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Abstract Predators can strongly influence disease transmission and evolution, particularly when they prey selectively on infected hosts. Although selective predation has been observed in numerous systems, why predators select infected prey remains poorly understood. Here, we use a mathematical model of predator vision to test a long‐standing hypothesis about the mechanistic basis of selective predation in a
Daphnia –microparasite system, which serves as a model for the ecology and evolution of infectious diseases. Bluegill sunfish feed selectively onDaphnia infected by a variety of parasites, particularly in water uncolored by dissolved organic carbon. The leading hypothesis for selective predation in this system is that infection‐induced changes in the transparency ofDaphnia render them more visible to bluegill. Rigorously evaluating this hypothesis requires that we quantify the effect of infection on the visibility of prey from the predator's perspective, rather than our own. Using a model of the bluegill visual system, we show that three common parasites,Metschnikowia bicuspidata ,Pasteuria ramosa , andSpirobacillus cienkowskii , decrease the transparency ofDaphnia , rendering infectedDaphnia darker against a background of bright downwelling light. As a result of this increased brightness contrast, bluegill can see infectedDaphnia at greater distances than uninfectedDaphnia —between 19% and 33% further, depending on the parasite.Pasteuria andSpirobacillus also increase the chromatic contrast ofDaphnia . These findings lend support to the hypothesis that selective predation by fish on infectedDaphnia could result from the effects of infection onDaphnia 's visibility. However, contrary to expectations, the visibility ofDaphnia was not strongly impacted by water color in our model. Our work demonstrates that models of animal visual systems can be useful in understanding ecological interactions that impact disease transmission. -
A genetic colour polymorphism is present in bluefin killifish
, where red and yellow anal‐fin morphs coexist in clear springs, but the source of balancing selection is unknown. In a field study, vertical distributions did not differ between the morphs and there was little evidence that light environments differed qualitatively over the 200 cm at which fish were collected. A greenhouse study showed that both morphs preferred to spawn at shallow depths and hence vertical distribution and spawning site choice are unlikely to explain the maintenance of the colour polymorphism.Lucania goodei