Abstract
Prey organisms often use multiple sensory cues to gain reliable information about imminent predation threat. In this study we test if a freshwater fish increases the reliance on supplementary cues when the reliability of the primary cue is reduced. Fish commonly use vision to evaluate predation threat, but may also use chemical cues from predators or injured conspecifics. Environmental changes, such as increasing turbidity or water colour, may compromise the use of vision through changes in the optical properties of water. In an experiment we tested if changes in optical conditions have any effects on how crucian carp respond to chemical predator cues. In turbidity treatments we added either clay or algae, and in a brown water colour treatment we added water with a high humic content. We found that carp reduced activity in response to predator cues, but only in the turbidity treatments (clay, algae), whereas the response in the brown water treatment was intermediate, and not significantly different from, clear and turbid water treatments. The increased reliance on chemical cues indicates that crucian carp can compensate for the reduced information content from vision in waters where optical conditions are degraded. The lower effect in brown water may be due to the reduction in light intensity, changes in the spectral composition (reduction of UV light) or to a change in chemical properties of the cue in humic waters.
Highlights
Predation is an important structuring force in freshwater ecosystems and acts as a strong selection pressure for antipredator adaptations in prey organisms
Addition of predator cue resulted in a significant reduction in crucian carp swimming activity in clay (t9 = 23.090, p = 0.013), algae (t9 = 29.395, p,0.001) and brown water (t9 = 22.495, p = 0.034), while no change in activity was detected in the clearwater control (t9 = 20.261, p = 0.800, Fig. 2)
In this study we found a significant reduction in the activity of crucian carp in response to chemical cues from a pike predator
Summary
Predation is an important structuring force in freshwater ecosystems and acts as a strong selection pressure for antipredator adaptations in prey organisms. The sensory compensation model, Hartman and Abrahams [17] assumed that fish primarily use visual cues to evaluate predation threat and suggested that the threshold of alarm cue concentration necessary to elicit a behavioural response was dependent on predation risk and the quality of the visual information. They predicted that the threshold concentration should decrease in response to reduced visual information when risk of predation was low, and in an experiment with fathead minnows they were able to show that at low risk minnows displayed fright behaviours in response to chemical cues only when the information from visual cues was reduced due to increasing turbidity (created by adding clay)
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