Extracellular enzyme stoichiometry and microbial resource limitation following various grassland reestablishment in abandoned cropland
Grassland restoration in abandoned cropland had great impact on soil enzyme stoichiometry and microbial resource limitation, hence altering carbon (C) sequestration progress in soil depending on soil depth and grassland restoration strategy. It is crucial to understand the microbial resource limitat...
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Veröffentlicht in: | The Science of the total environment 2023-04, Vol.870, p.161746-161746, Article 161746 |
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Sprache: | eng |
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Zusammenfassung: | Grassland restoration in abandoned cropland had great impact on soil enzyme stoichiometry and microbial resource limitation, hence altering carbon (C) sequestration progress in soil depending on soil depth and grassland restoration strategy. It is crucial to understand the microbial resource limitation under various restoration strategies, which could have key implication for optimizing management to improve C sequestration in abandoned cropland. The objective of this study was to examine the changes and key regulators of soil enzyme stoichiometry and microbial resource limitation in different soil depths under different management strategies to restore grassland, namely a) cropland as continuous cropping (CR); b) naturally restored grassland (NR); c) grass-based grassland (GG); d) legume-based grassland (LG); e) grass-legume mixed grassland (MG); and f) grass-based grassland with N fertilization (GF). Results showed that converting cropland into grassland increased absolute soil enzyme activities potential for microbial C, nitrogen (N) and phosphorus (P) acquisition by 5–110 %, 25–132 % and 17–215 %, respectively depending on soil depth and grassland restoration strategy. These enzyme activities increased more in surface soil than subsoil with the conversion of cropland into grassland, especially under LG and GF. The strategies to restore grassland, especially LG and GF, significantly decreased enzymatic C:P and N:P ratios. Microbial C limitation was reduced associated with re-establishment of grassland, exacerbating the P limitation depending on grassland restoration strategies, especially under LG and GF. The shift of relative microbial resource limitation from C to P reduced the microbial C use efficiency, reducing the ecosystem C sequestration potential during the restoration of grassland. It appears that increased biomass input and soil C:P ratio are the key drivers to shift microbial resource limitation from C to P during the restoration of grassland. Thus, a moderate harvest of above-ground biomass with a supplement of P may be necessary for improving the C sequestration potential during the restoration of grasslands, especially in the grass-legume mix or grass-based grassland with N fertilization.
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•Grassland restoration of increases absolute soil enzyme activities.•Conversion from cropland into grassland reduces the microbial carbon limitation.•Nitrogen input increases microbial phosphorus limitation in soil.•Substrate carbon inp |
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ISSN: | 0048-9697 1879-1026 |
DOI: | 10.1016/j.scitotenv.2023.161746 |