Climate and geology overwrite land use effects on soil organic nitrogen cycling on a continental scale

Soil fertility and plant productivity are globally constrained by N availability. Proteins are the largest N reservoir in soils, and the cleavage of proteins into small peptides and amino acids has been shown to be the rate-limiting step in the terrestrial N cycle. However, we are still lacking a pr...

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Bibliographic Details
Published in:Biogeosciences 2022-12, Vol.19 (23), p.5419-5433
Main Authors: Noll, Lisa, Zhang, Shasha, Zheng, Qing, Hu, Yuntao, Hofhansl, Florian, Wanek, Wolfgang
Format: Article
Language:English
Subjects:
Amino acids
Availability
Biogeography
Boreal ecosystems
Cleavage
Climate
Climate and land use
Climate control
Climate effects
Cycles
Decomposition
Depolymerization
Environmental conditions
Environmental control
Enzymes
Fertility
Forest soils
Geochemistry
Geology
Grasslands
Identification
Land use
Land use effects
Multivariate statistical analysis
Nitrogen
Nitrogen cycle
Organic matter
Organic nitrogen
Organic soils
Peptides
Precipitation
Precipitation effects
Proteins
Soil
Soil fertility
Soil organic matter
Soil stabilization
Substrates
Vegetation
Weathering
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Summary:Soil fertility and plant productivity are globally constrained by N availability. Proteins are the largest N reservoir in soils, and the cleavage of proteins into small peptides and amino acids has been shown to be the rate-limiting step in the terrestrial N cycle. However, we are still lacking a profound understanding of the environmental controls of this process. Here we show that integrated effects of climate and soil geochemistry drive protein cleavage across large scales. We measured gross protein depolymerization rates in mineral and organic soils sampled across a 4000 km long European transect covering a wide range of climates, geologies and land uses. Based on structural equation models we identified that soil organic N cycling was strongly controlled by substrate availability, e.g., by soil protein content. Soil geochemistry was a secondary predictor, by controlling protein stabilization mechanisms and protein availability. Precipitation was identified as the main climatic control on protein depolymerization, by affecting soil weathering and soil organic matter accumulation. In contrast, land use was a poor predictor of protein depolymerization. Our results highlight the need to consider geology and precipitation effects on soil geochemistry when estimating and predicting soil N cycling at large scales.
ISSN:1726-4189
1726-4170
1726-4189
DOI:10.5194/bg-19-5419-2022