Diverse marsh plant communities are more consistently productive across a range of different environmental conditions through functional complementarity

Environmental stress changes the relationship between biodiversity and ecosystem functions, but the underlying mechanisms are poorly understood. Because species interactions shape biodiversity–ecosystem functioning relationships, changes in per capita interactions under stress (as predicted by the stress gradient hypothesis) can be an important driver of stress-induced changes in these relationships. To test this hypothesis, we measure productivity in microalgae communities along a diversity and herbicide gradient. On the basis of additive partitioning and a mechanistic community model, we demonstrate that changes in per capita interactions do not explain effects of herbicide stress on the biodiversity–productivity relationship. Instead, assuming that the per capita interactions remain unaffected by stress, causing species densities to only change through differences in stress tolerance, suffices to predict the stress-induced changes in the biodiversity–productivity relationship and community composition. We discuss how our findings set the stage for developing theory on how environmental stress changes biodiversity effects on ecosystem functions.

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“…Confirming other studies7913141516, we found that envionmental stress changed the biodiversity–ecosystem function relationship (Fig. 1, Table 1).…”

Section: Discussionsupporting

confidence: 91%

Per capita interactions and stress tolerance drive stress-induced changes in biodiversity effects on ecosystem functions

et al. 2016

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“…In general, complementarity is fundamental in explaining stability and resilience in highly diverse systems ( Fig. 3; Cardinale et al, 2007;Steudel et al, 2011). However, increased trait diversity cannot be assumed to always be associated with community stability (Loreau & Behera, 1999).…”

Section: Mechanisms For Plant Community Resiliencementioning

confidence: 99%

Extreme climate events and wet grasslands: plant traits for ecological resilience

Brotherton

Joyce

2014

Hydrobiologia

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Extreme climate events, including floods and droughts, represent disturbances that impact plant functioning, biodiversity and ecosystem processes. Wetlands can mediate climate change impacts through their multiple ecosystem services, and wet grasslands offer a fascinating wetland case because they are adapted to regular disturbance regimes typified by inundation, cutting and/or grazing. This review identifies key concepts for a better understanding of extreme climate impacts on wet grassland plant communities, focussing upon the use of functional traits for ecological resilience. It suggests that wet grasslands are underrepresented in extreme climate event experiments, despite some field studies that show floods have significant impacts upon community composition. Mechanisms for ecological stability and resilience are linked to functional diversity through plant traits, via niche complementarity or dominance. Facilitation may be important as climate stresses increase, while modified plant behaviour may promote recovery. However, plant community responses to extreme events are complex; the challenges for wet grassland researchers include: (i) identifying thresholds, tipping points and lag effects; (ii) monitoring key community components; (iii) using effective plant trait metrics; (iv) investigating beyond conservative norms; (v) combining multiple stressors and traits and (vi) extrapolating experimental results to field conditions.

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“…In aquatic systems positive biodiversity effects were observed in manipulation experiments, i.e., experiments in which biodiversity was artificially manipulated to simulate species loss or artificial communities, with higher plants [20,32,33], macroalgae [34][35][36][37][38], and microalgae [22,[39][40][41][42]. Manipulation experiments with species from oceanic systems show a positive biodiversity-ecosystem functioning effect for primary producers, i.e., plants and algae [33].…”

Section: General Questions Applied On Microalgae Models Ecosystem Funmentioning

confidence: 99%

“…Ecosystems can be stressed to some degree without direct destruction of the functioning of the system, but a decrease of functioning was found in several systems [19][20][21][22].…”

mentioning

confidence: 99%

Journal of Oceanography and Marine Research

Steudel¹

2014

J Oceanogr Mar Res

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Diverse marsh plant communities are more consistently productive across a range of different environmental conditions through functional complementarity

Cited by 25 publications

References 41 publications

Per capita interactions and stress tolerance drive stress-induced changes in biodiversity effects on ecosystem functions

Per capita interactions and stress tolerance drive stress-induced changes in biodiversity effects on ecosystem functions

Extreme climate events and wet grasslands: plant traits for ecological resilience

Journal of Oceanography and Marine Research

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