Phenotypic Plasticity Confers Multiple Fitness Benefits to a Mimic

Animal communication is often deceptive; however, such dishonesty can become ineffective if it is used too often, is used out of context, or is too easy to detect [1–3]. Mimicry is a common form of deception, and most mimics gain the greatest fitness benefits when they are rare compared to their mod...

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Published in:Current biology 2015-03, Vol.25 (7), p.949-954
Main Authors: Cortesi, Fabio, Feeney, William E., Ferrari, Maud C.O., Waldie, Peter A., Phillips, Genevieve A.C., McClure, Eva C., Sköld, Helen N., Salzburger, Walter, Marshall, N. Justin, Cheney, Karen L.
Format: Article
Language:English
Subjects:
Adaptation, Physiological - physiology
Animals
Avoidance Learning - physiology
Biochemistry & Molecular Biology
Cell Biology
COLOR THRESHOLDS
COMMUNICATION
Coral Reefs
CORAL-REEF FISH
DECEPTION
EVOLUTION
Fishes
Phenotype
Pigmentation - physiology
POLYMORPHISM
Predatory Behavior - physiology
PREY
Pseudochromis
RECEPTOR NOISE
Species Specificity
Symbiosis - physiology
Zoologi
Zoology
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Summary:Animal communication is often deceptive; however, such dishonesty can become ineffective if it is used too often, is used out of context, or is too easy to detect [1–3]. Mimicry is a common form of deception, and most mimics gain the greatest fitness benefits when they are rare compared to their models [3, 4]. If mimics are encountered too frequently or if their model is absent, avoidance learning of noxious models is disrupted (Batesian mimicry [3]), or receivers become more vigilant and learn to avoid perilous mimics (aggressive mimicry [4]). Mimics can moderate this selective constraint by imperfectly resembling multiple models [5], through polymorphisms [6], or by opportunistically deploying mimetic signals [1, 7]. Here we uncover a novel mechanism to escape the constraints of deceptive signaling: phenotypic plasticity allows mimics to deceive targets using multiple guises. Using a combination of behavioral, cell histological, and molecular methods, we show that a coral reef fish, the dusky dottyback (Pseudochromis fuscus), flexibly adapts its body coloration to mimic differently colored reef fishes and in doing so gains multiple fitness benefits. We find that by matching the color of other reef fish, dottybacks increase their success of predation upon juvenile fish prey and are therefore able to deceive their victims by resembling multiple models. Furthermore, we demonstrate that changing color also increases habitat-associated crypsis that decreases the risk of being detected by predators. Hence, when mimics and models share common selective pressures, flexible imitation of models might inherently confer secondary benefits to mimics. Our results show that phenotypic plasticity can act as a mechanism to ease constraints that are typically associated with deception. [Display omitted] [Display omitted] •Fish mimics can flexibly change color to imitate multiple model species•Flexible mimicry increases predation success by preventing detection by prey•Changing color also increases protection by deceiving larger predatory fish•Phenotypic plasticity thus enables the continuous use of deceptive signals Cortesi et al. show that a predatory fish changes color to mimic various surrounding fishes. This prevents detection by prey, increasing predation success, and reduces detection by larger predators. Phenotypic plasticity is a novel strategy to maintain the effectiveness of deceptive signals.
ISSN:0960-9822
1879-0445
DOI:10.1016/j.cub.2015.02.013