Striatal Cholinergic Interneurons Signal Aversion and Drive Avoidance

Seeking reward and avoiding punishment are essential for survival. However, how the brain learns aversive value and generates avoidance remains poorly understood. We investigate acetylcholine-releasing striatal cholinergic interneurons (ChIs), which exhibit prominent excitation to salient behavioral cues but have largely been postulated to play a permissive role in reinforcement learning. Using voltage imaging in mice performing aversive versus reward conditioning tasks, we reveal learning-mediated changes in both subthreshold membrane voltage and suprathreshold spiking of individual ChIs. Across tasks, ChIs exhibit stronger immediate excitation to conditioned cues predicting negative outcomes than positive outcomes. This valence-dependent response augmentation reflects a learning-induced network change specific to cues predicting negative outcomes. Furthermore, brief optogenetic silencing of this immediate excitation selectively impairs conditioned avoidance, but not conditioned approach. Together, these results reveal that ChIs actively signal evidence for aversion and play a critical role in driving avoidance, highlighting a cholinergic mechanism underlying aversive learning.