Fasting hypometabolism and thermoregulation in cold-adapted rats

The influence of extended fasting on thyroid hormone: local and differentiated regulatory mechanisms

The hypometabolism induced by fasting has great potential in maintaining health and improving survival in extreme environments, among which thyroid hormone (TH) plays an important role in the adaptation and the formation of new energy metabolism homeostasis during long-term fasting. In the present review, we emphasize the potential of long-term fasting to improve physical health and emergency rescue in extreme environments, introduce the concept and pattern of fasting and its impact on the body's energy metabolism consumption. Prolonged fasting has more application potential in emergency rescue in special environments. The changes of THs caused by fasting, including serum biochemical characteristics, responsiveness of the peripheral and central hypothalamus-pituitary-thyroid (HPT) axis, and differential changes of TH metabolism, are emphasized in particular. It was proposed that the variability between brain and liver tissues in THs uptake, deiodination activation and inactivation is the key regulatory mechanism for the cause of peripheral THs decline and central homeostasis. While hypothalamic tanycytes play a pivotal role in the fine regulation of the HPT negative feedback regulation during long-term fasting. The study progress of tanycytes on thyrotropin-releasing hormone (TRH) release and deiodination is described in detail. In conclusion, the combination of the decrease of TH metabolism in peripheral tissues and stability in the central HPT axis maintains the basal physiological requirement and new energy metabolism homeostasis to adapt to long-term food scarcity. The molecular mechanisms of this localized and differential regulation will be a key research direction for developing measures for hypometabolic applications in extreme environment.

Energetics of fasting heterothermia in TRPV1-KO and wild type mice

To learn the possible role of TRPV1 in the changes of temperature regulation induced by short-term energy lack, TRPV1-KO and wild type mice were exposed to complete fasting for 2 or 3 days while their core temperature and locomotor activity were recorded using a biotelemetry method. In both types of mice, fasting led to progressive daytime hypothermia with night-time core temperature being maintained at normothermia (collectively called heterothermia). During fasting rises of locomotor activity were observed parallel to night-time normothermia with occasional increases of both parameters recorded every 2 to 3 hours (ultradian rhythms). The daytime fall of core temperature was significantly greater in wild type than in TRPV1-KO mice, in the former an advance of the temperature/activity rhythm having been observed in spite of the presence of a 12/12 hour light/darkness schedule. Re-feeding applied at the beginning of the light-period led to rapid reappearance of normothermia in both types of mice without a large increase in locomotor activity. It is concluded that the TRPV1-gene may have a role in the development of adaptive daytime hypothermia (and hence saving some energy) in mice during complete fasting but still allowing normothermia maintained at night, a strategy probably serving survival under natural conditions in small size rodents such as the mouse. The possible role of muscle thermogenesis either with or without gross bodily movement during fasting or on re-feeding, respectively, may be based on different mechanisms yet to be clarified.

Increased thermoregulatory responsiveness in cold adapted but not in hyperthyroid hypermetabolic rats

Cold-adapted (CA) rats, unlike non-adapted (NA) ones, give exaggerated metabolic response to acute cold exposure, with paradoxical "overshoot" core temperature (Tc) rise in the cold, and they also give enhanced hyperthermia to central injection of prostaglandin E1 (PGE1). The adaptation-dependent differences might be explained either by the high thermogenic capacity of peripheral tissues in CA rats or by differences in the central processing of regulatory signals. If high tissue metabolism sufficiently explains the extreme responses of CA animals, other hypermetabolic states (with high resting metabolic rate, RMR), e.g. hyperthyroidism, should also be accompanied by enhanced reactions. In the present study thermoregulatory responses to acute cold exposure or to PGE1 were compared in hypermetabolic CA, similarly hypermetabolic thyroxine-treated (T4) and control non-hypermetabolic NA rats (mean RMR = 8.12, 8.47 and 6.03 W kg(-1), respectively). Cold exposure was followed by paradoxical core temperature (Tc) rise of 0.5 to 0.7 degrees C only in CA rats, but by Tc fall (0.8 to 2.1 degrees C) in NA and T4 animals. Identical central stimuli (PGE1) induced larger elevations of Tc and metabolic rate in CA rats than in similarly hypermetabolic T4 or in non-hypermetabolic NA animals (mean Tc rise of 1.9 degrees C in CA vs. 0.9 degrees C in T4 and 1.0 degrees C in NA rats). Vasodilatation thresholds were also similar in NA and T4, but lowered in CA animals. A hypermetabolic status, per se, does not seem to explain the enhanced thermoregulatory responsiveness of CA animals, adaptation-induced central regulatory changes may be more important for the "overshoot" phenomenon.