Abstract
In aquatic environments, prey perceive predator threats by chemical cues called kairomones, which can induce changes in their morphology, life histories, and behavior. Predator‐induced defenses have allowed for prey, such as Daphnia pulex, to avert capture by common invertebrate predators, such as Chaoborus sp. larvae. However, the influence of additional stressors, such as ultraviolet radiation (UVR), on the Daphnia–Chaoborus interaction is not settled as UVR may for instance deactivate the kairomone. In laboratory experiments, we investigated the combined effect of kairomones and UVR at ecologically relevant levels on induced morphological defenses of two D. pulex clones. We found that kairomones were not deactivated by UVR exposure. Instead, UVR exposure suppressed induced morphological defense traits of D. pulex juveniles under predation threat by generally decreasing the number of neckteeth and especially by decreasing the size of the pedestal beneath the neckteeth. UVR exposure also decreased the body length, body width, and tail spine length of juveniles, likely additionally increasing the vulnerability to Chaoborus predation. Our results suggest potential detrimental effects on fitness and survival of D. pulex subject to UVR stress, with consequences on community composition and food web structure in clear and shallow water bodies.
Highlights
Studies on predator–prey dynamics have provided powerful insights into the ability of prey organisms to respond and adapt to predators by morphological, behavioral, or life-history responses (Dodson, 1989; Ghalambor et al, 2015; Hammill et al, 2008)
Our first experiment showed that the prepared Chaoborus kairomone extract was effective in inducing neckteeth and pedestals in the 2nd instar of the D. pulex UNI clone (Figure 2, Appendix: Figure A1) as there was a significant difference between treatments receiving kairomone (i.e., photosynthetically active radiation (PAR) and ultraviolet radiation (UVR) treatments) and the control that received no kairomones (Appendix: Table A1)
Our results show that UVR, in the intensity, wavelengths, and duration applied, did not denature kairomones to levels that influenced the effectivity in inducing morphological defense traits
Summary
Studies on predator–prey dynamics have provided powerful insights into the ability of prey organisms to respond and adapt to predators by morphological, behavioral, or life-history responses (Dodson, 1989; Ghalambor et al, 2015; Hammill et al, 2008). Recorded costs of neckteeth induction include longer development time for offspring, reduced survival, and reduced reproductive success (Hammill et al, 2008; Riessen, 2012; Tollrian, 1995) Such costs could lead to greater vulnerability to other environmental stressors and impose trade-offs. Sterr and Sommaruga (2008) have shown that strong UVR exposure can degrade the Chaoborus kairomones, rendering the chemical cue ineffective in inducing defensive traits in D. pulex. The relevance of this mechanism in natural systems is unclear as kairomones are constantly produced when the predator is present. Algal suspensions were estimated from photometric light extinction (800 nm, Shimadzu UV 160-A, Japan) using a previously determined carbon-light extinction conversion equation
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