Metabolites Limiting Predator Growth Wane with Prey Biodiversity

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2024 Dec 17

PMID 39689178

Authors

Gen Li

Ting Liu

Wangliang Xie

Zhenzhen Liu

Huixin Li

Joann K Whalen

Alexandre Jousset

Zhong Wei

Affiliations

Soon will be listed here.

Abstract

Predator-prey interactions are a major driver of microbiome dynamics, but remain difficult to predict. While several prey traits potentially impact resistance to predation, their effects in a multispecies context remain unclear. Here, we leverage synthetic bacterial communities of varying complexity to identify traits driving palatability for nematodes, a main consumer of bacteria in soil. We assessed trophic interactions between four nematode species and 122 bacterial isolates, across a gradient of prey biodiversity ranging from single species to 50 species. Nematode size, a proxy for prey palatability, varied strongly with prey community composition and could be predicted by metabolic and morphological properties of the prey. However, the influence of prey traits on predators depended on biodiversity. Secondary metabolites drove palatability in monoculture, but this effect vanished under increasing prey biodiversity, where prey size became the dominant predictors of nematode size. Although idiosyncratic properties are often emphasized in the literatures, our results suggest that in biodiverse assemblages, the composition of available prey and their traits are more reliable predictors of predator-prey interactions. This study offers valuable insights into microbial ecology in the context of predator-prey interactions, as cryptic microbial responses can be guided by deductions based on generalizable biological traits.

Citing Articles

Metabolites limiting predator growth wane with prey biodiversity.

Li G, Liu T, Xie W, Liu Z, Li H, Whalen J Proc Natl Acad Sci U S A. 2024; 121(52):e2410210121.

PMID: 39689178 PMC: 11670093. DOI: 10.1073/pnas.2410210121.

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