Tonically active GABAergic neurons in the dorsal periaqueductal gray control the initiation and execution of instinctive escape

Abstract: To avoid predation, animals perform defensive actions that are both instinctive and adaptable to the environment. In mice, the decision to escape from imminent threats is implemented by a feed-forward circuit in the midbrain, where excitatory VGluT2+neurons in the dorsal periaqueductal gray (dPAG) compute escape initiation and escape vigour from threat evidence. Here we show that GABAergic VGAT+neurons in the dPAG dynamically control this process by modulating the excitability of excitatory escape neurons. Usi… Show more

“…However, these two forms of learning likely engage distinct neural circuits and may differ in their specificity and time course (46,48). The plasticity mechanism described here is likely part of a larger network for regulating defensive behavior, including processes in downstream areas SC and PAG, as well as complementary top-down pathways through the basal ganglia, hypothalamus and amygdala (20,21,(48)(49)(50)(51)(52)(53).…”

Overwriting an instinct: visual cortex instructs learning to suppress fear responses

“…However, these two forms of learning likely engage distinct neural circuits and may differ in their specificity and time course (46,48). The plasticity mechanism described here is likely part of a larger network for regulating defensive behavior, including processes in downstream areas SC and PAG, as well as complementary top-down pathways through the basal ganglia, hypothalamus and amygdala (20,21,(48)(49)(50)(51)(52)(53).…”

Overwriting an instinct: visual cortex instructs learning to suppress fear responses