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Please use this identifier to cite or link to this item: https://doi.org/10.7554/eLife.05558
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dc.titleA cortical disinhibitory circuit for enhancing adult plasticity
dc.contributor.authorFu, Y
dc.contributor.authorKaneko, M
dc.contributor.authorTang, Y
dc.contributor.authorAlvarez-Buylla, A
dc.contributor.authorStryker, M.P
dc.date.accessioned2020-10-26T08:31:14Z
dc.date.available2020-10-26T08:31:14Z
dc.date.issued2015
dc.identifier.citationFu, Y, Kaneko, M, Tang, Y, Alvarez-Buylla, A, Stryker, M.P (2015). A cortical disinhibitory circuit for enhancing adult plasticity. eLife 2015 (4). ScholarBank@NUS Repository. https://doi.org/10.7554/eLife.05558
dc.identifier.issn2050084X
dc.identifier.urihttps://scholarbank.nus.edu.sg/handle/10635/180346
dc.description.abstractThe adult brain continues to learn and can recover from injury, but the elements and operation of the neural circuits responsible for this plasticity are not known. In previous work we have: shown that locomotion dramatically enhances neural activity in the visual cortex (V1) of the mouse (Neill and Stryker, 2010); identified the cortical circuit responsible for this enhancement (Fu et al., 2014); and shown that locomotion also dramatically enhances adult plasticity (Kaneko & Stryker, 2014). The circuit responsible that is responsible for enhancing neural activity in the visual cortex contains both vasoactive intestinal peptide (VIP) and somatostatin (SST) neurons (Fu et al., 2014). Here we ask whether this VIP-SST circuit enhances plasticity directly, independent of locomotion and aerobic activity. Optogenetic activation or genetic blockade of this circuit reveal that it is both necessary and sufficient for rapidly increasing V1 cortical responses following manipulation of visual experience in adult mice. These findings reveal a disinhibitory circuit that regulates adult cortical plasticity. © 2015, eLife Sciences Publications Ltd. All rights reserved.
dc.relation.isreplacedbyhdl:10635/179380
dc.rightsAttribution 4.0 International
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/
dc.sourceUnpaywall 20201031
dc.subjectsomatostatin
dc.subjectvasoactive intestinal polypeptide
dc.subjectsomatostatin
dc.subjectvasoactive intestinal polypeptide
dc.subjectadult
dc.subjectanimal experiment
dc.subjectanimal tissue
dc.subjectArticle
dc.subjectbrain electrophysiology
dc.subjectbrain tissue
dc.subjectcontrolled study
dc.subjectfemale
dc.subjectfiber optic cannula implantation
dc.subjectfluorescence imaging
dc.subjectimmunohistochemistry
dc.subjectimplantation
dc.subjectlocomotion
dc.subjectmale
dc.subjectmonocular deprivation
dc.subjectmouse
dc.subjectnerve block
dc.subjectnerve cell plasticity
dc.subjectnonhuman
dc.subjectoptogenetics
dc.subjectsynaptic transmission
dc.subjecttetrode recording
dc.subjectvirus
dc.subjectvisual cortex
dc.subjectvisual stimulation
dc.subjectaging
dc.subjectanimal
dc.subjectC57BL mouse
dc.subjecteye dominance
dc.subjectmetabolism
dc.subjectnerve cell
dc.subjectnerve cell inhibition
dc.subjectnerve cell plasticity
dc.subjectphysiology
dc.subjectrunning
dc.subjectMus
dc.subjectAging
dc.subjectAnimals
dc.subjectDominance, Ocular
dc.subjectMice, Inbred C57BL
dc.subjectNeural Inhibition
dc.subjectNeuronal Plasticity
dc.subjectNeurons
dc.subjectRunning
dc.subjectSomatostatin
dc.subjectSynaptic Transmission
dc.subjectVasoactive Intestinal Peptide
dc.subjectVisual Cortex
dc.typeArticle
dc.contributor.departmentPHYSIOLOGY
dc.description.doi10.7554/eLife.05558
dc.description.sourcetitleeLife
dc.description.volume2015
dc.description.issue4
dc.published.statePublished
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