Linking rhizosphere processes across scales: Opinion

Schnepf, Andrea; Carminati, Andrea; Ahmed, Mutez Ali; Ani, M.; Benard, Pascal; Bentz, Jonas; Bonkowski, Michael; Brax, Mathilde; Diehl, Dörte; Duddek, Patrick; Kroener, Eva; Javaux, Mathieu; Landl, Magdalena; Lehndorff, Eva; Lippold, Eva; Lieu, Alice; Cw, Mueller; Oburger, Eva; Otten, Wilfred; Phalempin, Maxime; Prechtel, Alexander; Schulz, Raphael; Vanderborght, Jan; Vetterlein, Doris

doi:10.1101/2021.07.08.451655

Cited by 7 publications

(6 citation statements)

References 82 publications

(78 reference statements)

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“…Although the opposite has also been shown (Ruehr et al ., 2009), these studies mostly measured C allocation as root growth or exudation at the root‐branch level but did not assess whether C exudation at the root‐system and tree levels also increased. Extending root C exudation to larger scales helps to identify processes related to the up‐ and downregulation of exudation at the whole‐tree level and the linkage to rhizosphere characteristics (Prescott et al ., 2020; Schnepf et al ., 2022). Given the potential ecological benefits of belowground C allocation in the forest´s capacity to recover from drought (Hagedorn et al ., 2016) and for tree drought tolerance (Carminati et al ., 2016), we hypothesized that trees would increase the partitioning of C from net photosynthesis into root exudation under drought.…”

Section: Discussionmentioning

confidence: 99%

Carbon allocation to root exudates is maintained in mature temperate tree species under drought

et al. 2022

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Carbon (C) exuded via roots is proposed to increase under drought and facilitate important ecosystem functions. However, it is unknown how exudate quantities relate to the total C budget of a drought-stressed tree, that is, how much of net-C assimilation is allocated to exudation at the tree level.We calculated the proportion of daily C assimilation allocated to root exudation during early summer by collecting root exudates from mature Fagus sylvatica and Picea abies exposed to experimental drought, and combining above-and belowground C fluxes with leaf, stem and fine-root surface area.Exudation from individual roots increased exponentially with decreasing soil moisture, with the highest increase at the wilting point. Despite c. 50% reduced C assimilation under drought, exudation from fine-root systems was maintained and trees exuded 1.0% (F. sylvatica) to 2.5% (P. abies) of net C into the rhizosphere, increasing the proportion of C allocation to exudates two-to three-fold. Water-limited P. abies released two-thirds of its exudate C into the surface soil, whereas in droughted F. sylvatica it was only one-third.Across the entire root system, droughted trees maintained exudation similar to controls, suggesting drought-imposed belowground C investment, which could be beneficial for ecosystem resilience.

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Section: Discussionmentioning

confidence: 99%

Carbon allocation to root exudates is maintained in mature temperate tree species under drought

et al. 2022

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“…However, the rhizosphere constitutes hotspots of soil microbial activity and rhizodeposition has a role in the priming effect and soil aggregation (e.g., Baumert et al, 2018). Current advances in modelling and experimental methods offer new opportunities to quantify the rhizosphere at microscopic scales and advance new insights into how these microscopic processes impact across scales, and current challenges in the rhizosphere (Schnepf et al, 2022). Microscale models could help in quantifying the respective role of detritusphere and rhizosphere in SOM decomposition and greenhouse gas production.…”

Section: Discussionmentioning

confidence: 99%

Understanding the joint impacts of soil architecture and microbial dynamics on soil functions: Insights derived from microscale models

Pot

Portell

Otten

et al. 2022

European J Soil Science

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Over the last decades, a new generation of microscale models has been developed to simulate soil microbial activity. An earlier article (Pot et al., 2021) presented a detailed review of the description of soil architecture and microbial dynamics in these models. In the present article, we summarise the main results obtained by these models according to six model outputs: growth and spatial organisation of microbial colonies, soil hydraulic conductivity, coexistence and trophic interactions of microorganisms, temporal dynamics of the amount of solid and dissolved organic matter in soil and, microbial production of CO 2 . For each of these outputs, we draw particular attention to the respective roles of soil architecture and microbial dynamics, and we report how microscale models allow for disentangling and quantifying them. We finally discuss limitations and future directions of microscale models in combination with the on-going development of highperformance imaging tools revealing the spatial heterogeneity of the actors of soil microbial activity. Highlights• We review the insights on soil functions derived from microscale models of soil microbial processes.• Microscale models disentangle the complex interactions between soil architecture and microbial dynamics.• Spatial accessibility of resources to microbes, growth and ecological interactions are key factors in soil functions.• Translation of knowledge of interactions at the microscopic scale into larger scales is still in its infancy.

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“…In addition to the focus on individual rhizosphere compounds, it is important to consider the interplay between multitudes of processes taking place in the rhizosphere at various spatial and temporal scales (Schnepf et al., 2022). For instance, plants can alter their rhizosphere by releasing organic substances that affect the hydraulic and/or chemical nature of the soil surrounding them.…”

Section: Water and Nutrient Dynamics At The Plant Scalementioning

confidence: 99%

Soil water status shapes nutrient cycling in agroecosystems from micrometer to landscape scales

Bauke

Amelung

Bol

et al. 2022

J. Plant Nutr. Soil Sci.

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Soil water status, which refers to the wetness or dryness of soils, is crucial for the productivity of agroecosystems, as it determines nutrient cycling and uptake physically via transport, biologically via the moisture‐dependent activity of soil flora, fauna, and plants, and chemically via specific hydrolyses and redox reactions. Here, we focus on the dynamics of nitrogen (N), phosphorus (P), and sulfur (S) and review how soil water is coupled to the cycling of these elements and related stoichiometric controls across different scales within agroecosystems. These scales span processes at the molecular level, where nutrients and water are consumed, to processes in the soil pore system, within a soil profile and across the landscape. We highlight that with increasing mobility of the nutrients in water, water‐based nutrient flux may alleviate or even exacerbate imbalances in nutrient supply within soils, for example, by transport of mobile nutrients towards previously depleted microsites (alleviating imbalances), or by selective loss of mobile nutrients from microsites (increasing imbalances). These imbalances can be modulated by biological activity, especially by fungal hyphae and roots, which contribute to nutrient redistribution within soils, and which are themselves dependent on specific, optimal water availability. At larger scales, such small‐scale effects converge with nutrient inputs from atmospheric (wet deposition) or nonlocal sources and with nutrient losses from the soil system towards aquifers. Hence, water acts as a major control in nutrient cycling across scales in agroecosystems and may either exacerbate or remove spatial disparities in the availability of the individual nutrients (N, P, S) required for biological activity.

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Linking rhizosphere processes across scales: Opinion

Cited by 7 publications

References 82 publications

Carbon allocation to root exudates is maintained in mature temperate tree species under drought

Carbon allocation to root exudates is maintained in mature temperate tree species under drought

Understanding the joint impacts of soil architecture and microbial dynamics on soil functions: Insights derived from microscale models

Soil water status shapes nutrient cycling in agroecosystems from micrometer to landscape scales

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