Resumen
Glutamate transporter 1 (GLT1) is the main astrocytic transporter that shapes glutamatergic transmission in the brain. However, whether this transporter modulates sleep–wake regulatory neurons is unknown. Using quantitative immunohistochemical analysis, we assessed perisomatic GLT1 apposition with sleep–wake neurons in the male rat following 6 h sleep deprivation (SD) or following 6 h undisturbed conditions when animals were mostly asleep (Rest). We found that SD decreased perisomatic GLT1 apposition with wake-promoting orexin neurons in the lateral hypothalamus compared with Rest. Reduced GLT1 apposition was associated with tonic presynaptic inhibition of excitatory transmission to these neurons due to the activation of Group III metabotropic glutamate receptors, an effect mimicked by a GLT1 inhibitor in the Rest condition. In contrast, SD resulted in increased GLT1 apposition with sleep-promoting melanin-concentrating hormone (MCH) neurons in the lateral hypothalamus. Functionally, this decreased the postsynaptic response of MCH neurons to high-frequency synaptic activation without changing presynaptic glutamate release. The changes in GLT1 apposition with orexin and MCH neurons were reversed after 3 h of sleep opportunity following 6 h SD. These SD effects were specific to orexin and MCH neurons, as no change in GLT1 apposition was seen in basal forebrain cholinergic or parvalbumin-positive GABA neurons. Thus, within a single hypothalamic area, GLT1 differentially regulates excitatory transmission to wake-and sleep-promoting neurons depending on sleep history. These processes may constitute novel astrocyte-mediated homeostatic mechanisms controlling sleep–wake behavior.
| Idioma original | English |
|---|---|
| Páginas (desde-hasta) | 2505-2518 |
| Número de páginas | 14 |
| Publicación | Journal of Neuroscience |
| Volumen | 38 |
| N.º | 10 |
| DOI | |
| Estado | Published - mar. 7 2018 |
Nota bibliográfica
Funding Information:This work was supported by Canadian Institutes of Health Research CIHRRNL-132870 and Research & Development Corporation New foundland and Labrador 5404.1171.102 to M.H., and Canadian Institutes of Health ResearchCIHRMOP-93673 and Natural Sciences and Engineering Research CouncilNSERCRGPIN 2015-05571 to K.S. C.B. was supported by the Nova Scotia Health Research Foundation (Doctoral Scotia Scholarship). We thank Samuel Deurveilher for helpful discussions; Joan Burns, Christian Alberto, Stephen Whitefield, Elizabeth Seary, Alex Madore, Erik Wibowo, and Maxine Profitt for technical assistance; Shannon Hall for help with analysis of quantitative immunohistochemistry; and Kenneth Baimbridge for a gift of parvalbumin antibody.
Funding Information:
This work was supported by Canadian Institutes of Health Research RNL-132870 and Research & Development CorporationNewfoundlandandLabrador5404.1171.102toM.H.,andCanadianInstitutesofHealthResearchMOP-93673andNaturalSciencesandEngineeringResearchCouncilRGPIN2015-05571toK.S.C.B.wassupportedbythe
Funding Information:
Nova Scotia Health Research Foundation (Doctoral Scotia Scholarship). We thank Samuel Deurveilher for helpful discussions; Joan Burns, Christian Alberto, Stephen Whitefield, Elizabeth Seary, Alex Madore, Erik Wibowo, and Maxine Profitt for technical assistance; Shannon Hall for help with analysis of quantitative immunohistochemistry; and Kenneth Baimbridge for a gift of parvalbumin antibody. The authors declare no competing financial interests. *M.H. and K.S. contributed equally to this work.
Publisher Copyright:
© 2018 the authors.
ASJC Scopus Subject Areas
- General Neuroscience