Development of Neural Circuits for Social Motion Perception in Schooling Fish

Overview

Journal Curr Biol

Publisher Cell Press

Specialty Biology

Date 2024 Jul 18

PMID 39025069

Authors

David Zada

Lisanne Schulze

Jo-Hsien Yu

Princess Tarabishi

Julia L Napoli

Jimjohn Milan

Matthew Lovett-Barron

Affiliations

Soon will be listed here.

Abstract

The collective behavior of animal groups emerges from the interactions among individuals. These social interactions produce the coordinated movements of bird flocks and fish schools, but little is known about their developmental emergence and neurobiological foundations. By characterizing the visually based schooling behavior of the micro glassfish Danionella cerebrum, we found that social development progresses sequentially, with animals first acquiring the ability to aggregate, followed by postural alignment with social partners. This social maturation was accompanied by the development of neural populations in the midbrain that were preferentially driven by visual stimuli that resemble the shape and movements of schooling fish. Furthermore, social isolation over the course of development impaired both schooling behavior and the neural encoding of social motion in adults. This work demonstrates that neural populations selective for the form and motion of conspecifics emerge with the experience-dependent development of collective movement.

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