Plant secondary metabolites: a key driver of litter decomposition and soil nutrient cycling

• Published in: The Journal of ecology Vol. 104; no. 6; pp. 1527 - 1541
• Main Authors: Chomel, Mathilde, Guittonny-Larchevêque, Marie, Fernandez, Catherine, Gallet, Christiane, DesRochers, Annie, Paré, David, Jackson, Benjamin G., Baldy, Virginie
• Format: Journal Article
• Language: English
• Published: Oxford John Wiley & Sons Ltd 01.11.2016; Blackwell Publishing Ltd; Wiley
• Subjects: Biodiversity and Ecology; biogeochemical cycles; Decomposition; Ecological function; Ecological succession; ecosystem processes; Ecosystems; Environmental changes; Environmental Sciences; ESSAY REVIEW; functional traits; Litter; litter decomposition; Metabolites; Nutrient cycles; phenolic compounds; Plant ecology; plant–soil (below‐ground) interactions; Secondary metabolites; soil; soil biota; Soil nutrients; soil organisms; Soils; tannins; terpenes
• ISSN: 0022-0477; 1365-2745
• DOI: 10.1111/1365-2745.12644

1. A broad and diversified group of compounds, secondary metabolites, are known to govern species interactions in ecosystems. Recent studies have shown that secondary metabolites can also play a major role in ecosystem processes, such as plant succession or in the process of litter decomposition, by governing the interplay between plant matter and soil organisms. 2. We reviewed the ecological role of the three main classes of secondary metabolites and the methodological challenges and novel avenues for their study. We highlight emerging general patterns of the impacts of secondary metabolites on decomposer communities and litter decomposition and argue for the consideration of secondary compounds as key drivers of soil functioning and ecosystem functioning. 3. Synthesis. Gaining a greater understanding of plant–soil organisms relationships and underlying mechanisms, including the role of secondary metabolites, could improve our ability to understand ecosystem processes. We outline some promising directions for future research that would stimulate studies aiming to understand the interactions of secondary metabolites across a range of spatio-temporal scales. Detailed mechanistic knowledge could help us to develop models for the process of litter decomposition and nutrient cycling in ecosystems and help us to predict future impacts of global changes on ecosystem functioning.