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Effects of nitrogen and water addition on trace element stoichiometry in five grassland species

Cai, Jiangping, Weiner, Jacob, Wang, Ruzhen, Luo, Wentao, Zhang, Yongyong, Liu, Heyong, Xu, Zhuwen, Li, Hui, Zhang, Yuge, Jiang, Yong
Journal of plant research 2017 v.130 no.4 pp. 659-668
arid lands, bioaccumulation factor, bioavailability, cation exchange capacity, chemical concentration, copper, correlation, ecological function, forbs, grasses, grasslands, iron, leaves, manganese, nitrogen, nutrient deficiencies, soil acidification, soil pH, stoichiometry, toxicity, zinc, China
A 9-year manipulative experiment with nitrogen (N) and water addition, simulating increasing N deposition and changing precipitation regime, was conducted to investigate the bioavailability of trace elements, iron (Fe), manganese (Mn), copper (Cu), and zinc (Zn) in soil, and their uptake by plants under the two environmental change factors in a semi-arid grassland of Inner Mongolia. We measured concentrations of trace elements in soil and in foliage of five common herbaceous species including 3 forbs and 2 grasses. In addition, bioaccumulation factors (BAF, the ratio of the chemical concentration in the organism and the chemical concentration in the growth substrate) and foliar Fe:Mn ratio in each plant was calculated. Our results showed that soil available Fe, Mn and Cu concentrations increased under N addition and were negatively correlated with both soil pH and cation exchange capacity. Water addition partly counteracted the positive effects of N addition on available trace element concentrations in the soil. Foliar Mn, Cu and Zn concentrations increased but Fe concentration decreased with N addition, resulting in foliar elemental imbalances among Fe and other selected trace elements. Water addition alleviated the effect of N addition. Forbs are more likely to suffer from Mn toxicity and Fe deficiency than grass species, indicating more sensitivity to changing elemental bioavailability in soil. Our results suggested that soil acidification due to N deposition may accelerate trace element cycling and lead to elemental imbalance in soil–plant systems of semi-arid grasslands and these impacts of N deposition on semi-arid grasslands were affected by water addition. These findings indicate an important role for soil trace elements in maintaining ecosystem functions associated with atmospheric N deposition and changing precipitation regimes in the future.