Abstract
Continuous nitrogen (N) deposition has raised concerns that temperate forest ecosystems shift from N limitation to progressing phosphorus (P) limitation under global change. According to the multiple resource limitation theory, this will not only influence P economy, but also reduce N uptake and use efficiencies of trees such that growth is equally limited by N and P. We used different global change scenarios including summer drought to test the prediction of this hypothesis for the N economy of European beech (Fagus sylvatica L.) saplings. Our study demonstrates that the N uptake efficiency (NUptakeE) of beech adjusts to soil N availability and stabilizes leaf and fine root N concentrations. By contrast, both efficiencies of N use were curtailed by increasing P limitation under elevated soil N. The photosynthetic N use efficiency (PNUE) was serially reduced with decreasing soil P availability and increasing foliar N:P ratios, while the N use efficiency (NUE) decreased with increasing fine root N:P ratios. Soil drought induced relative P deficiency alike and reduced NUptakeE, PNUE, and NUE independent from the soil N:P ratios. We conclude that not only N deposition but also increasing summer droughts might affect N:P ratios, thereby inducing P imbalances and affecting the N economy of European beech saplings under global change.
Highlights
The net primary production of temperate forests is primarily limited by N availability (LeBauer and Treseder, 2008)
We demonstrated that P uptake efficiency of beech in dry soils significantly decreased with decreasing Ectomycorrhizal fungi (ECMF) α diversity, whereas the P use efficiency was negatively related to soil P availability
In the related current study, we aimed to investigate the effect of global change on the N economy of European beech saplings in a four-factorial climate-chamber experiment that simulated the expected conditions for Central Europe
Summary
The net primary production of temperate forests is primarily limited by N availability (LeBauer and Treseder, 2008). Increased N availability changes nutrient stoichiometry, i.e., leads to rises in the N:P ratio of ecosystems (Peñuelas et al, 2013). The degree of relative P deficiency increases and potentially shifts temperate forests from N limitation to P limitation (Talkner et al, 2015; Sardans et al, 2016; Hedwall et al, 2017). According to co-limitation hypothesis, N acquisition and use efficiencies depend on P availability and vice versa (Ågren et al, 2012).
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