Layer 4 Gates Plasticity in Visual Cortex Independent of a Canonical Microcircuit

Layer 4 Gates Plasticity in Visual Cortex Independent of a Canonical Microcircuit

Disrupting binocular vision during a developmental critical period can yield enduring changes to ocular dominance (OD) in primary visual cortex (V1). Here we investigated how this experience-dependent plasticity is coordinated within the laminar circuitry of V1 by deleting separately in each cortica...

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Bibliographic Details
Published in:Current biology Vol. 30; no. 15; pp. 2962 - 2973.e5
Main Authors: Frantz, Michael G., Crouse, Emily C., Sokhadze, Guela, Ikrar, Taruna, Stephany, Céleste-Élise, Nguyen, Collins, Xu, Xiangmin, McGee, Aaron W.
Format: Journal Article
Language:English
Published: England Elsevier Inc 03-08-2020
Subjects:
amblyopia
Animals
cortical circuit
critical period
Dominance, Ocular
experience-dependent plasticity
Gene Deletion
Mice
myelin
Neuronal Plasticity - physiology
Nogo Receptor 1 - genetics
Nogo Receptor 1 - physiology
ocular dominance
reticulon receptor
Sensory Receptor Cells - physiology
Vision, Binocular - physiology
visual cortex
Visual Cortex - physiology
myelin
experience-dependent plasticity
ocular dominance
cortical circuit
critical period
amblyopia
visual cortex
reticulon receptor
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Summary:Disrupting binocular vision during a developmental critical period can yield enduring changes to ocular dominance (OD) in primary visual cortex (V1). Here we investigated how this experience-dependent plasticity is coordinated within the laminar circuitry of V1 by deleting separately in each cortical layer (L) a gene required to close the critical period, nogo-66 receptor (ngr1). Deleting ngr1 in excitatory neurons in L4, but not in L2/3, L5, or L6, prevented closure of the critical period, and adult mice remained sensitive to brief monocular deprivation. Intracortical disinhibition, but not thalamocortical disinhibition, accompanied this OD plasticity. Both juvenile wild-type mice and adult mice lacking ngr1 in L4 displayed OD plasticity that advanced more rapidly L4 than L2/3 or L5. Interestingly, blocking OD plasticity in L2/3 with the drug AM-251 did not impair OD plasticity in L5. We propose that L4 restricts disinhibition and gates OD plasticity independent of a canonical cortical microcircuit. •Deleting ngr1 in L4, but not L2/3, L5, or L6, sustains OD plasticity in adult mice•Intracortical, but not thalamocortical, disinhibition accompanies OD plasticity•Blocking plasticity in L2/3 with AM-251 does not affect plasticity in L4 or L5 Frantz et al. explore the regulation and propagation of experience-dependent plasticity within the laminar circuitry of visual cortex. Layer 4 limits intracortical disinhibition to close the critical period for OD plasticity throughout visual cortex. OD plasticity does not follow a canonical cortical microcircuit.
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These authors contributed equally to this work
The contributions are as follows: MGF, ECC, GS, XX, and AWM designed the study. MGF, ECC, GS, CES, and TI performed the experiments. CN assisted with data analysis. XX and AWM wrote the manuscript.
Author Contributions
ISSN:0960-9822
1879-0445
DOI:10.1016/j.cub.2020.05.067