Effects of Biodiversity Loss on Freshwater Ecosystem Functions Increase With the Number of Stressors

Journal article

A multitude of anthropogenic stressors drive biodiversity loss and alter ecosystem functioning. Freshwaters, which contribute disproportionally to global biodiversity and biogeochemical cycles, are particularly threatened. Although the relationship between biodiversity and ecosystem functions (BEF) is generally well‐established, especially in terrestrial ecosystems, the role of multiple, co‐occurring stressors in modulating the relationship remains unclear. We conducted a meta‐analysis to address this knowledge gap by assessing the effect of multiple stressors on the relationship between taxon richness and four measures of ecosystem function. The relationship was generally positive, with the slope becoming steeper as the number of stressors increased, suggesting that exposure to multiple stressors exacerbates impacts of biodiversity loss on ecosystem function. Multiple stressor effects on both taxon richness and ecosystem functions were largely predictable from individual stressor effects, although antagonistic effects on ecosystem functions emerged in 14% of the considered cases. The type of stressor and ecosystem function, along with taxonomic group, exerted no influence on the BEF relationship, contrary to our expectations. Microbial production and biomass declined most strongly in response to stressors, despite notable variability. Overall, our findings imply that functional consequences of freshwater biodiversity loss are more severe under multifaceted environmental change than previously assumed.

Authors: Schäfer, RB; Baikova, D; Bayat, HS; Beermann, AJ; Berger, SA

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: Wiley
• Journal: Global Change Biology
• Volume: 31
• Issue: 11
• Article number: e70617
• Publication date: 2025-11-26
• Acceptance date: 2025-11-11
• DOI: 10.1111/gcb.70617
• EISSN: 1365-2486
• ISSN: 1354-1013
• Language: English
• Keywords: ecosystem processes; rivers; litter breakdown; leaf decomposition; multiple stressors; global change; productivity; communities; environmental drivers