Serotonin is implicated in mood and affective disorders1,2 but growing evidence suggests that its core endogenous role may be to promote flexible adaptation to changes in the causal structure of the environment3–8. This stems from two functions of endogenous serotonin activation: inhibiting learned responses that are not currently adaptive9,10 and driving plasticity to reconfigure them1113. These mirror dual functions of dopamine in invigorating reward-related responses and promoting plasticity that reinforces new ones16,17. However, while dopamine neurons are known to be activated by reward prediction errors18,19, consistent with theories of reinforcement learning, the reported firing patterns of serotonin neurons21–23 do not accord with any existing theories1,24,25. Here, we used long-term photometric recordings in mice to study a genetically-defined population of dorsal raphe serotonin neurons whose activity we could link to normal reversal learning. We found that these neurons are activated by both positive and negative prediction errors, thus reporting the kind of surprise signal proposed to promote learning in conditions of uncertainty26,27. Furthermore, by comparing cue responses of serotonin and dopamine neurons we found differences in learning rates that could explain the importance of serotonin in inhibiting perseverative responding. Together, these findings show how the firing patterns of serotonin neurons support a role in cognitive flexibility and suggest a revised model of dopamine-serotonin opponency with potential clinical implications.
Author response: Activity patterns of serotonin neurons underlying cognitive flexibility