Abstract
BackgroundIn forest ecosystems with phosphorus (P) deficiency, the impact of atmospheric nitrogen (N) deposition on nutritional traits related to P uptake and P use potentially determines plant growth and vegetation productivity.Methodology/Principal FindingsTwo N deposition simulations were combined with three soil P conditions (homogeneous P deficiency with evenly low P; heterogeneous P deficiency with low subsoil P and high topsoil P; high P) using four full-sib families of Masson pine (Pinus massoniana). Under homogeneous P deficiency, N had a low effect on growth due to higher N:P ratios, whereas N-sensitive genotypes had lower N:P ratios and greater N sensitivity. The N effect increased under higher P conditions due to increased P concentration and balanced N:P ratios. An N:P threshold of 12.0–15.0 was detected, and growth was increased by N with an N:P ratio ≤ 12.0 and increased by P with an N:P ratio ≥ 15.0. Under homogeneous P deficiency, increased P use efficiency by N deposition improved growth. Under heterogeneous P deficiency, a greater P deficiency under N deposition due to increased N:P ratios induced greater adaptive responses to low P (root acid phosphatase secretion and topsoil root proliferation) and improved P acquisition and growth.Conclusions/SignificanceN deposition diversely affected seedling growth across different P conditions and genotypes via N:P ratio effects and the modulation of adaptive responses to low P. The positive impact of N on growth was genotype-specific and increased by soil P addition due to balanced N:P ratios. These results indicate the significance of breeding N-sensitive tree genotypes and improving forest soil P status to compensate for increasing N deposition.
Highlights
Low phosphorus (P) availability is a limiting factor of plant growth in many terrestrial ecosystems [1,2,3]
No significant differences in major growth traits were detected between the MLP and high P (HP) conditions (Figure 1a, 1b, 1c)
The activity of the root secreted acid phosphatase was much greater in the LP condition than that in the MLP and HP conditions (Figure 1d)
Summary
Low phosphorus (P) availability is a limiting factor of plant growth in many terrestrial ecosystems [1,2,3]. Dramatically increased N levels elevate an ecosystem’s N:P ratios [10,12,13], which might increase the degree of relative soil P deficiency These factors potentially influence plant growth and P nutritional traits [10,12,14,15]. In forest ecosystems with phosphorus (P) deficiency, the impact of atmospheric nitrogen (N) deposition on nutritional traits related to P uptake and P use potentially determines plant growth and vegetation productivity. The positive impact of N on growth was genotype-specific and increased by soil P addition due to balanced N:P ratios These results indicate the significance of breeding N-sensitive tree genotypes and improving forest soil P status to compensate for increasing N deposition
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