To maintain core body temperature in mammals, the normal CNS thermoregulatory reflex networks produce an increase in brown adipose tissue (BAT) thermogenesis in response to skin cooling, and an inhibition of the sympathetic outflow to BAT during skin rewarming. In contrast, these normal thermoregulatory reflexes appear to be inverted in hibernation/torpor: thermogenesis is inhibited during exposure to a cold environment, allowing dramatic reductions in core temperature and metabolism, and thermogenesis is activated during skin rewarming, contributing to a return of normal body temperature. Here we describe two unrelated experimental paradigms in which rats, a non-hibernating/torpid species, exhibit a "Thermoregulatory Inversion", characterized by an inhibition of BAT thermogenesis in response to skin cooling, and a switch in the gain of the skin cooling reflex transfer function from negative to positive values. Either transection of the neuraxis immediately rostral to the dorsomedial hypothalamus in anesthetized rats, or activation of A1 adenosine receptors within the CNS of free-behaving rats produces a state of thermoregulatory inversion, in which skin cooling inhibits BAT thermogenesis, leading to hypothermia, and skin warming activates BAT, supporting an increase in core temperature. These results reflect the existence of a novel neural circuit that mediates inverted thermoregulatory reflexes, and suggests a pharmacologic mechanism through which a deeply hypothermic state can be achieved in non-hibernating/torpid mammals, possibly including humans.
Tupone, D., Cano, G., Morrison, S.F. (2017). Thermoregulatory Inversion - a novel thermoregulatory paradigm. AMERICAN JOURNAL OF PHYSIOLOGY. REGULATORY, INTEGRATIVE AND COMPARATIVE PHYSIOLOGY, 312(5), R779-R786 [10.1152/ajpregu.00022.2017].
Thermoregulatory Inversion - a novel thermoregulatory paradigm
TUPONE, DOMENICO;
2017
Abstract
To maintain core body temperature in mammals, the normal CNS thermoregulatory reflex networks produce an increase in brown adipose tissue (BAT) thermogenesis in response to skin cooling, and an inhibition of the sympathetic outflow to BAT during skin rewarming. In contrast, these normal thermoregulatory reflexes appear to be inverted in hibernation/torpor: thermogenesis is inhibited during exposure to a cold environment, allowing dramatic reductions in core temperature and metabolism, and thermogenesis is activated during skin rewarming, contributing to a return of normal body temperature. Here we describe two unrelated experimental paradigms in which rats, a non-hibernating/torpid species, exhibit a "Thermoregulatory Inversion", characterized by an inhibition of BAT thermogenesis in response to skin cooling, and a switch in the gain of the skin cooling reflex transfer function from negative to positive values. Either transection of the neuraxis immediately rostral to the dorsomedial hypothalamus in anesthetized rats, or activation of A1 adenosine receptors within the CNS of free-behaving rats produces a state of thermoregulatory inversion, in which skin cooling inhibits BAT thermogenesis, leading to hypothermia, and skin warming activates BAT, supporting an increase in core temperature. These results reflect the existence of a novel neural circuit that mediates inverted thermoregulatory reflexes, and suggests a pharmacologic mechanism through which a deeply hypothermic state can be achieved in non-hibernating/torpid mammals, possibly including humans.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.