Litcius/Paper detail

Prediction error drives associative learning and conditioned behavior in a spiking model of Drosophila larva

Anna-Maria Jürgensen, Panagiotis Sakagiannis, Michael H. Schleyer, Bertram Gerber, Martin Paul Nawrot

2023iScience13 citationsDOIOpen Access PDF

Abstract

Predicting reinforcement from sensory cues is beneficial for goal-directed behavior. In insect brains, underlying associations between cues and reinforcement, encoded by dopaminergic neurons, are formed in the mushroom body. We propose a spiking model of the Drosophila larva mushroom body. It includes a feedback motif conveying learned reinforcement expectation to dopaminergic neurons, which can compute prediction error as the difference between expected and present reinforcement. We demonstrate that this can serve as a driving force in learning. When combined with synaptic homeostasis, our model accounts for theoretically derived features of acquisition and loss of associations that depend on the intensity of the reinforcement and its temporal proximity to the cue. From modeling olfactory learning over the time course of behavioral experiments and simulating the locomotion of individual larvae toward or away from odor sources in a virtual environment, we conclude that learning driven by prediction errors can explain larval behavior.

Topics & Concepts

Mushroom bodiesReinforcement learningAssociative learningReinforcementDopaminergicSensory cueAssociative propertyDrosophila (subgenus)NeuroscienceSensory systemComputer scienceBiologyArtificial intelligenceDrosophila melanogasterPsychologyDopamineGeneGeneticsSocial psychologyPure mathematicsMathematicsNeurobiology and Insect Physiology ResearchAnimal Behavior and ReproductionInsect and Arachnid Ecology and Behavior