Abstract
Foraging is costly in terms of time and energy. An endogenous food-entrainable system allows anticipation of predictable changes of food resources in nature. Yet the molecular mechanism that controls food anticipation in mammals remains elusive. Here we report that deletion of the clock component Rev-erbα impairs food entrainment in mice. Rev-erbα global knockout (GKO) mice subjected to restricted feeding showed reduced elevations of locomotor activity and body temperature prior to mealtime, regardless of the lighting conditions. The failure to properly anticipate food arrival was accompanied by a lack of phase-adjustment to mealtime of the clock protein PERIOD2 in the cerebellum, and by diminished expression of phosphorylated ERK 1/2 (p-ERK) during mealtime in the mediobasal hypothalamus and cerebellum. Furthermore, brain-specific knockout (BKO) mice for Rev-erbα display a defective suprachiasmatic clock, as evidenced by blunted daily activity under a light-dark cycle, altered free-running rhythm in constant darkness and impaired clock gene expression. Notably, brain deletion of Rev-erbα totally prevented food-anticipatory behaviour and thermogenesis. In response to restricted feeding, brain deletion of Rev-erbα impaired changes in clock gene expression in the hippocampus and cerebellum, but not in the liver. Our findings indicate that Rev-erbα is required for neural network-based prediction of food availability.
Highlights
Foraging is costly in terms of time and energy
The sharp preprandial rise in body temperature seen in WT animals was not observed in global knockout (GKO) mice ([Genotype x ZT] interaction: F(3,59) = 2.8, p < 0.05; Fig. 1B,C)
Food-induced phase-adjustment of liver oscillations occurred in GKO mice in spite of up-regulated Clock and Bmal[1] expression (Fig. 2A–C)
Summary
Foraging is costly in terms of time and energy. An endogenous food-entrainable system allows anticipation of predictable changes of food resources in nature. When food access is limited to a narrow daily temporal window, animals can predict feeding time and change their activity pattern. They develop food-seeking behaviours in anticipation of mealtime, concomitant with physiological and hormonal activations[9,10,11]. We hypothesized that brain expression of REV-ERBαmay be required to link circadian feeding cues to the central regulation of behaviour and physiology. We show that both global and brain-specific deletions of Rev-erbα profoundly altered the expression of food-anticipatory components. This study gives evidence that Rev-erbα in the central nervous system is essential to shape the 24-hour pattern of activity in conditions of limited food access
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