Social Learning of a Spatial Task by Observation Alone

Interactions between conspecifics are central to the acquisition of useful memories in the real world. Observational learning, i.e., learning a task by observing the success or failure of others, has been reported in many species, including rodents. However, previous work in rats with NMDA-receptor...

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Bibliographic Details
Published in:Frontiers in behavioral neuroscience 2022-07, Vol.16, p.902675-902675
Main Authors: Doublet, Thomas, Nosrati, Mona, Kentros, Clifford G.
Format: Article
Language:English
Subjects:
Behavior
Behavioral Neuroscience
Boxes
Cognitive science
Conspecifics
Electrophysiological recording
Glutamic acid receptors (ionotropic)
Hippocampus
Laboratory animals
Learning
learning by observation
memory
N-Methyl-D-aspartic acid receptors
Observational learning
Reinforcement
social behavior
Social discrimination learning
social memory
Spatial discrimination learning
spatial memory
Success
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Summary:Interactions between conspecifics are central to the acquisition of useful memories in the real world. Observational learning, i.e., learning a task by observing the success or failure of others, has been reported in many species, including rodents. However, previous work in rats with NMDA-receptor blockade has shown that even extensive observation of an unexplored space through a clear barrier is not sufficient to generate a stable hippocampal representation of that space. This raises the question of whether rats can learn a spatial task in a purely observed space from watching a conspecific, and if so, does this somehow stabilize their hippocampal representation? To address these questions, we designed an observational spatial task in a two-part environment that is nearly identical to that of the aforementioned electrophysiological study, in which an observer rat watches a demonstrator animal to learn the location of a hidden reward. Our results demonstrate that rats do not need to physically explore an environment to learn a reward location, provided a conspecific demonstrates where it is. We also show that the behavioral memory is not affected by NMDA receptor blockade, suggesting that the spatial representation underlying the behavior has been consolidated by observation alone.
ISSN:1662-5153
1662-5153
DOI:10.3389/fnbeh.2022.902675