Soil microbial populations shift as processes protecting organic matter change during podzolization
Vermeire, M.-L.; Cornelis, J.-T.; Van Ranst, E.; Bonneville, S.; Doetterl, S.; Delvaux, B. (2018). Soil microbial populations shift as processes protecting organic matter change during podzolization. Frontiers in Environmental Science 6: 70. https://hdl.handle.net/10.3389/fenvs.2018.00070 In: Frontiers in Environmental Science. Frontiers Media S.A.: Switzerland. e-ISSN 2296-665X, more | |
Author keywords | organic matter; microorganisms; amino sugars; carbon fractionation; micromorphology; SOM protection mechanisms; podzol; chronosequence |
Abstract | In the upper part of the solum of mineral soils, soil organic and mineral constituents co-evolve through pedogenesis, that in turn impacts the transformation and stabilization of soil organic matter (SOM). Here, we assess the reciprocal interactions between soil minerals, SOM and the broad composition of microbial populations in a 530-year chronosequence of podzolic soils. Five pedons, derived from beach sand, are studied. From young to old soils, net acidification parallels mineral dissolution and the formation of eluvial and illuvial horizons. Organo-mineral associations (OMA) accumulate in the illuvial B horizon of the older soils (330–530 years). Apart from contributing to SOM stabilization and protection, organo-mineral compounds progressively fill up interparticle voids. The subsequent loss of porosity leads to horizon induration, decrease of hydraulic conductivity, which promote redoximorphic processes. While recalcitrant SOM is preserved in the topsoil of the old soils, the largest quantity of protected SOM occurs in the indurated, temporalily waterlogged B horizons, through both the OMA accumulation and inhibition of microbial decomposition. SOM protection is thus both time- and horizon-specific. The microbiota also evolve along the chronosequence. Fungi dominate in all horizons of the younger soils and in the topsoil of the older soils, while bacteria prevail in the cemented B horizons of older soils. This shift in microbial community composition is due to the interdependent co-evolution of SOM and minerals during pedogenesis. Our results call for considering the microenvironment and parameters inherent to decomposer microorganisms to understand SOM protection processes in soils. |
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