Multi-elemental consumer-driven nutrient cycling when predators feed on different prey

Predators play a fundamental role in cycling nutrients through ecosystems, by altering the amount and compositions of waste products and uneaten prey parts available to decomposers. Different prey can vary in their elemental content and the deposition of elements in predator waste can vary depending on which elements are preferentially retained versus eliminated as waste products. We tested how feeding on different prey (caterpillars, cockroaches, crickets, and flies) affected the concentrations of 23 elements in excreta deposited by wolf spider across 2 seasons (spring versus fall). Spider excreta had lower concentrations of carbon and higher concentrations of many other elements (Al, B, Ba, K, Li, P, S, Si, and Sr) compared to prey remains and whole prey carcasses. In addition, elemental concentrations in unconsumed whole prey carcasses and prey remains varied between prey species, while spider excreta had the lowest variation among prey species. Finally, the concentrations of elements deposited differed between seasons, with wolf spiders excreting greater concentrations of Fe, Mg, Mn, Mo, S, and V in the fall. However, in the spring, spiders excreted higher concentrations of Al, B, Ba, Ca, Cd, Cu, K, P, Na, Si, Sr, and Zn. These results highlight that prey identity and environmental variation can determine the role that predators play in regulating the cycling of many elements. A better understanding of these convoluted nutritional interactions is critical to disentangle specific consumer-driven effects on ecosystem function.

Automated summary

Predators have a significant impact on nutrient cycling in ecosystems by modifying waste products and uneaten parts of prey available to decomposers. Feeding on different prey influenced the elemental concentrations in wolf spider excreta, with lower carbon concentrations and higher concentrations of other elements. Elemental concentrations in unconsumed prey carcasses and remains varied between prey species, while spider excreta had the lowest variation among prey species. Additionally, the deposition of elements differed between seasons, with higher concentrations of certain elements in spider excreta in the fall and higher concentrations of other elements in the spring. Understanding these complex nutritional interactions is crucial for understanding the effects of predators on ecosystem function.