Spatial reference memory is known to be modulated by the dopaminergic system involving different brain regions. Here, we sought to identify the contribution of D1 (D1R) and D2 (D2R)-like dopamine receptor signaling on learning and memory in a food rewarded hole-board task by intracerebroventricular infusing D1R- and D2R- like receptor agonists (SKF-81297 and Sumanirole) and antagonists (SCH 23390 and Remoxipride) once 30 min prior to daily training sessions. D1R agonism induced persistent enhancement of performance, whereas D1R antagonism impaired reference memory formation. D2R agonist and antagonist exerted no effects. Phase specific comparisons revealed an enhancement of spatial acquisition in the presence of the D1R but not D2R agonism on acquisition, but not during retention. Since task difficulty might skew dopamine-induced improvements in learning and memory, we tested the D1R agonist in the hole-board task with increased difficulty. Drug treated animals performed significantly better during all training phases, with results better resolved than in the easy task. Additionally, proteomic analysis of the prefrontal cortex revealed ninety six proteins to be regulated by D1R agonism, from which 35 were correlated with behavioral performance. Obtained targets were grouped by function, showing synaptic transmission, synaptic remodeling, and dendritic spine morphology as the major functional classes affected. In sum, we find that activation of D1R signaling during spatial acquisition and retention improved reference memory index, depended on the task difficulty, and altered the proteome landscape of the prefrontal cortex indicative of massive organizational synaptic restructuring.
Keywords: Cognition; Dopamine; Frontal cortex; Long-term memory; Synaptic restructuring; Task load.
Copyright © 2019. Published by Elsevier B.V.