Gross soil N transformations and microbial communities in Luxembourg beech forest (Fagus sylvatica L.) soils along a pH gradient

Gross soil N transformations and microbial communities in Luxembourg beech forest (Fagus sylvatica L.) soils along a pH gradient

Acidic and calcareous soils differ in nitrogen (N) cycling, yet the underlying gross N transformations remain unclear in temperate forests. To address this gap, we quantified gross N transformations and microbial abundances in the organic layer and mineral topsoil (0–5 cm) of four closely situated b...

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Bibliographic Details
Main Authors: Mengru Jia, Annemieke Kooijman, Roland Bol, Wim W. Wessel, Kathrin Hassler, Albert Tietema
Format: Article
Language:English
Published: Elsevier 2025-02-01
Series:Geoderma
Subjects:
Gross N transformations
15N tracing
Soil pH
Microbial N demand
Fungi-to-bacteria ratios
N fertility
Online Access:http://www.sciencedirect.com/science/article/pii/S0016706125000321
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Summary:Acidic and calcareous soils differ in nitrogen (N) cycling, yet the underlying gross N transformations remain unclear in temperate forests. To address this gap, we quantified gross N transformations and microbial abundances in the organic layer and mineral topsoil (0–5 cm) of four closely situated beech forests along a natural pH gradient. Gross N turnover accelerated from acidic to calcareous soils, with gross mineralization rates increasing 6-fold in the organic layer and 10-fold in the mineral topsoil. However, net N release did not increase accordingly due to concurrent increases in gross immobilization. Enhanced immobilization at higher pH reflected greater microbial N demand under bacterial dominance, evidenced by higher microbial N, lower microbial C:N ratios and reduced fungi-to-bacteria (F:B) ratios. Autotrophic nitrification also increased with pH, corresponding to elevated ammonium supply from gross mineralization and higher abundances of ammonia-oxidizers. Heterotrophic nitrification was much lower than autotrophic nitrification in calcareous soils but equally important in acidic soils. Net N release was restricted to the mineral topsoil, shifting from low ammonium and nitrate release in acidic soils, to substantial nitrate release in calcareous soils, potentially supporting greater plant species richness at high pH. Our results demonstrate that soil N supply mechanisms differ markedly along the pH gradient, from low immobilization at low pH to high nitrification at high pH, driven by shifts in fungal versus bacterial dominance and their distinct N demands. This improved understanding of microbial regulation of acidity-related soil N fertility is crucial for predicting forest responses to global climate disturbances.
ISSN:1872-6259

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