Prelimbic corticopontine neurons gate extinction learning

The prelimbic cortex is essential for association of temporally separated events, and impedes extinction of learned association. The network mechanism underlying reversal learning, however, remains elusive. Here, we found that mitochondria-dependent post-tetanic potentiation at synapses onto prelimbic corticopontine neurons impedes extinction learning without affecting initial associative learning. Rats underwent trace fear conditioning followed by extinction sessions. Pharmacological inhibition of post-tetanic potentiation using tetaraphenylphosphnium (TPP), a mitochondrial Ca2+ release blocker, accelerated extinction of trace fear memory, leaving trace fear memory formation intact. Optogenetic inhibition of corticopontine, but not commissural, neurons phenocopied these effects. Electrophysiological recordings and Ca2+ imaging revealed that TPP treatment reduced the persistent activity of corticopontine neurons encoding tone presentation. Mechanistically, associative learning triggers the bursting activity of prelimbic pyramidal neurons that induces post-tetanic potentiation of corticopontine neurons, an effect blocked by TPP treatment. Thus, we identified a prelimbic cell type- and local circuit-specific mechanism that selectively gates extinction learning.