Foliar nutrient resorption patterns of four functional plants along a precipitation gradient on the Tibetan Changtang Plateau

Guangshuai Zhao; Peili Shi; Jianshuang Wu; Dingpeng Xiong; Ning Zong; Xianzhou Zhang

doi:10.1002/ece3.3283

Foliar nutrient resorption patterns of four functional plants along a precipitation gradient on the Tibetan Changtang Plateau

Ecol Evol. 2017 Aug 2;7(18):7201-7212. doi: 10.1002/ece3.3283. eCollection 2017 Sep.

Authors

Guangshuai Zhao^{1

2}, Peili Shi^{1

3}, Jianshuang Wu^{1

4}, Dingpeng Xiong¹, Ning Zong¹, Xianzhou Zhang^{1

3}

Affiliations

¹ Key Laboratory of Ecosystem Network Observation and Modelling Institute of Geographic Sciences and Natural Resources Research Chinese Academy of Sciences Beijing China.
² China National Forestry Economics and Development Research Center Beijing China.
³ College of Resource and Environment University of Chinese Academy of Sciences Beijing China.
⁴ Functional Biodiversity Dahlem Center of Plant Science Free University of Berlin Berlin Germany.

Abstract

Nutrient resorption from senesced leaves as a nutrient conservation strategy is important for plants to adapt to nutrient deficiency, particularly in alpine and arid environment. However, the leaf nutrient resorption patterns of different functional plants across environmental gradient remain unclear. In this study, we conducted a transect survey of 12 communities to address foliar nitrogen (N) and phosphorus (P) resorption strategies of four functional groups along an eastward increasing precipitation gradient in northern Tibetan Changtang Plateau. Soil nutrient availability, leaf nutrient concentration, and N:P ratio in green leaves ([N:P]_g) were linearly correlated with precipitation. Nitrogen resorption efficiency decreased, whereas phosphorus resorption efficiency except for sedge increased with increasing precipitation, indicating a greater nutrient conservation in nutrient-poor environment. The surveyed alpine plants except for legume had obviously higher N and P resorption efficiencies than the world mean levels. Legumes had higher N concentrations in green and senesced leaves, but lowest resorption efficiency than nonlegumes. Sedge species had much lower P concentration in senesced leaves but highest P resorption efficiency, suggesting highly competitive P conservation. Leaf nutrient resorption efficiencies of N and P were largely controlled by soil and plant nutrient, and indirectly regulated by precipitation. Nutrient resorption efficiencies were more determined by soil nutrient availability, while resorption proficiencies were more controlled by leaf nutrient and N:P of green leaves. Overall, our results suggest strong internal nutrient cycling through foliar nutrient resorption in the alpine nutrient-poor ecosystems on the Plateau. The patterns of soil nutrient availability and resorption also imply a transit from more N limitation in the west to a more P limitation in the east Changtang. Our findings offer insights into understanding nutrient conservation strategy in the precipitation and its derived soil nutrient availability gradient.

Keywords: N:P; Tibetan Changtang Plateau; environmental controls; leaf nutrient resorption; nitrogen and phosphorus; plant functional group; precipitation gradient; soil nutrient availability; stoichiometry.