Evaluating the effect of pelagic zooplankton community composition and density on larval walleye (Sander vitreus) growth with a bioenergetic-based foraging model

Abstract

We developed a bioenergetic-based foraging model to evaluate how the composition of the pelagic zooplankton community influences the growth of zooplanktivorous larval walleye (Sander vitreus). Our model incorporates field observations of pelagic zooplankton composition and density as well as size-specific prey preferences of larval walleye to simulate both foraging and consumption rates. The model was evaluated in four lakes in northern Wisconsin: two with invasive populations of rainbow smelt (Osmerus mordax) and two without populations of rainbow smelt. Invasive rainbow smelt are known to alter the composition of pelagic zooplankton communities as well as cause declines in walleye recruitment, thus providing a unique opportunity to evaluate our model. The results suggest that larval walleye growth is slowed in systems that lack high densities of large-bodied Daphnia. Such conditions may create an energetic bottleneck for larval walleye. This approach could easily be applied to other species that are also affected by rainbow smelt or more generally where success of larval foraging is suspected to have a large influence on year-class strength.