Litcius/Paper detail

Dopaminergic mechanism underlying reward-encoding of punishment omission during reversal learning in Drosophila

Li Yan McCurdy, Preeti Sareen, Pasha A. Davoudian, Michael N. Nitabach

2021Nature Communications61 citationsDOIOpen Access PDF

Abstract

Animals form and update learned associations between otherwise neutral sensory cues and aversive outcomes (i.e., punishment) to predict and avoid danger in changing environments. When a cue later occurs without punishment, this unexpected omission of aversive outcome is encoded as reward via activation of reward-encoding dopaminergic neurons. How such activation occurs remains unknown. Using real-time in vivo functional imaging, optogenetics, behavioral analysis and synaptic reconstruction from electron microscopy data, we identify the neural circuit mechanism through which Drosophila reward-encoding dopaminergic neurons are activated when an olfactory cue is unexpectedly no longer paired with electric shock punishment. Reduced activation of punishment-encoding dopaminergic neurons relieves depression of olfactory synaptic inputs to cholinergic neurons. Synaptic excitation by these cholinergic neurons of reward-encoding dopaminergic neurons increases their odor response, thus decreasing aversiveness of the odor. These studies reveal how an excitatory cholinergic relay from punishment- to reward-encoding dopaminergic neurons encodes the absence of punishment as reward, revealing a general circuit motif for updating aversive memories that could be present in mammals.

Topics & Concepts

NeuroscienceDopaminergicOptogeneticsPunishment (psychology)CholinergicCholinergic neuronPsychologyBiological neural networkGlutamatergicBiologyDopamineGlutamate receptorGeneticsReceptorSocial psychologyNeurobiology and Insect Physiology ResearchInsect and Arachnid Ecology and BehaviorAnimal Behavior and Reproduction