Top-down inputs are controlled by somatostatin-expressing interneurons during associative learning

Associative learning links sensory signals to their behavioral meaning by combining bottom-up inputs with top-down contextual information, enabling decision-making based on expected outcomes. It triggers plastic changes of neuronal responses in both excitatory and inhibitory cell populations. However, the role of inhibition in shaping this plasticity remains debated. Here we used chronic extracellular electrophysiology and optogenetic manipulation of inhibitory neurons and top-down inputs in mice learning an auditory discrimination task. We found that learning enhances stimulus selectivity in a subset of neurons in the primary auditory cortex. Interestingly, somatostatin-expressing (SST) interneurons decrease their response to the rewarded cue and bidirectionally regulate associative learning. More specifically, an increased activity of SST neurons impairs learning by altering bottom-up signaling, whereas the reduction of their activity facilitates learning by gating top-down inputs from the orbitofrontal cortex. These findings demonstrate that inhibition plays a critical role in gating top-down inputs to primary sensory cortices involved in associative learning.