Abstract
The leaf economics spectrum (LES) is based on a suite of leaf traits related to plant functioning and ranges from resource‐conservative to resource‐acquisitive strategies. However, the relationships with root traits, and the associated belowground plant functioning such as N uptake, including nitrate (NO3−) and ammonium (NH4+), is still poorly known. Additionally, environmental variations occurring both in time and in space could uncouple LES from root traits. We explored, in subalpine grasslands, the relationships between leaf and root morphological traits for three dominant perennial grass species, and to what extent they contribute to the whole‐plant economics spectrum. We also investigated the link between this spectrum and NO3− and NH4+ uptake rates, as well as the variations of uptake across four grasslands differing by the land‐use history at peak biomass and in autumn. Although poorly correlated with leaf traits, root traits contributed to an economic spectrum at the whole plant level. Higher NH4+ and NO3− uptake abilities were associated with the resource‐acquisitive strategy. Nonetheless, NH4+ and NO3−‐uptake within species varied between land‐uses and with sampling time, suggesting that LES and plant traits are good, but still incomplete, descriptors of plant functioning. Although the NH4+:NO3− uptake ratio was different between plant species in our study, they all showed a preference for NH4+, and particularly the most conservative species. Soil environmental variations between grasslands and sampling times may also drive to some extent the NH4+ and NO3− uptake ability of species. Our results support the current efforts to build a more general framework including above‐ and below‐ground processes when studying plant community functioning.
Highlights
Functional traits have been widely used to describe different plant strategies
We investigated the relationships between functional traits and inorganic N (NH4+ and NO3-) uptake for three perennial grass species with contrasted leaf economic strategies
Estimating root NH4+ and NO3- uptake, and measuring functional traits for leaves and roots, we tested the following hypotheses: (1) similar to leaf traits, root traits are contributing to the plant economics spectrum with root traits reflecting nutrient acquisition expected to be more associated to the exploitative syndrome, (2) and with more exploitative species being more efficient to take up both NH4+ and NO3-. (3) As functional traits are influenced by environmental conditions, we hypothesised that NH4+ and NO3- uptake will be influenced by environmental variations between grasslands, as well as during the growing season, probably following NH4+ and NO3- availability depending on the most abundant form
Summary
Functional traits have been widely used to describe different plant strategies. One major axis of specialisation involves a trade-off between conservation of resources in well protected and long lived tissues, and acquisition of resources by tissue with high use-efficiency and turnover, and commonly referred as the leaf economic spectrum (LES, Wright et al 2004). Decreased management intensity favours plant species with resource conservative traits (Quétier et al 2007), which are usually associated with fungal-dominated belowground communities (de Vries et al 2012, Grigulis et al 2013) It slows down N cycling (Zeller et al 2000, Robson et al 2010), favouring the accumulation of soil ammonium (NH4+) rather than soil nitrate (NO3-) (Robson et al 2007). Estimating root NH4+ and NO3- uptake, and measuring functional traits for leaves and roots, we tested the following hypotheses: (1) similar to leaf traits, root traits are contributing to the plant economics spectrum with root traits reflecting nutrient acquisition (e.g. high specific root length and root nitrogen content) expected to be more associated to the exploitative syndrome, (2) and with more exploitative species being more efficient to take up both NH4+ and NO3-. Estimating root NH4+ and NO3- uptake, and measuring functional traits for leaves and roots, we tested the following hypotheses: (1) similar to leaf traits, root traits are contributing to the plant economics spectrum with root traits reflecting nutrient acquisition (e.g. high specific root length and root nitrogen content) expected to be more associated to the exploitative syndrome, (2) and with more exploitative species being more efficient to take up both NH4+ and NO3-. (3) As functional traits are influenced by environmental conditions, we hypothesised that NH4+ and NO3- uptake will be influenced by environmental variations between grasslands, as well as during the growing season, probably following NH4+ and NO3- availability depending on the most abundant form
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