Abstract
Group or population level self-organised systems comprise many individuals displaying group-level emergent properties. Current theory indicates that individual-level behaviours have an effect on the final group-level behaviour; that is, self-organised systems are sensitive to small changes in individual behaviour. Here we examine a self-organised behaviour in relation to environmentally-driven individual-level changes in behaviour, using both natural systems and computer simulations. We demonstrate that aggregations of intertidal snails slightly decrease in size when, owing to hotter and more desiccating conditions, individuals forage for shorter periods – a seemingly non-adaptive behaviour for the snails since aggregation reduces desiccation stress. This decrease, however, only occurs in simple experimental systems (and simulations of these systems). When studied in their natural and more complex environment, and simulations of such an environment, using the same reduced foraging time, no difference in aggregation behaviour was found between hot and cool days. These results give an indication of how robust self-organised systems are to changes in individual-level behaviour. The complexity of the natural environment and the interactions of individuals with this environment, therefore, can result in self-organised systems being more resilient to individual-level changes than previously assumed.
Highlights
Self-organised systems are frequently considered sensitive to changes in the individual-level behaviours of organisms that comprise the systems [1,2]
In this study we test the effects of increased desiccation stress on the ability of snails to form aggregations, using natural systems, simplified experimental treatments, and computer simulations of the natural and experimental systems
Natural shore study Desiccation rate differed significantly between the different temperature conditions, significant differences were observed between replicate days within the same conditions (Table 1)
Summary
Self-organised systems are frequently considered sensitive to changes in the individual-level behaviours of organisms that comprise the systems [1,2]. Self-organisation of aggregation behaviour has been documented in species of highshore littorinid snails [11,12,13], and simulation models of these snails have been validated on data collected from natural shores [12]. This system, provides an excellent opportunity to test predictions on naturally-occurring changes in individual-level behaviour, and the resultant, group-level, self-organised distributions that form under different environmental conditions. In this study we test the effects of increased desiccation stress on the ability of snails to form aggregations, using natural systems (rocky shores on hot and cool days), simplified experimental treatments (artificial rock slabs with roofs to decrease desiccation stress), and computer simulations of the natural and experimental systems
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