Fine-grained Descending Control of Steering in Walking

Overview

Journal bioRxiv

Date 2023 Oct 31

PMID 37904997

Authors

Helen H Yang

Luke E Brezovec

Laia Serratosa Capdevila

Quinn X Vanderbeck

Atsuko Adachi

Richard S Mann

Rachel I Wilson

Affiliations

Soon will be listed here.

Abstract

Locomotion involves rhythmic limb movement patterns that originate in circuits outside the brain. Purposeful locomotion requires descending commands from the brain, but we do not understand how these commands are structured. Here we investigate this issue, focusing on the control of steering in walking . First, we describe different limb "gestures" associated with different steering maneuvers. Next, we identify a set of descending neurons whose activity predicts steering. Focusing on two descending cell types downstream from distinct brain networks, we show that they evoke specific limb gestures: one lengthens strides on the outside of a turn, while the other attenuates strides on the inside of a turn. Notably, a single descending neuron can have opposite effects during different locomotor rhythm phases, and we identify networks positioned to implement this phase-specific gating. Together, our results show how purposeful locomotion emerges from brain cells that drive specific, coordinated modulations of low-level patterns.

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