TY - JOUR
T1 - Nutrient limitation of alpine plants
T2 - Implications from leaf N : P stoichiometry and leaf δ
15N
AU - Xu, Xingliang
AU - Wanek, Wolfgang
AU - Zhou, Caiping
AU - Richter, Andreas
AU - Song, Minghua
AU - Cao, Guangmin
AU - Ouyang, Hua
AU - Kuzyakov, Yakov
PY - 2014/6
Y1 - 2014/6
N2 - Nitrogen (N) deposition can affect grassland ecosystems by altering biomass production, plant species composition and abundance. Therefore, a better understanding of the response of dominant plant species to N input is a prerequisite for accurate prediction of future changes and interactions within plant communities. We evaluated the response of seven dominant plant species on the Tibetan Plateau to N input at two levels: individual species and plant functional group. This was achieved by assessing leaf N : P stoichiometry, leaf δ
15N and biomass production for the plant functional groups. Seven dominant plant species-three legumes, two forbs, one grass, one sedge-were analyzed for N, P, and δ
15N 2 years after fertilization with one of the three N forms: NO$ _3^- $, NH$ _4^+ $, or NH
4NO
3 at four application rates (0, 7.5, 30, and 150kg N ha
-1 y
-1). On the basis of biomass production and leaf N : P ratios, we concluded that grasses were limited by available N or co-limited by available P. Unlike for grasses, leaf N : P and biomass production were not suitable indicators of N limitation for legumes and forbs in alpine meadows. The poor performance of legumes under high N fertilization was mainly due to strong competition with grasses. The total above-ground biomass was not increased by N fertilization. However, species composition shifted to more productive grasses. A significant negative correlation between leaf N : P and leaf δ
15N indicated that the two forbs Gentiana straminea and Saussurea superba switched from N deficiency to P limitation (e.g., N excess) due to N fertilization. These findings imply that alpine meadows will be more dominated by grasses under increased atmospheric N deposition.
AB - Nitrogen (N) deposition can affect grassland ecosystems by altering biomass production, plant species composition and abundance. Therefore, a better understanding of the response of dominant plant species to N input is a prerequisite for accurate prediction of future changes and interactions within plant communities. We evaluated the response of seven dominant plant species on the Tibetan Plateau to N input at two levels: individual species and plant functional group. This was achieved by assessing leaf N : P stoichiometry, leaf δ
15N and biomass production for the plant functional groups. Seven dominant plant species-three legumes, two forbs, one grass, one sedge-were analyzed for N, P, and δ
15N 2 years after fertilization with one of the three N forms: NO$ _3^- $, NH$ _4^+ $, or NH
4NO
3 at four application rates (0, 7.5, 30, and 150kg N ha
-1 y
-1). On the basis of biomass production and leaf N : P ratios, we concluded that grasses were limited by available N or co-limited by available P. Unlike for grasses, leaf N : P and biomass production were not suitable indicators of N limitation for legumes and forbs in alpine meadows. The poor performance of legumes under high N fertilization was mainly due to strong competition with grasses. The total above-ground biomass was not increased by N fertilization. However, species composition shifted to more productive grasses. A significant negative correlation between leaf N : P and leaf δ
15N indicated that the two forbs Gentiana straminea and Saussurea superba switched from N deficiency to P limitation (e.g., N excess) due to N fertilization. These findings imply that alpine meadows will be more dominated by grasses under increased atmospheric N deposition.
KW - ammonium
KW - plant functional groups
KW - nitrate
KW - nitrogen cycling
KW - alpine meadow
KW - PHOSPHORUS LIMITATION
KW - TERRESTRIAL ECOSYSTEMS
KW - ORGANIC NITROGEN
KW - MEADOW
KW - AMMONIUM
KW - NITRATE
KW - N-15
KW - NUTRITION
KW - PATTERNS
KW - PLATEAU
KW - Ammonium
KW - Alpine meadow
KW - Nitrate
KW - Plant functional groups
KW - Nitrogen cycling
UR - http://www.scopus.com/inward/record.url?scp=84901694688&partnerID=8YFLogxK
U2 - 10.1002/jpln.201200061
DO - 10.1002/jpln.201200061
M3 - Article
SN - 1436-8730
VL - 177
SP - 378
EP - 387
JO - Journal of Plant Nutrition and Soil Science
JF - Journal of Plant Nutrition and Soil Science
IS - 3
ER -