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Stability and carbon uptake of the soil microbial community is determined by differences between rhizosphere and bulk soil

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Author / Producer

Lange, Markus Azizi-Rad, Mina Dittmann, Georg

Date

2024-02

Publication Type

Journal Article

ETH Bibliography

yes

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Full text (published version) (PDF, 2.22 MB)

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Creative Commons Attribution-NonCommercial 4.0 International north_east

Abstract

The interactions between plants and soil microorganisms are fundamental for ecosystem functioning. However, it remains unclear if seasonality of plant growth impacts plant-microbial interactions, such as by inducing shifts in the microbial community composition, their biomass, or changes in the microbial uptake of plant-derived carbon. Here, we investigated the stability of the microbial community and their net assimilation of plant-derived carbon over an entire growing season. Using a C3–C4 vegetation change experiment, and taking advantage of a natural 13C label, we measured the plant-derived carbon in lipid biomarkers of soil microorganisms in rhizosphere and bulk soil in two soils with contrasting textures. We found that temporal stability was higher in bacterial than in fungal biomass, whereas the spatial stability of the fungal biomass was higher than that of bacterial biomass. Moreover, symbiotic AM fungi tended to be more stable in the uptake of plant-derived carbon than bacteria and saprophytic fungi. While soil texture did influence microbial community composition as expected, it had no effect on the microbial plant carbon assimilation and the differences between rhizosphere and bulk soil. In addition, the putative differences in carbon utilization between microbial groups, with the exception of AM fungi, were generally smaller than expected, reflecting opportunistic utilization of energy sources. Our results suggest that microbial uptake of plant carbon is primarily limited by plant carbon allocation rather than by environmental factors such as soil texture and seasonality. This indicates that the ongoing carbon assimilation during the growing season is supported by a functional redundancy within the microbial community, which, in turn, helps sustain ecosystem functioning.

Permanent link

https://doi.org/10.3929/ethz-b-000649840

Publication status

published

External links

https://doi.org/10.1016/j.soilbio.2023.109280 north_east

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Book title

Journal / series

Volume

189

Pages / Article No.

109280

Publisher

Elsevier

Event

Edition / version

Methods

Software

Geographic location

Date collected

Date created

Subject

Microbial functioning; PLFA; NLFA; Root exudation; 13C; Vegetation change experiments; Soil carbon

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Notes

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