharmacological agents can reduce obesity and improve insulin sensitivity. Recent evidence has shown the existence of two sources for brown adipocytes, one appearing as discrete brown fat depots during fetal development and the other appears during post-natal development as diffuse populations in traditional white fat depots. The latter can be induced by adrenergic stimulation depending on the genetic background of the animals and the nutritional environment. Understanding the biological and environmental factors controlling the expression of these two brown adipocyte populations promises to provide new strategies by which enhanced thermogenesis can be used to reduce obesity.International Journal of Obesity (2008) 32, S32-S38; doi:10.1038/ijo.2008.236.