Relative Telencephalon Size Does Not Affect Collective Motion in the Guppy ()

Overview

Journal Behav Ecol

Publisher Oxford University Press

Date 2024 May 23

PMID 38779596

Authors

Annika Boussard

Mikaela Ahlkvist

Alberto Corral-Lopez

Stephanie Fong

John Fitzpatrick

Niclas Kolm

Affiliations

Soon will be listed here.

Abstract

Collective motion is common across all animal taxa, from swarming insects to schools of fish. The collective motion requires intricate behavioral integration among individuals, yet little is known about how evolutionary changes in brain morphology influence the ability for individuals to coordinate behavior in groups. In this study, we utilized guppies that were selectively bred for relative telencephalon size, an aspect of brain morphology that is normally associated with advanced cognitive functions, to examine its role in collective motion using an open-field assay. We analyzed high-resolution tracking data of same-sex shoals consisting of 8 individuals to assess different aspects of collective motion, such as alignment, attraction to nearby shoal members, and swimming speed. Our findings indicate that variation in collective motion in guppy shoals might not be strongly affected by variation in relative telencephalon size. Our study suggests that group dynamics in collectively moving animals are likely not driven by advanced cognitive functions but rather by fundamental cognitive processes stemming from relatively simple rules among neighboring individuals.

Citing Articles

Relative telencephalon size does not affect collective motion in the guppy ().

Boussard A, Ahlkvist M, Corral-Lopez A, Fong S, Fitzpatrick J, Kolm N Behav Ecol. 2024; 35(4):arae033.

PMID: 38779596 PMC: 11110457. DOI: 10.1093/beheco/arae033.

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