From pots to plots: hierarchical trait‐based prediction of plant performance in a mesic grassland

From pots to plots: hierarchical trait‐based prediction of plant performance in a mesic grassland

Traits are powerful predictors of ecosystem functions pointing to underlying physiological and ecological processes. Plant individual performance results from the coordinated operation of many processes, ranging from nutrient uptake over organ turnover to photosynthesis, thus requiring a large set o...

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Bibliographic Details
Published in:The Journal of ecology 2016-01, Vol.104 (1), p.206-218
Main Authors: Schroeder‐Georgi, Thomas, Wirth, Christian, Nadrowski, Karin, Meyer, Sebastian T, Mommer, Liesje, Weigelt, Alexandra, Gibson, David
Format: Article
Language:eng
Subjects:
biomass
ecosystems
equations
functional traits
grasslands
individual plant biomass
intraspecific competition
leaf traits
leaves
model selection
monoculture
Nature Conservation and Plant Ecology
Natuurbeheer en Plantenecologie
nitrogen content
nutrient uptake
PE&RC
photosynthesis
Plant Ecology and Nature Conservation
Plant population and community dynamics
Plantenecologie en Natuurbeheer
prediction
regression analysis
root traits
stature traits
trophic relationships
variance
vertical root distribution
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Summary:Traits are powerful predictors of ecosystem functions pointing to underlying physiological and ecological processes. Plant individual performance results from the coordinated operation of many processes, ranging from nutrient uptake over organ turnover to photosynthesis, thus requiring a large set of traits for its prediction. For plant performance on higher hierarchical levels, e.g. populations, additional traits important for plant‐plant and trophic interactions may be required which should even enlarge the spectrum of relevant predictor traits. The goal of this study was to assess the importance of plant functional traits to predict individual and population performance of grassland species with particular focus on the significance of root traits. We tested this for 59 grassland species using 35 traits divided into three trait clusters: leaf traits (16), stature traits (8) and root traits (11), using individual biomass of mesocosm plants as a measure of individual performance and population biomass of monocultures as a measure of population performance. We applied structural equation models to disentangle direct effects of single traits on population biomass and indirect effects via individual plant biomass or shoot density.We tested multivariate trait effects on individual and population biomass to analyse whether the importance of different trait clusters shifts with increasing hierarchical integration from individuals to populations. Traits of all three clusters significantly correlated with individual and population biomass. However, in spite of a number of significant correlations, above‐below‐ground linkages were generally weak, with few exceptions like N content. Stature traits exclusively affected population biomass indirectly via their effect on individual biomass, whereas root and leaf traits showed also direct effects and partly indirect effects via density. The inclusion of root traits in multiple regression models improved the prediction of individual biomass when compared with models with only above‐ground information only slightly (95% vs. 93% of variance prediction with and without root traits, respectively) but was crucial for the prediction of population biomass (77% and 49%, respectively). Root traits were more important for plant performance than leaf traits and were even the most important predictors at the population level Synthesis. Upscaling from the individual to the population level reflects an increasing number of processes re
ISSN:0022-0477
1365-2745