Thermogenic Mechanisms and Their Hormonal Regulation

doi:10.1152/physrev.00009.2005

Thermogenic Mechanisms and Their Hormonal Regulation

J. Enrique Silva

Baystate Medical Education and Research Foundation, Department of Medicine, Division of Endocrinology, Baystate Medical Center, Tufts University Medical School, Springfield, Massachusetts

Increased heat generation from biological processes is inherentto homeothermy. Homeothermic species produce more heat fromsustaining a more active metabolism as well as from reducingfuel efficiency. This article reviews the mechanisms used byhomeothermic species to generate more heat and their regulationlargely by thyroid hormone (TH) and the sympathetic nervoussystem (SNS). Thermogenic mechanisms antecede homeothermy, butin homeothermic species they are activated and regulated. Someof these mechanisms increase ATP utilization (same amount ofheat per ATP), whereas others increase the heat resulting fromaerobic ATP synthesis (more heat per ATP). Among the former,ATP utilization in the maintenance of ionic gradient throughmembranes seems quantitatively more important, particularlyin birds. Regulated reduction of the proton-motive force toproduce heat, originally believed specific to brown adiposetissue, is indeed an ancient thermogenic mechanism. A regulatedproton leak has been described in the mitochondria of severaltissues, but its precise mechanism remains undefined. This leakis more active in homeothermic species and is regulated by TH,explaining a significant fraction of its thermogenic effect.Homeothermic species generate additional heat, in a facultativemanner, when obligatory thermogenesis and heat-saving mechanismsbecome limiting. Facultative thermogenesis is activated by theSNS but is modulated by TH. The type II iodothyronine deiodinaseplays a critical role in modulating the amount of the activeTH, T₃, in BAT, thereby modulating the responses to SNS. Otherhormones affect thermogenesis in an indirect or permissive manner,providing fuel and modulating thermogenesis depending on foodavailability, but they do not seem to have a primary role intemperature homeostasis. Thermogenesis has a very high energycost. Cold adaptation and food availability may have been conflictingselection pressures accounting for the variability of thermogenesisin humans.

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