Regulation of Neuronal Plasticity and Fear by a Dynamic Change in PAR1 – G Protein Coupling in the Amygdala

Fear memories are acquired through neuronal plasticity, an orchestrated sequence of events regulated at circuit and cellular levels. The conventional model of fear acquisition assumes unimodal (e.g. excitatory or inhibitory) roles of modulatory receptors in controlling neuronal activity and learning. Contrary to this view, we show that protease-activated receptor-1 (PAR1) promotes contrasting neuronal responses depending on the emotional status of an animal by a dynamic shift between distinct G protein coupling partners. In the basolateral amygdala of fear-naïve mice PAR1 couples to Gα(q/11) and Gα(o) proteins, while after fear conditioning coupling to Gα(o) increases. Concurrently, stimulation of PAR1 before conditioning enhanced, but afterwards it inhibited firing of basal amygdala neurons. An initial impairment of the long-term potentiation (LTP) in PAR1-deficient mice was transformed into an increase in LTP and enhancement of fear after conditioning. These effects correlated with more frequent AMPA receptor-mediated miniature post synaptic events and increased neuronal excitability. Our findings point to experience-specific shifts in PAR1-G protein-coupling in the amygdala as a novel mechanism regulating neuronal excitability and fear.