Understanding context dependency in the response of forest understorey plant communities to nitrogen deposition

Perring, Michael P.; Diekmann, Martin; Midolo, Gabriele; Costa, David Schellenberger; Bernhardt‐Römermann, Markus; Otto, Johanna; Gilliam, Frank S.; Hedwall, Per‐Ola; Nordin, Annika; Dirnböck, Thomas; Simkin, Samuel M.; Máliš, František; Blondeel, Haben; Brunet, Jörg; Chudomelová, Markéta; Durak, Tomasz; Frenne, Pieter De; Hédl, Radim; Kopecký, Martin; Landuyt, Dries; Li, Daijiang; Manning, Peter; Petřík, Petr; Reczyńska, Kamila; Schmidt, Wolfgang; Standovár, Tibor; Świerkosz, Krzysztof; Vild, Ondřej; Waller, Donald M.; Verheyen, Kris

doi:10.1016/j.envpol.2018.07.089

Cited by 54 publications

(45 citation statements)

References 99 publications

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“…This lack of interaction on the short term does not imply that such interactive effects are not important to understorey community development in response to global change. It rather shows the complementary of experimental research to long‐term vegetation resurveys (Perring, Bernhardt‐Römermann, et al, ; Perring, Diekmann, et al, ; Verstraeten et al, ) or mechanistic modelling approaches (Dirnböck et al, ; Landuyt et al, ). Long‐term experiments, vegetation resurveys and modelling are perhaps better suited to unravel such long‐term interactive effects between global change drivers on understorey communities (Luo et al, ; Verheyen et al, ).…”

Section: Discussionmentioning

confidence: 99%

Light and warming drive forest understorey community development in different environments

Blondeel

Perring

Depauw

et al. 2020

Global Change Biology

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Plant community composition and functional traits respond to chronic drivers such as climate change and nitrogen (N) deposition. In contrast, pulse disturbances from ecosystem management can additionally change resources and conditions. Community responses to combined environmental changes may further depend on land‐use legacies. Disentangling the relative importance of these global change drivers is necessary to improve predictions of future plant communities. We performed a multifactor global change experiment to disentangle drivers of herbaceous plant community trajectories in a temperate deciduous forest. Communities of five species, assembled from a pool of 15 forest herb species with varying ecological strategies, were grown in 384 mesocosms on soils from ancient forest (forested at least since 1850) and postagricultural forest (forested since 1950) collected across Europe. Mesocosms were exposed to two‐level full‐factorial treatments of warming, light addition (representing changing forest management) and N enrichment. We measured plant height, specific leaf area (SLA) and species cover over the course of three growing seasons. Increasing light availability followed by warming reordered the species towards a taller herb community, with limited effects of N enrichment or the forest land‐use history. Two‐way interactions between treatments and incorporating intraspecific trait variation (ITV) did not yield additional inference on community height change. Contrastingly, community SLA differed when considering ITV along with species reordering, which highlights ITV’s importance for understanding leaf morphology responses to nutrient enrichment in dark conditions. Contrary to our expectations, we found limited evidence of land‐use legacies affecting community responses to environmental changes, perhaps because dispersal limitation was removed in the experimental design. These findings can improve predictions of community functional trait responses to global changes by acknowledging ITV, and subtle changes in light availability. Adaptive forest management to impending global change could benefit the restoration and conservation of understorey plant communities by reducing the light availability.

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Section: Discussionmentioning

confidence: 99%

Light and warming drive forest understorey community development in different environments

Blondeel

Perring

Depauw

et al. 2020

Global Change Biology

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“…The responses of plant communities to N deposition vary depending on the environmental context (Perring, Diekmann, et al, ; Simkin et al, ; Vellend et al, ). Modifying factors include the amount and duration of N deposition, which determine the cumulative N input over time (Bernhardt‐Römermann et al, ; Duprè et al, ); soil pH and acid‐neutralizing capacity (Clark et al, ; Simkin et al, ); the chemical forms of N input (Stevens et al, ); environmental conditions, such as climate (Clark et al, ; Humbert, Dwyer, Andrey, & Arlettaz, ; Limpens et al, ); and vegetation types (Pardo et al, ; Simkin et al, ).…”

Section: Introductionmentioning

confidence: 99%

Impacts of nitrogen addition on plant species richness and abundance: A global meta‐analysis

Midolo

Alkemade

Schipper

et al. 2018

Global Ecol Biogeogr

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Aim Experimental nitrogen (N) addition (fertilization) studies are commonly used to quantify the impacts of increased N inputs on plant biodiversity. However, given that plant community responses can vary considerably among individual studies, there is a clear need to synthesize and generalize findings with meta‐analytical approaches. Our goal was to quantify changes in species richness and abundance in plant communities in response to N addition across different environmental contexts, while controlling for different experimental designs. Location Global. Time period Data range: 1985–2016; Publication years: 1990–2018. Major taxa studied Plants. Methods We performed a meta‐analysis of 115 experiments reported in 85 studies assessing the effects of N addition on terrestrial natural and semi‐natural plant communities. We quantified local‐scale changes in plant biodiversity in relationship to N addition using four metrics: species richness (SR), individual species abundance (IA), mean species abundance (MSA) and geometric mean abundance (GMA). Results For all metrics, greater amounts of annual N addition resulted in larger declines in plant diversity. Additionally, MSA decreased more steeply with N that was applied in reduced (NH4+) rather than oxidized (NO3-) form. Loss of SR with increasing amounts of N was found to be larger in warmer sites. Furthermore, greater losses of SR were found in sites with longer experimental durations, smaller plot sizes and lower soil cation exchange capacity. Finally, reductions in the abundance of individual species were larger for N‐sensitive plant life‐form types (legumes and non‐vascular plants). Main conclusions N enrichment decreases both SR and abundance of plants in N‐addition experiments, but the magnitude of the response differs among biodiversity metrics and with the environmental and experimental context. This underlines the importance of integrating multiple dimensions of biodiversity and relevant modifying factors into assessments of biodiversity responses to global environmental change.

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“…Furthermore, global change drivers can drive changes in plant communities through altering local resource availabilities, e.g . soil nitrogen or phosphorus; and local resources and conditions can, vice versa , determine whether and how global change drivers affect plant communities (Smith et al, ; Perring et al ). Studies evaluating the functional response of communities to global change drivers should therefore aim to incorporate effects of local resources and conditions (Bruelheide et al, ).…”

Section: Introductionmentioning

confidence: 99%

Plant functional trait response to environmental drivers across European temperate forest understorey communities

et al. 2020

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Functional traits respond to environmental drivers, hence evaluating trait-environment relationships across spatial environmental gradients can help to understand how multiple drivers influence plant communities. Global-change drivers such as changes in atmospheric nitrogen deposition occur worldwide, but affect community trait distributions at the local scale, where resources (e.g. light availability) and conditions (e.g. soil pH) also influence plant communities.• We investigate how multiple environmental drivers affect community trait responses related to resource acquisition (plant height, specific leaf area (SLA), woodiness, and mycorrhizal status) and regeneration (seed mass, lateral spread) of European temperate deciduous forest understoreys. We sampled understorey communities and derived trait responses across spatial gradients of global-change drivers (temperature, precipitation, nitrogen deposition, and past land use), while integrating in-situ plot measurements on resources and conditions (soil type, Olsen phosphorus (P), Ellenberg soil moisture, light, litter mass, and litter quality).• Among the global-change drivers, mean annual temperature strongly influenced traits related to resource acquisition. Higher temperatures were associated with taller understoreys producing leaves with lower SLA, and a higher proportional cover of woody and obligate mycorrhizal (OM) species. Communities in plots with higher Ellenberg soil moisture content had smaller seeds and lower proportional cover of woody and OM species. Finally, plots with thicker litter layers hosted taller understoreys with larger seeds and a higher proportional cover of OM species.• Our findings suggest potential community shifts in temperate forest understoreys with global warming, and highlight the importance of local resources and conditions as well as global-change drivers for community trait variation. Hansen et al., 2001;Walther, 2010;De Frenne et al., 2011;Bernhardt-R€ omermann et al., 2015;Bjorkman et al., 2018). Important global change drivers affecting temperate plant communities include increased temperatures, changes in Plant Biology 22 (2020) 410-424

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Understanding context dependency in the response of forest understorey plant communities to nitrogen deposition

Cited by 54 publications

References 99 publications

Light and warming drive forest understorey community development in different environments

Light and warming drive forest understorey community development in different environments

Impacts of nitrogen addition on plant species richness and abundance: A global meta‐analysis

Plant functional trait response to environmental drivers across European temperate forest understorey communities

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