Litcius/Paper detail

Connectomic analysis of thalamus-driven disinhibition in cortical layer 4

Yunfeng Hua, Sahil Loomba, Verena Pawlak, Kay-Michael Voit, Philip Laserstein, Kevin M. Boergens, Damian J. Wallace, Jason N. D. Kerr, Moritz Helmstaedter

2022Cell Reports29 citationsDOIOpen Access PDF

Abstract

Sensory signals are transmitted via the thalamus primarily to layer 4 (L4) of the primary sensory cortices. While information about average neuronal connectivity in L4 is available, its detailed higher-order circuit structure is not known. Here, we used three-dimensional electron microscopy for a connectomic analysis of the thalamus-driven inhibitory network in L4. We find that thalamic input drives a subset of interneurons with high specificity, which in turn target excitatory neurons with subtype specificity. These interneurons create a directed disinhibitory network directly driven by the thalamic input. Neuronal activity recordings show that strong synchronous sensory activation yields about 1.5-fold stronger activation of star pyramidal cells than spiny stellates, in line with differential windows of opportunity for activation of excitatory neurons in the thalamus-driven disinhibitory circuit model. With this, we have identified a high degree of specialization of the microcircuitry in L4 of the primary sensory cortex.

Topics & Concepts

ThalamusDisinhibitionNeuroscienceLayer (electronics)Functional connectivityBiologyComputer sciencePsychologyChemistryOrganic chemistryNeural dynamics and brain functionNeuroscience and Neural EngineeringPhotoreceptor and optogenetics research