Increased N affects P uptake of eight grassland species: The role of root surface phosphatase activity
Increased N affects P uptake of eight grassland species: The role of root surface phosphatase activity
Increased N deposition may change species composition in grassland communities by shifting them to P limitation. Interspecific differences in P uptake traits might be a crucial yet poorly understood factor in determining the N effects. To test the effects of increased N supply (relative to P), we conducted two greenhouse fertilization experiments with eight species from two functional groups (grasses, herbs), including those common in P and N limited grasslands. We investigated plant growth and P uptake from two P sources, orthophosphate and not-readily available P (bound-P), under different N supply levels. Furthermore, to test if the N effects on P uptake was due to N availability alone or altered N:P ratio, we examined several uptake traits (root-surface phosphatase activity, specific root length (SRL), root mass ratio (RMR)) under varying N:P supply ratios. Only a few species (M. caerulea, A. capillaris, S. pratensis) could take up a similar amount of P from bound-P to that from orthophosphate. These species had neither higher SRL, RMR, phosphatase activity per unit root (Paseroot), nor higher total phosphatase activity (Pasetot: Paseroot times root mass), but higher relative phosphatase activity (Paserel: Pasetot divided by biomass) than other species. The species common from P-limited grasslands had high Paserel. P uptake from bound-P was positively correlated with Pasetot for grasses. High N supply stimulated phosphatase activity but decreased RMR and SRL, resulting in no increase in P uptake from bound-P. Paseroot was influenced by N:P supply ratio, rather than by only N or P level, whereas SRL and RMR was not dominantly influenced by N:P ratio. We conclude that increased N stimulates phosphatase activity via N:P stoichiometry effects, which potentially increases plant P uptake in a species-specific way. N deposition, therefore, may alter plant community structure not only by enhancing productivity, but also by favouring species with traits that enable them to persist better under P limited conditions.
1665-1673
Fujita, Yuki
caec3e66-3b79-4cc1-8f0c-bf55ffb58b59
Robroek, Bjorn J M
06dcb269-687c-41db-ab73-f61899617f92
de Ruiter, Peter C.
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Heil, Gerrit W.
a0f5577f-30ec-4204-8759-665c6941ddb7
Wassen, Martin J.
0f530153-e74d-49f3-99b0-9d1f191acc70
October 2010
Fujita, Yuki
caec3e66-3b79-4cc1-8f0c-bf55ffb58b59
Robroek, Bjorn J M
06dcb269-687c-41db-ab73-f61899617f92
de Ruiter, Peter C.
f556218c-3625-44be-80a4-321b0b7f4df9
Heil, Gerrit W.
a0f5577f-30ec-4204-8759-665c6941ddb7
Wassen, Martin J.
0f530153-e74d-49f3-99b0-9d1f191acc70
Fujita, Yuki, Robroek, Bjorn J M, de Ruiter, Peter C., Heil, Gerrit W. and Wassen, Martin J.
(2010)
Increased N affects P uptake of eight grassland species: The role of root surface phosphatase activity.
Oikos, 119 (10), .
(doi:10.1111/j.1600-0706.2010.18427.x).
Abstract
Increased N deposition may change species composition in grassland communities by shifting them to P limitation. Interspecific differences in P uptake traits might be a crucial yet poorly understood factor in determining the N effects. To test the effects of increased N supply (relative to P), we conducted two greenhouse fertilization experiments with eight species from two functional groups (grasses, herbs), including those common in P and N limited grasslands. We investigated plant growth and P uptake from two P sources, orthophosphate and not-readily available P (bound-P), under different N supply levels. Furthermore, to test if the N effects on P uptake was due to N availability alone or altered N:P ratio, we examined several uptake traits (root-surface phosphatase activity, specific root length (SRL), root mass ratio (RMR)) under varying N:P supply ratios. Only a few species (M. caerulea, A. capillaris, S. pratensis) could take up a similar amount of P from bound-P to that from orthophosphate. These species had neither higher SRL, RMR, phosphatase activity per unit root (Paseroot), nor higher total phosphatase activity (Pasetot: Paseroot times root mass), but higher relative phosphatase activity (Paserel: Pasetot divided by biomass) than other species. The species common from P-limited grasslands had high Paserel. P uptake from bound-P was positively correlated with Pasetot for grasses. High N supply stimulated phosphatase activity but decreased RMR and SRL, resulting in no increase in P uptake from bound-P. Paseroot was influenced by N:P supply ratio, rather than by only N or P level, whereas SRL and RMR was not dominantly influenced by N:P ratio. We conclude that increased N stimulates phosphatase activity via N:P stoichiometry effects, which potentially increases plant P uptake in a species-specific way. N deposition, therefore, may alter plant community structure not only by enhancing productivity, but also by favouring species with traits that enable them to persist better under P limited conditions.
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Published date: October 2010
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Local EPrints ID: 413685
URI: http://eprints.soton.ac.uk/id/eprint/413685
ISSN: 0030-1299
PURE UUID: dec48d91-d1c3-436a-b783-53a3f70f9e9f
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Date deposited: 31 Aug 2017 16:31
Last modified: 15 Apr 2024 17:04
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Author:
Yuki Fujita
Author:
Bjorn J M Robroek
Author:
Peter C. de Ruiter
Author:
Gerrit W. Heil
Author:
Martin J. Wassen
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