Sippy, TanyaChaimowitz, CorrynCrochet, SylvainPetersen, Carl C. H.2022-01-152022-01-152022-01-152021-01-0110.1093/function/zqab049https://infoscience.epfl.ch/handle/20.500.14299/184499WOS:000734900700003The striatum integrates sensorimotor and motivational signals, likely playing a key role in reward-based learning of goal-directed behavior. However, cell type-specific mechanisms underlying reinforcement learning remain to be precisely determined. Here, we investigated changes in membrane potential dynamics of dorsolateral striatal neurons comparing naive mice and expert mice trained to lick a reward spout in response to whisker deflection. We recorded from three distinct cell types: (i) direct pathway striatonigral neurons, which express type 1 dopamine receptors; (ii) indirect pathway striatopallidal neurons, which express type 2 dopamine receptors; and (iii) tonically active, putative cholinergic, striatal neurons. Task learning was accompanied by cell type-specific changes in the membrane potential dynamics evoked by the whisker deflection and licking in successfully-performed trials. Both striatonigral and striatopallidal types of striatal projection neurons showed enhanced task-related depolarization across learning. Striatonigral neurons showed a prominent increase in a short latency sensory-evoked depolarization in expert compared to na<spacing diaeresis>ive mice. In contrast, the putative cholinergic striatal neurons developed a hyperpolarizing response across learning, driving a pause in their firing. Our results reveal cell type-specific changes in striatal membrane potential dynamics across the learning of a simple goal-directed sensorimotor transformation, helpful for furthering the understanding of the various potential roles of different basal ganglia circuits.Cell BiologyPhysiologystriatumgoal-directed sensorimotor transformationreward-based learningwhole-cell membrane potentialbasal ganglia circuitscholinergic interneuronsgabaergic interneuronsdendritic excitabilityindirect pathwaysdopamine releaserat neostriatummodulationneuronsplasticitytext::journal::journal article::research article