A Unique Mouse Model of Early Life Exercise Enables Hippocampal Memory and Synaptic Plasticity

Abstract

AbstractAerobic exercise is a powerful modulator of learning and memory. Molecular mechanisms underlying the cognitive benefits of exercise are well documented in adult rodents. Animal models of exercise targeting specific postnatal periods of hippocampal development and plasticity are lacking. Here we characterize a model of early-life exercise (ELE) in male and female mice designed with the goal of identifying critical periods by which exercise may have a lasting impact on hippocampal memory and synaptic plasticity. Mice freely accessed a running wheel during three postnatal periods: the 4th postnatal week (juvenile ELE, P21-27), 6th postnatal week (adolescent ELE, P35-41), or 4th-6th postnatal weeks (juvenile-adolescent ELE, P21-41). All exercise groups significantly increased their running distances over time. When exposed to a weak learning stimulus, mice that had exercised during the juvenile period were able to form lasting long-term memory for a hippocampus-dependent spatial memory task. Electrophysiological experiments revealed enhanced long-term potentiation in hippocampal CA1 the juvenile-adolescent ELE group only. Furthermore, basal synaptic transmission was significantly increased in all mice that exercised during the juvenile period. Our results suggest early-life exercise can enable hippocampal memory, synaptic plasticity, and basal synaptic physiology when occurring during postnatal periods of hippocampal maturation.