Root Exudation of Primary Metabolites: Mechanisms and Their Roles in Plant Responses to Environmental Stimuli

Canarini, Alberto; Kaiser, Christina; Merchant, Andrew; Richter, Andreas; Wanek, Wolfgang

doi:10.3389/fpls.2019.00157

Cited by 663 publications

(524 citation statements)

References 215 publications

(292 reference statements)

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“…New Phytologist the associated priming effect respond to N deficiency (Dijkstra et al, 2013;Canarini et al, 2019). A low SON concentration increases the diffusion-driven (passive) exudation by a steeper concentration gradient between root cells and soil environment, which leads to increased exudation per unit root biomass at low N supply (Paterson & Sim, 2000).…”

Section: Researchmentioning

confidence: 99%

Root exudation of mature beech forests across a nutrient availability gradient: the role of root morphology and fungal activity

et al. 2020

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Summary Root exudation is a key plant function with a large influence on soil organic matter dynamics and plant–soil feedbacks in forest ecosystems. Yet despite its importance, the main ecological drivers of root exudation in mature forest trees remain to be identified. During two growing seasons, we analyzed the dependence of in situ collected root exudates on root morphology, soil chemistry and nutrient availability in six mature European beech (Fagus sylvatica L.) forests on a broad range of bedrock types. Root morphology was a major driver of root exudation across the nutrient availability gradient. A doubling of specific root length exponentially increased exudation rates of mature trees by c. 5‐fold. Root exudation was also closely negatively related to soil pH and nitrogen (N) availability. At acidic and N‐poor sites, where fungal biomass was reduced, exudation rates were c. 3‐fold higher than at N‐ and base‐richer sites and correlated negatively with the activity of enzymes degrading less bioavailable carbon (C) and N in the bulk soil. We conclude that root exudation increases on highly acidic, N‐poor soils, in which fungal activity is reduced and a greater portion of the assimilated plant C is shifted to the external ecosystem C cycle.

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Section: Researchmentioning

confidence: 99%

Root exudation of mature beech forests across a nutrient availability gradient: the role of root morphology and fungal activity

et al. 2020

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“…Second, drought has been shown to increase the concentration of secondary metabolites in root exudates (Gargallo-Garriga et al, 2018), which might stimulate specific microbial functional groups and reduce others, which could potentially result in increased N availability for plant uptake (Liu et al, 2015;Czaban et al, 2018). Third, plants might increase the exudation of organic acids to mobilize inorganic P and thus increase plant P uptake during regrowth (Canarini et al, 2019); several studies show that organic acids have the potential to prime the decomposition of soil organic C (Falchini et al, 2003;Brant et al, 2006). Strikingly, the total respiration derived from root exudates was similar under control and drought conditions, suggesting that the effect on respiration of the change in root exudate quality compensated for the reduction in root exudate quantity.…”

Section: Researchmentioning

confidence: 99%

Changes in root‐exudate‐induced respiration reveal a novel mechanism through which drought affects ecosystem carbon cycling

et al. 2019

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Summary Root exudates play an important role in ecosystem response to climate change, but the functional consequences of drought‐induced changes in the quality of root exudates are unknown. Here, we addressed this knowledge gap in a unique experimental approach. We subjected two common grassland species that differ widely in their growth strategies and root systems, the grass Holcus lanatus and the forb Rumex acetosa, to 2 wk of drought. We collected root exudates and soils at the end of the drought and after 2 wk of recovery and readded all root exudates to all soils in a fully reciprocal set‐up to measure root‐exudate‐induced respiration. We found that soil treatment was unimportant for determining root‐exudate‐induced respiration. By contrast, root exudates collected from plants that had experienced drought clearly triggered more soil respiration than exudates from undroughted plants. Importantly, this increased respiration compensated for the lower rates of root exudation in droughted plants. Our findings reveal a novel mechanism through which drought can continue to affect ecosystem carbon cycling, and a potential plant strategy to facilitate regrowth through stimulating microbial activity. These findings have important implications for understanding plant and ecosystem response to drought.

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“…Metabolites secreted into the rhizosphere are degraded by microbes and adsorbed onto soil organic matter and clay minerals, depending on the soil type and microbes present (Canarini, Kaiser, Merchant, Richter, & Wanek, 2019;Soma & Soma, 1989;Sugiyama, 2019). In order to gain insight into daidzein distribution in soybean fields, we used grey lowland soils obtained from a soybean farm where soybeans had been cultivated for more than 5 years.…”

Section: Simulation Of Daidzein Distributionmentioning

confidence: 99%

Rhizosphere modelling reveals spatiotemporal distribution of daidzein shaping soybean rhizosphere bacterial community

Okutani

Hamamoto

Aoki

et al. 2020

Plant Cell & Environment

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Plant roots nurture a wide variety of microbes via exudation of metabolites, shaping the rhizosphere's microbial community. Despite the importance of plant specialized metabolites in the assemblage and function of microbial communities in the rhizosphere, little is known of how far the effects of these metabolites extend through the soil. We employed a fluid model to simulate the spatiotemporal distribution of daidzein, an isoflavone secreted from soybean roots, and validated using soybeans grown in a rhizobox. We then analysed how daidzein affects bacterial communities using soils artificially treated with daidzein. Simulation of daidzein distribution showed that it was only present within a few millimetres of root surfaces. After 14 days in a rhizobox, daidzein was only present within 2 mm of root surfaces. Soils with different concentrations of daidzein showed different community composition, with reduced α‐diversity in daidzein‐treated soils. Bacterial communities of daidzein‐treated soils were closer to those of the soybean rhizosphere than those of bulk soils. This study highlighted the limited distribution of daidzein within a few millimetres of root surfaces and demonstrated a novel role of daidzein in assembling bacterial communities in the rhizosphere by acting as more of a repellant than an attractant.

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Root Exudation of Primary Metabolites: Mechanisms and Their Roles in Plant Responses to Environmental Stimuli

Cited by 663 publications

References 215 publications

Root exudation of mature beech forests across a nutrient availability gradient: the role of root morphology and fungal activity

Root exudation of mature beech forests across a nutrient availability gradient: the role of root morphology and fungal activity

Changes in root‐exudate‐induced respiration reveal a novel mechanism through which drought affects ecosystem carbon cycling

Rhizosphere modelling reveals spatiotemporal distribution of daidzein shaping soybean rhizosphere bacterial community

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