Revealing the structure of information flows discriminates similar animal social behaviors

• Published in: eLife Vol. 9
• Main Authors: Valentini, Gabriele, Mizumoto, Nobuaki, Pratt, Stephen C, Pavlic, Theodore P, Walker, Sara I
• Format: Journal Article
• Language: English
• Published: England eLife Science Publications, Ltd 30.07.2020; eLife Sciences Publications, Ltd; eLife Sciences Publications Ltd
• Subjects: Analysis; Animal behavior; Animal Communication; Animals; Ants - physiology; Behavior, Animal; Communications protocols; coptotermes formosanus; Ecology; Ethology - methods; Information management; information theory; Isoptera - physiology; Physics of Living Systems; reticulitermes speratus; Social aspects; Social Behavior; temnothorax rugatulus; Termites; ecology; social behavior; temnothorax rugatulus; coptotermes formosanus; information theory; physics of living systems; reticulitermes speratus
• ISSN: 2050-084X; 2050-084X
• DOI: 10.7554/eLife.55395

Behavioral correlations stretching over time are an essential but often neglected aspect of interactions among animals. These correlations pose a challenge to current behavioral-analysis methods that lack effective means to analyze complex series of interactions. Here we show that non-invasive information-theoretic tools can be used to reveal communication protocols that guide complex social interactions by measuring simultaneous flows of different types of information between subjects. We demonstrate this approach by showing that the tandem-running behavior of the ant Temnothorax rugatulus and that of the termites Coptotermes formosanus and Reticulitermes speratus are governed by different communication protocols. Our discovery reconciles the diverse ultimate causes of tandem running across these two taxa with their apparently similar signaling mechanisms. We show that bidirectional flow of information is present only in ants and is consistent with the use of acknowledgement signals to regulate the flow of directional information. Social animals continuously influence each other’s behavior. Most of these interactions simply consist in an individual immediately responding to the behavior of another in a predictable way. Still, when the same individuals interact over long periods, complex social interactions can arise. These can be difficult for scientists to study, because how animals behave at a given moment depends on their shared history. Certain species of ants and termites use smell and touch to do ‘tandem runs’ and move in pairs through the environment. Only ants, however, can learn a new route from their running partner. Understanding how this difference arises means examining how the animals interact and communicate over longer time scales. This requires new approaches to capture how information flows between the insects. Here, Valentini et al. used a scientific methodology known as information theory to study tandem running in one species of ants and two species of termites. Information theory provides a framework to quantify how information is shared, processed and stored. The flow of information between individuals was measured separately for different aspects of tandem running. At small time scales, ant and termite behavior appeared identical, but over longer periods, it was possible to distinguish between the two types of insects. In termites, only one individual in a pair sent information to the other to instruct the second termite where to go. By contrast, in ants, both members of the tandem communicated with each other in a way that was consistent with how humans acknowledge information they receive from other individuals. The approach used by Valentini et al. will be useful to researchers who study how complex and often cryptic social interactions develop over extended periods in social animals. This framework could also be applied in other systems such as groups of cells, or economic networks.