Plant traits, stoichiometry and microbes as drivers of decomposition in the rhizosphere in a temperate grassland
1. It is becoming increasingly clear that plant roots can impact the decomposition of existing soil dependent, but whether this is the case in natural conditions or what factors underlie this variation is mostly unknown. 2. With a novel field-based isotopic approach combining ¹³C-enriched glucose an...
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Veröffentlicht in: | The Journal of ecology 2017-11, Vol.105 (6), p.1750-1765 |
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Zusammenfassung: | 1. It is becoming increasingly clear that plant roots can impact the decomposition of existing soil dependent, but whether this is the case in natural conditions or what factors underlie this variation is mostly unknown. 2. With a novel field-based isotopic approach combining ¹³C-enriched glucose and 5-bromo-2-deoxyuridine additions, we compared in situ C decomposition of added labile and native soil C (priming) among eight semi-arid grassland species' rhizospheres to investigate the factors driving inter-species variation. We examined the influence of several rhizosphere factors related to soil chemistry, microbial activity, microbial community, microbial stoichiometry, plant chemistry and root morphology. 3. Plant species generated distinct microbial and chemical rhizosphere environments, which translated into differences in the direction, magnitude and temporal dynamics of the soil C priming. Soil C decomposition was positively related to soil C/P and soil N/P (via its influence on the bacterial community), which in turn were positively related to plant N/P. Plant C/N was also a significant factor via its negative influence on soil N/P. In contrast, the main direct predictors of labile decomposition were microbial biomass, microbial C/N and the C-degrading enzymes, which in turn were linked to root morphology and C chemistry. 4. Synthesis. Within this community, plant species' rhizospheres can vary in their susceptibility to C loss in response to changes in C availability. Soil stoichiometry, driven by plant chemical traits, appeared to be the strongest driver of priming. Our study suggests that shifts in plant communities involving increases in N relative to P have the greatest potential to lead to C loss. We provide evidence of root morphology and C chemistry as drivers of labile C processing in soil, a novel empirical contribution to our understanding of the role of plant traits below-ground. The contrasting regulation of different pools of soil C suggests observations of the regulation of simple C compounds should not be extrapolated to the whole C pool. Our findings provide support for rhizosphere-driven mechanisms by which shifts in plant community composition could have implications on the ecosystem-level C balance. |
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ISSN: | 0022-0477 1365-2745 |
DOI: | 10.1111/1365-2745.12772 |