Exercise, neurogenesis and memory

Hippocampal adult neurogenesis is modulated by many factors including age, stress, environmental enrichment, physical exercise and learning. Spontaneous exercise in a running wheel stimulates cell proliferation in the adult dentate gyrus and facilitates acquisition and/or retention of hippocampal-dependent tasks including the Morris water maze. While it is well established that regular physical exercise improves cognitive performance, it is unclear for how long these benefits last after its interruption. In this study, we investigate the temporal relation between exercise-induced benefits associated with learning of a hippocampal-dependent task, this relationship with neurogenesis, considering the time after exercise has ended. Independent groups of rats were given free access to either unlocked (EXE Group) or locked (No-EXE Group) running wheels for 7 days, having received daily injections of BrdU for the last 3 days. The animals were then transferred to standard home cages. After a time period of either 1, 3 or 6 weeks, the animals were tested in the Morris water maze, one of them being exposed to the spatial working memory task dependent on hippocampal function (H) and partly to a task search for a visible platform, independent of hippocampal function (NH). In both cases, the interval between trials (ITI) was 10 minutes during sessions and 1-6 and (virtually) zero minute during the sessions 7-10. After the task brains were processed for immunohistochemistry. Cell proliferation and net neurogenesis were assessed in hippocampal sections using antibodies against BrdU, NeuN (to identify mature neurons), and DCX (to identify immature neurons). Data of the present study confirm that exposure of rats to 7 days of spontaneous wheel running increases cell proliferation and neurogenesis. In contrast, however, the present results did not confirm that this neurogenesis is accompanied by a significant improvement in spatial learning, as evaluated using the working memory version of the Morris’ water maze task. The introduction of a delay period between the end of exercise and cognitive training on the Morris water maze reduces cell survival; the number of new neurons was higher in the EXE1 week delay group as compared to the EXE6 week delay. We showed that learning the Morris water maze in the working memory task dependent on hippocampal function (H) increases the new neurons survival, in contrast, learning hippocampal-independent version of the task decreases number of new neurons (AU)