Abstract
The ability to entrain circadian rhythms to food availability is important for survival. Food-entrained circadian rhythms are characterized by increased locomotor activity in anticipation of food availability (food anticipatory activity). However, the molecular components and neural circuitry underlying the regulation of food anticipatory activity remain unclear. Here we show that serotonin2C receptor (5-HT2CR) null mutant mice subjected to a daytime restricted feeding schedule exhibit enhanced food anticipatory activity compared to wild-type littermates, without phenotypic differences in the impact of restricted feeding on food consumption, body weight loss, or blood glucose levels. Moreover, we show that the enhanced food anticipatory activity in 5-HT2CR null mutant mice develops independent of external light cues and persists during two days of total food deprivation, indicating that food anticipatory activity in 5-HT2CR null mutant mice reflects the locomotor output of a food-entrainable oscillator. Whereas restricted feeding induces c-fos expression to a similar extent in hypothalamic nuclei of wild-type and null mutant animals, it produces enhanced expression in the nucleus accumbens and other extrahypothalamic regions of null mutant mice relative to wild-type subjects. These data suggest that 5-HT2CRs gate food anticipatory activity through mechanisms involving extrahypothalamic neural pathways.
Highlights
Multiple aspects of physiology and behavior exhibit circadian rhythmicity [1]
We found no significant correlations between locomotor activity occurring in the first hour of the dark cycle and c-fos gene expression in any of the regions tested (DMH correlation: R2 = 0.051, p = 0.338, Figure S4A; lateral hypothalamic area (LHA) correlation: R2 = 0.109, p = 0.156, Figure S4B; barrel cortex correlation: R2 = 0.085, p = 0.211, Figure S4C; nucleus accumbens (NAc) correlation: R2 = 0.019, p = 0.567, Figure S4D)
In response to a temporally restricted feeding schedule, 5-HT2CR null mutant mice exhibit enhanced FAA relative to wild-type mice
Summary
Multiple aspects of physiology and behavior exhibit circadian rhythmicity [1]. These circadian rhythms are driven by an endogenous molecular clock located in the suprachiasmatic nucleus (SCN) and entrains to light/dark cues from the environment [2]. Many species have evolved mechanisms for the entrainment of circadian rhythms to other environmental cues important for survival, such as food availability. Once established, FAA persists after two or more days of total food deprivation [8], indicating that FAA is not driven by cycles of energy depletion and restoration imposed by the scheduled meal
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