Abstract
Animals in groups obtain information from their social partners to engage in collective behavior(1-4). Social information transmission has been observed amongst individuals in fish schools(5-8), bird flocks(9,10), and human groups(11,12), but the neural mechanisms for detecting socially transmitted information are poorly understood(4,13-15). By studying the schooling glassfish Danionella cerebrum (16-18), here we demonstrate that escape from danger is enhanced by visual perception of other escaping fish. We found that neural populations in the midbrain optic tectum(19-21) and dorsal thalamus(22,23) are activated by the rapid escape of social partners. These neurons are also driven by the sudden disappearance of virtual social partners, yet unaffected by disappearing stimuli without social relevance. Virtual fish schools that escape or disappear were sufficient to cause observers to escape, even in the absence of direct threats. These results demonstrate that rapid "social-off" detection in visual circuits enables the detection of socially transmitted threat information, which may be a particularly effective strategy for animals capable of rapid movement but limited visual range(17,24). These results show how neural computations in individuals enables rapid information sharing in animal collectives(4,15).