Excitation Creates a Distributed Pattern of Cortical Suppression Due to Varied Recurrent Input

Overview

Journal Neuron

Publisher Cell Press

Specialty Neurology

Date 2023 Oct 21

PMID 37865083

Authors

Jonathan F ORawe

Zhishang Zhou

Anna J Li

Paul K LaFosse

Hannah C Goldbach

Mark H Histed

Affiliations

Soon will be listed here.

Abstract

Dense local, recurrent connections are a major feature of cortical circuits, yet how they affect neurons' responses has been unclear, with some studies reporting weak recurrent effects, some reporting amplification, and others indicating local suppression. Here, we show that optogenetic input to mouse V1 excitatory neurons generates salt-and-pepper patterns of both excitation and suppression. Responses in individual neurons are not strongly predicted by that neuron's direct input. A balanced-state network model reconciles a set of diverse observations: the observed dynamics, suppressed responses, decoupling of input and output, and long tail of excited responses. The model shows recurrent excitatory-excitatory connections are strong and also variable across neurons. Together, these results demonstrate that excitatory recurrent connections can have major effects on cortical computations by shaping and changing neurons' responses to input.

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