Rhizosphere priming promotes plant nitrogen acquisition by microbial necromass recycling
Copyright policy )Rhizosphere priming promotes plant nitrogen acquisition by microbial necromass recycling
AbstractNitrogen availability in the rhizosphere relies on root‐microorganism interactions, where root exudates trigger soil organic matter (SOM) decomposition through the rhizosphere priming effect (RPE). Though microbial necromass contribute significantly to organically bound soil nitrogen (N), the role of RPEs in regulating necromass recycling and plant nitrogen acquisition has received limited attention. We used 15N natural abundance as a proxy for necromass‐N since necromass is enriched in 15N compared to other soil‐N forms. We combined studies using the same experimental design for continuous 13CO2 labelling of various plant species and the same soil type, but considering top‐ and subsoil. RPE were quantified as difference in SOM‐decomposition between planted and unplanted soils. Results showed higher plant N uptake as RPEs increased. The positive relationship between 15N‐enrichment of shoots and roots and RPEs indicated an enhanced necromass‐N turnover by RPE. Moreover, our data revealed that RPEs were saturated with increasing carbon (C) input via rhizodeposition in topsoil. In subsoil, RPEs increased linearly within a small range of C input indicating a strong effect of root‐released C on decomposition rates in deeper soil horizons. Overall, this study confirmed the functional importance of rhizosphere C input for plant N acquisition through enhanced necromass turnover by RPEs.
- Leibniz Centre for Agricultural Landscape Research Germany
- Leibniz Association Germany
- University of California, Santa Cruz United States
- Peking University China (People's Republic of)
- University of Bayreuth Germany
Nitrogen, Soil Science, Organic chemistry, Carbon Dynamics in Peatland Ecosystems, Germination, Plant Science, Nitrogen cycle, Plant Roots, Subsoil, Agricultural and Biological Sciences, Soil, Symbiotic Nitrogen Fixation in Legumes, Plant Signaling, Soil water, Genetics, Soil Carbon Sequestration, Biology, Soil Microbiology, Soil Fertility, Nitrogen Isotopes, Ecology, Bacteria, Life Sciences, Plants, Topsoil, Soil carbon, Carbon, Agronomy, Priming (agriculture), Chemistry, FOS: Biological sciences, Environmental Science, Physical Sciences, Rhizosphere, Nitrogen Deposition, Soil Carbon Dynamics and Nutrient Cycling in Ecosystems, Plant Shoots, Ecosystem Functioning
Nitrogen, Soil Science, Organic chemistry, Carbon Dynamics in Peatland Ecosystems, Germination, Plant Science, Nitrogen cycle, Plant Roots, Subsoil, Agricultural and Biological Sciences, Soil, Symbiotic Nitrogen Fixation in Legumes, Plant Signaling, Soil water, Genetics, Soil Carbon Sequestration, Biology, Soil Microbiology, Soil Fertility, Nitrogen Isotopes, Ecology, Bacteria, Life Sciences, Plants, Topsoil, Soil carbon, Carbon, Agronomy, Priming (agriculture), Chemistry, FOS: Biological sciences, Environmental Science, Physical Sciences, Rhizosphere, Nitrogen Deposition, Soil Carbon Dynamics and Nutrient Cycling in Ecosystems, Plant Shoots, Ecosystem Functioning
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