Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics
1. Nitrogen (N) cycling is a key process determining ecosystem functioning in subalpine grasslands where traditional mowing and manuring are being abandoned. However, the roles of the plant and microbial communities in mediating changes in N availability are still poorly understood. 2. We inoculated 15 subalpine grassland fields with dual-labelled ammonium nitrate (15NH4+, 15NO3 -) during July 2005 and used pool dilutions over 1 month to calculate inorganic N fluxes into the microbial pool and uptake in plant communities by grasses, forbs and legumes. The effects of current land abandonment were assessed by comparing manured and mown terraces (ancient croplands) with other terraces where these practices have ceased, and mown versus unmown unterraced meadows. 3. Rapid cycling of inorganic N and high soil N availability in forb-dominated manured and mown terraces resulted from fast plant N uptake and low microbial CN ratio. In grass-dominated unmown terraces, N cycling was slower and N retention was greater; microbial N uptake remained similar to that in the other terraces, although a higher CN ratio suggested a shift towards fungal dominance. 4. In unterraced meadows, pH was low due to reduced mixing of soil with the underlying calcareous rock. Soil [NH4+] was high and [NO3-] low, but current management had no effect on N pool size, although plant N uptake was greater in the mown than unmown fields. This may be partially explained by high N retention by dominant Festuca paniculata tussocks. The microbial N pool and N uptake were both low and the microbial CN ratio was high, suggesting that fungi slowed N cycling and reduced the influence of mowing on N turnover. 5. Synthesis. In these marginal long-term grasslands, with low productivity and high biodiversity value, changes in ecosystem function associated with reduced management intensity were mediated through slower N cycling. This response was expressed as more gradual nutrient uptake but greater retention by unmown plant communities, slower microbial uptake and smaller soil N pools. In contrast to more productive ecosystems, such as north-western European grasslands, reduced management is detrimental to both biodiversity and the maintenance of soil-related ecosystem services. These costs will need to be balanced against potential benefits, such as carbon storage. © 2009 British Ecological Society.
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| Format: | journal article biblioteca |
| Language: | English |
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Wiley
2010
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| Subjects: | 15N isotope, Marginal grasslands, Microbial N, N mineralization, Plant functional types, Pool dilution, Traditional land use15N isotope, Traditional land use, |
| Online Access: | http://hdl.handle.net/20.500.12792/3751 http://hdl.handle.net/10261/294436 |
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dig-inia-es-10261-2944362023-02-20T10:38:40Z Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics Robson, T. M. Baptist, F. Clément, J. C. Lavorel, S. 15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use 1. Nitrogen (N) cycling is a key process determining ecosystem functioning in subalpine grasslands where traditional mowing and manuring are being abandoned. However, the roles of the plant and microbial communities in mediating changes in N availability are still poorly understood. 2. We inoculated 15 subalpine grassland fields with dual-labelled ammonium nitrate (15NH4+, 15NO3 -) during July 2005 and used pool dilutions over 1 month to calculate inorganic N fluxes into the microbial pool and uptake in plant communities by grasses, forbs and legumes. The effects of current land abandonment were assessed by comparing manured and mown terraces (ancient croplands) with other terraces where these practices have ceased, and mown versus unmown unterraced meadows. 3. Rapid cycling of inorganic N and high soil N availability in forb-dominated manured and mown terraces resulted from fast plant N uptake and low microbial CN ratio. In grass-dominated unmown terraces, N cycling was slower and N retention was greater; microbial N uptake remained similar to that in the other terraces, although a higher CN ratio suggested a shift towards fungal dominance. 4. In unterraced meadows, pH was low due to reduced mixing of soil with the underlying calcareous rock. Soil [NH4+] was high and [NO3-] low, but current management had no effect on N pool size, although plant N uptake was greater in the mown than unmown fields. This may be partially explained by high N retention by dominant Festuca paniculata tussocks. The microbial N pool and N uptake were both low and the microbial CN ratio was high, suggesting that fungi slowed N cycling and reduced the influence of mowing on N turnover. 5. Synthesis. In these marginal long-term grasslands, with low productivity and high biodiversity value, changes in ecosystem function associated with reduced management intensity were mediated through slower N cycling. This response was expressed as more gradual nutrient uptake but greater retention by unmown plant communities, slower microbial uptake and smaller soil N pools. In contrast to more productive ecosystems, such as north-western European grasslands, reduced management is detrimental to both biodiversity and the maintenance of soil-related ecosystem services. These costs will need to be balanced against potential benefits, such as carbon storage. © 2009 British Ecological Society. 2023-02-20T10:38:40Z 2023-02-20T10:38:40Z 2010 journal article Journal of Ecology 98(1): 62-73 (2010) 0022-0477 http://hdl.handle.net/20.500.12792/3751 http://hdl.handle.net/10261/294436 10.1111/j.1365-2745.2009.01609.x 1365-2745 en none Wiley |
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15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use 15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use |
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15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use 15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use Robson, T. M. Baptist, F. Clément, J. C. Lavorel, S. Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics |
| description |
1. Nitrogen (N) cycling is a key process determining ecosystem functioning in subalpine grasslands where traditional mowing and manuring are being abandoned. However, the roles of the plant and microbial communities in mediating changes in N availability are still poorly understood. 2. We inoculated 15 subalpine grassland fields with dual-labelled ammonium nitrate (15NH4+, 15NO3 -) during July 2005 and used pool dilutions over 1 month to calculate inorganic N fluxes into the microbial pool and uptake in plant communities by grasses, forbs and legumes. The effects of current land abandonment were assessed by comparing manured and mown terraces (ancient croplands) with other terraces where these practices have ceased, and mown versus unmown unterraced meadows. 3. Rapid cycling of inorganic N and high soil N availability in forb-dominated manured and mown terraces resulted from fast plant N uptake and low microbial CN ratio. In grass-dominated unmown terraces, N cycling was slower and N retention was greater; microbial N uptake remained similar to that in the other terraces, although a higher CN ratio suggested a shift towards fungal dominance. 4. In unterraced meadows, pH was low due to reduced mixing of soil with the underlying calcareous rock. Soil [NH4+] was high and [NO3-] low, but current management had no effect on N pool size, although plant N uptake was greater in the mown than unmown fields. This may be partially explained by high N retention by dominant Festuca paniculata tussocks. The microbial N pool and N uptake were both low and the microbial CN ratio was high, suggesting that fungi slowed N cycling and reduced the influence of mowing on N turnover. 5. Synthesis. In these marginal long-term grasslands, with low productivity and high biodiversity value, changes in ecosystem function associated with reduced management intensity were mediated through slower N cycling. This response was expressed as more gradual nutrient uptake but greater retention by unmown plant communities, slower microbial uptake and smaller soil N pools. In contrast to more productive ecosystems, such as north-western European grasslands, reduced management is detrimental to both biodiversity and the maintenance of soil-related ecosystem services. These costs will need to be balanced against potential benefits, such as carbon storage. © 2009 British Ecological Society. |
| format |
journal article |
| topic_facet |
15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use15N isotope Marginal grasslands Microbial N N mineralization Plant functional types Pool dilution Traditional land use |
| author |
Robson, T. M. Baptist, F. Clément, J. C. Lavorel, S. |
| author_facet |
Robson, T. M. Baptist, F. Clément, J. C. Lavorel, S. |
| author_sort |
Robson, T. M. |
| title |
Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics |
| title_short |
Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics |
| title_full |
Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics |
| title_fullStr |
Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics |
| title_full_unstemmed |
Land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics |
| title_sort |
land use in subalpine grasslands affects nitrogen cycling via changes in plant community and soil microbial uptake dynamics |
| publisher |
Wiley |
| publishDate |
2010 |
| url |
http://hdl.handle.net/20.500.12792/3751 http://hdl.handle.net/10261/294436 |
| work_keys_str_mv |
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