Abstract
ABSTRACTRich social, physical, and cognitively stimulating lifestyles have powerful effects on cognitive abilities, especially when they are experienced early in life. Cognitive therapies are widely used to attenuate cognitive impairment due to intellectual disability, but also aging and neurodegeneration, however the underlying neural mechanisms are poorly understood. Here we investigated the neural substrates of memory amelioration induced by postnatal environmental enrichment (EE) in diploid female mice and Ts65Dn female mice with partial trisomy of genes ortholog to human chromosome 21, a standard model of Down syndrome (DS, trisomy 21). We recorded neural activities in two brain structures key for cognitive function, the hippocampus and the prefrontal cortex, during rest, sleep and memory performance in mice reared in standard or enriched environments for 7 weeks post-weaning. We found that EE shaped hippocampal- prefrontal neural dynamics in diploid mice and rescued the same disrupted pathways in Ts65Dn mice. The neural activity changes detected in EE-reared wild-type mice combined task-independent adjustments (augmented hippocampal pyramidal activity and gamma synchrony across different brain states) and memory-dependent adjustments (enhanced theta-gamma coupling and ripples in the HPC). Therefore, both brain state adjustments and memory-associated adjustments are good candidates to underlie the beneficial effects of EE on cognition in diploid female mice. Concomitantly, EE attenuated hippocampal and prefrontal hypersynchrony in trisomic females, suggesting distinct neural mechanisms for the generation and rescue of healthy and pathological brain synchrony, respectively, by EE. These results put forward hippocampal hypersynchrony and hippocampal-prefrontal miscommunication as major neural mechanisms underlying the beneficial effects of EE for intellectual disability in DS.
Publisher
Cold Spring Harbor Laboratory