RT Journal Article SR Electronic T1 Contrasting stripes are a widespread feature of group living in birds, mammals and fishes JF bioRxiv FD Cold Spring Harbor Laboratory SP 2020.04.20.050245 DO 10.1101/2020.04.20.050245 A1 Juan J. Negro A1 Jorge Doña A1 M. del Carmen Blázquez A1 Airam Rodríguez A1 James E. Herbert-Read A1 M. de L. Brooke YR 2020 UL http://biorxiv.org/content/early/2020/05/26/2020.04.20.050245.abstract AB Grouping is a widespread form of predator defense, with individuals in groups often performing evasive collective movements in response to predators’ attacks. Individuals in these groups use behavioral rules to coordinate their movements, with visual cues about neighbors’ positions and orientations informing movement decisions. Although the exact visual cues individuals use to coordinate their movements with neighbors have not yet been decoded, some studies have suggested that stripes, lines or other body patterns may act as conspicuous conveyors of movement information that could promote coordinated group movement, or promote dazzle camouflage, thereby confusing predators. We used phylogenetic logistic regressions to test whether the contrasting achromatic stripes present in four different taxa vulnerable to predation, including species within two orders of birds (Anseriformes and Charadriiformes), a suborder of Artiodactyla (the ruminants) and several orders of marine fish (predominantly Perciformes) were associated with group living. Contrasting patterns were significantly more prevalent in social species, and tended to be absent in solitary species or species less vulnerable to predation. We suggest that stripes taking the form of light-colored lines on dark backgrounds, or vice versa, provide a widespread mechanism across taxa that serves either to inform conspecifics of neighbors’ directional movement, or to confuse predators, when moving in groups. Detection and processing of patterns and of motion in the visual channel is essentially colourblind. That diverse animal taxa with widely different vision systems (including di-, tri- and tetrachromats) appear to have converged on a similar use of achromatic patterns is therefore expected given signal-detection theory. This hypothesis would explain the convergent evolution of conspicuous achromatic patterns as an antipredator mechanism in numerous vertebrate species.Competing Interest StatementThe authors have declared no competing interest.