%A Jing,Hang
%A Zhou,Haoxiang
%A Wang,Guoliang
%A Xue,Sha
%A Liu,Guobin
%A Duan,Mengcheng
%D 2017
%J Frontiers in Plant Science
%C
%F
%G English
%K Nitrogen addition,stoichiometry,growth rate,Plant organ,root
%Q
%R 10.3389/fpls.2017.01922
%W
%L
%N 1922
%M
%P
%7
%8 2017-November-07
%9 Original Research
%+ Guoliang Wang,State Key Laboratory of Soil Erosion and Dryland Farming on the Loess Plateau, Institute of Soil and Water Conservation, Northwest A&F University,China,glwang@nwsuaf.edu.cn
%+ Guoliang Wang,Institute of Soil and Water Conservation, Chinese Academy of Sciences and Ministry of Water Resources,China,glwang@nwsuaf.edu.cn
%#
%! N addition for stoichiometry and growth rate
%*
%<
%T Nitrogen Addition Changes the Stoichiometry and Growth Rate of Different Organs in Pinus tabuliformis Seedlings
%U https://www.frontiersin.org/article/10.3389/fpls.2017.01922
%V 8
%0 JOURNAL ARTICLE
%@ 1664-462X
%X Background. Nitrogen (N) deposition could influence plant stoichiometry and growth rate and thus alter the structure and function of the ecosystem. However, the mechanism by which N deposition changes the stoichiometry and relative growth rate (RGR) of plant organs, especially roots with different diameters, is unclear. Methods. We created a gradient of N availability (0–22.4 g N m–2 year–1) for Pinus tabuliformis seedlings for 3 years and examined changes in the carbon (C):N:phosphorus (P) ratios and RGRs of the leaves, stems, and roots with four diameter classes (finest roots, <0.5 mm; finer roots, 0.5–1 mm; middle roots, 1–2 mm; and coarse roots, >2 mm). Results. (1) N addition significantly increased the C and N contents of the leaves and whole roots, the C content of the stems, the N:P ratios of the leaves and stems, and the C:P ratio of the whole roots. (2) In the root system, the C:N ratio of the finest roots and the C:P ratios of the finest and finer roots significantly changed with N addition. The N:P ratios of the finest, finer, and middle roots significantly increased with increasing amount of N added. The stoichiometric responses of the roots were more sensitive to N addition than those of the other organs (3) The RGR of all the organs significantly increased at low N addition levels (2.8–11.2 g N m–2 year–1) but decreased at high N addition levels (22.4 g N m–2 year–1). (4) The RGRs of the whole seedlings and leaves were not significantly correlated with their N:P ratios at low and high N addition levels. By contrast, the RGRs of the stems and roots showed a significantly positive correlation with their own N:P ratio only at low N addition level. Conclusions. Addition of N affected plant growth by altering the contents of C and N; the ratios of C, N, and P; and the RGRs of the organs. RGR is correlated with the N:P ratios of the stems and roots at low N addition level but not at high N addition level. This finding is inconsistent with the growth rate hypothesis.