Frontiers in Molecular Neuroscience (Apr 2018)

RNA-Sequencing Reveals Unique Transcriptional Signatures of Running and Running-Independent Environmental Enrichment in the Adult Mouse Dentate Gyrus

  • Catherine-Alexandra Grégoire,
  • Catherine-Alexandra Grégoire,
  • Catherine-Alexandra Grégoire,
  • Stephanie Tobin,
  • Stephanie Tobin,
  • Brianna L. Goldenstein,
  • Brianna L. Goldenstein,
  • Brianna L. Goldenstein,
  • Éric Samarut,
  • Éric Samarut,
  • Éric Samarut,
  • Andréanne Leclerc,
  • Anne Aumont,
  • Pierre Drapeau,
  • Pierre Drapeau,
  • Pierre Drapeau,
  • Stephanie Fulton,
  • Stephanie Fulton,
  • Karl J. L. Fernandes,
  • Karl J. L. Fernandes,
  • Karl J. L. Fernandes

DOI
https://doi.org/10.3389/fnmol.2018.00126
Journal volume & issue
Vol. 11

Abstract

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Environmental enrichment (EE) is a powerful stimulus of brain plasticity and is among the most accessible treatment options for brain disease. In rodents, EE is modeled using multi-factorial environments that include running, social interactions, and/or complex surroundings. Here, we show that running and running-independent EE differentially affect the hippocampal dentate gyrus (DG), a brain region critical for learning and memory. Outbred male CD1 mice housed individually with a voluntary running disk showed improved spatial memory in the radial arm maze compared to individually- or socially-housed mice with a locked disk. We therefore used RNA sequencing to perform an unbiased interrogation of DG gene expression in mice exposed to either a voluntary running disk (RUN), a locked disk (LD), or a locked disk plus social enrichment and tunnels [i.e., a running-independent complex environment (CE)]. RNA sequencing revealed that RUN and CE mice showed distinct, non-overlapping patterns of transcriptomic changes versus the LD control. Bio-informatics uncovered that the RUN and CE environments modulate separate transcriptional networks, biological processes, cellular compartments and molecular pathways, with RUN preferentially regulating synaptic and growth-related pathways and CE altering extracellular matrix-related functions. Within the RUN group, high-distance runners also showed selective stress pathway alterations that correlated with a drastic decline in overall transcriptional changes, suggesting that excess running causes a stress-induced suppression of running’s genetic effects. Our findings reveal stimulus-dependent transcriptional signatures of EE on the DG, and provide a resource for generating unbiased, data-driven hypotheses for novel mediators of EE-induced cognitive changes.

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