Neural circuits and motivational processes for hunger

SM Sternson, JN Betley, ZFH Cao - Current opinion in neurobiology, 2013 - Elsevier
Current opinion in neurobiology, 2013Elsevier
How does an organism's internal state direct its actions? At one moment an animal forages
for food with acrobatic feats such as tree climbing and jumping between branches. At
another time, it travels along the ground to find water or a mate, exposing itself to predators
along the way. These behaviors are costly in terms of energy or physical risk, and the
likelihood of performing one set of actions relative to another is strongly modulated by
internal state. For example, an animal in energy deficit searches for food and a dehydrated …
How does an organism's internal state direct its actions? At one moment an animal forages for food with acrobatic feats such as tree climbing and jumping between branches. At another time, it travels along the ground to find water or a mate, exposing itself to predators along the way. These behaviors are costly in terms of energy or physical risk, and the likelihood of performing one set of actions relative to another is strongly modulated by internal state. For example, an animal in energy deficit searches for food and a dehydrated animal looks for water. The crosstalk between physiological state and motivational processes influences behavioral intensity and intent, but the underlying neural circuits are poorly understood. Molecular genetics along with optogenetic and pharmacogenetic tools for perturbing neuron function have enabled cell type-selective dissection of circuits that mediate behavioral responses to physiological state changes. Here, we review recent progress into neural circuit analysis of hunger in the mouse by focusing on a starvation-sensitive neuron population in the hypothalamus that is sufficient to promote voracious eating. We also consider research into the motivational processes that are thought to underlie hunger in order to outline considerations for bridging the gap between homeostatic and motivational neural circuits.
Elsevier