Abstract
When fed in restricted amounts, rodents show robust activity in the hours preceding expected meal delivery. This process, termed food anticipatory activity (FAA), is independent of the light-entrained clock, the suprachiasmatic nucleus, yet beyond this basic observation there is little agreement on the neuronal underpinnings of FAA. One complication in studying FAA using a calorie restriction model is that much of the brain is activated in response to this strong hunger signal. Thus, daily timed access to palatable meals in the presence of continuous access to standard chow has been employed as a model to study FAA in rats. In order to exploit the extensive genetic resources available in the murine system we extended this model to mice, which will anticipate rodent high fat diet but not chocolate or other sweet daily meals (Hsu, Patton, Mistlberger, and Steele; 2010, PLoS ONE e12903). In this study we test additional fatty meals, including peanut butter and cheese, both of which induced modest FAA. Measurement of core body temperature revealed a moderate preprandial increase in temperature in mice fed high fat diet but entrainment due to handling complicated interpretation of these results. Finally, we examined activation patterns of neurons by immunostaining for the immediate early gene c-Fos and observed a modest amount of entrainment of gene expression in the hypothalamus of mice fed a daily fatty palatable meal.
Highlights
The ability of animals to time intervals to match resource availability is widely conserved in nature
Other circadian-like behaviors have been elicited by restricted feeding (RF) and calorie restriction (CR) paradigms, in which a meal is presented in limited amounts at a fixed time each day, usually in the middle of the light period [2,3,4]
Since Food Anticipatory Activity (FAA) persists beyond one cycle of total food deprivation at its original interval, researchers postulate the existence of a food entrainable oscillator (FEO) that is capable of operating autonomously at circadian intervals [3,5]
Summary
The ability of animals to time intervals to match resource availability is widely conserved in nature. Light-entrained circadian behaviors related to sleep-wake cycles have a defined neural substrate known as the suprachiasmatic nucleus (SCN) of the hypothalamus [1]. Other circadian-like behaviors have been elicited by restricted feeding (RF) and calorie restriction (CR) paradigms, in which a meal is presented in limited amounts at a fixed time each day, usually in the middle of the light period [2,3,4]. Seminal studies have shown that after a few days, rodents start showing bouts of hyperactivity in anticipation of the scheduled meal, a behavior termed Food Anticipatory Activity (FAA) [5]. Restricted feeding schedules result in an extreme catabolic state; importantly, starvation induces hyperactivity in rodents (especially mice), potentially confounding the behavioral readout of FAA
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