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Co-localised phosphorus mobilization processes in the rhizosphere of field-grown maize jointly contribute to plant nutrition

Nataliya Bilyera, Christina Hummel, Gabrielle Daudin, Michael Santangeli, Xuechen Zhang, Jakob Santner, Eva Lippold, Steffen Schlüter, Isabelle Bertrand, Walter W. Wenzel, Sandra Spielvogel, Doris Vetterlein, Bahar S. Razavi, Eva Oburger

2021Soil Biology and Biochemistry63 citationsDOIOpen Access PDF

Abstract

Understanding phosphorus (P) dynamics in the rhizosphere is crucial for sustainable crop production. P mobilization processes in the rhizosphere include the release of plant and microbially-derived protons and extracellular phosphatases. We investigated the effect of root hairs and soil texture on the spatial distribution and intensity of P mobilizing processes in the rhizosphere of Zea mays L. root-hair defective mutant (rth3) and wild-type (WT) grown in two substrates (loam, sand). We applied 2D-chemical imaging methods in custom-designed root windows installed in the field to visualize soil pH (optodes), acid phosphatase activity (zymography), and labile P and Mn fluxes (diffusive gradients in thin films, DGT). The average rhizosphere extent for phosphatase activity and pH was greater in sand than in loam, while the presence of root-hairs had no impact. Acidification was significantly stronger at young root tissue (<2 cm from root cap) than at older root segments (>4 cm from root cap) and stronger in WT than rth3. Accompanied with stronger acidification, higher P flux was observed mainly around young, actively growing root tissues for both genotypes. Our results indicate that acidification was linked to root growth and created a pH optimum for acid phosphatase activity, i.e., mineralization of organic P, especially at young root tissues which are major sites of P uptake. Both genotypes grew better in loam than in sand; however, the presence of root hairs generally resulted in higher shoot P concentrations and greater shoot biomass of WT compared to rth3. We conclude that soil substrate had a larger impact on the extent and intensity of P solubilization processes in the rhizosphere of maize than the presence of root hairs. For the first time, we combined 2D-imaging of soil pH, phosphatase activity, and nutrient gradients in the field and demonstrated a novel approach of stepwise data integration revealing the interplay of various P solubilizing processes in situ.

Topics & Concepts

RhizosphereLoamRoot hairShootPhosphorus deficiencyChemistryMineralization (soil science)PhosphorusSeedlingAcid phosphataseAgronomyBotanyHorticultureBiologySoil waterBiochemistryEnzymeEcologyOrganic chemistryGeneticsBacteriaGenePlant nutrient uptake and metabolismCrop Yield and Soil FertilitySoil Carbon and Nitrogen Dynamics