Wanted: Micronutrients! Phytosiderophore-mediated acquisition strategies in grass crops

Understanding how plants respond to micronutrient deficiency and which biogeochemical processes are induced at the root-soil interface, i.e. the rhizosphere, is crucial to improve crop yield and micronutrient grain content for high quality food and feed. Iron nutrition by grass species relies on the release and re-uptake of phytosiderophores, which are root exudates that form stable complexes with Fe but also other trace metals such as Zn and Cu. However, neither the importance of phytosiderophores under Zn and Cu deficient conditions nor the interplay of plant responses and rhizosphere processes are well understood as the majority of studies in the past was carried out under ‘soil-free’ hydroponic conditions. In this project, I aim to elucidate the mechanisms controlling phytosiderophore-mediated micronutrient acquisition of barley (Hordeum vulgare) under Zn, Cu, and as reference, Fe deficient conditions, with particular emphasis on soil environments. Barley is the fifth most produced crop worldwide and of great importance in regions that are characterized by harsh living conditions. In a holistic approach, my team and I will apply innovative soil-based and traditional hydroponic root exudation sampling approaches in combination with advanced plant molecular techniques to study the phytosiderophore release and uptake system under different experimental conditions. The chemical synthesis of otherwise commercially unavailable phytosiderophores in their natural and 13C-labelled form will allow us to trace their decomposition and metal solubilizing efficiency in the plant-microbe-soil system to uncover the interplay of plant genetic responses and rhizosphere processes affecting the time-window of PS-mediated MN acquisition. Moving beyond ‘soil-free’ experimental designs of the past, this project will generate key knowledge to improve selection of crops with highly efficient micronutrient acquisition traits to alleviate micronutrient malnutrition of people world-wide.

AIM 1 - Synthesize all known PS in their natural and 13C-labelled form (TU). All 8 PS were successfully synthesized within the planned period. Therefore, the first, most critical milestone of this project was achieved without any delay, with the developed synthetic strategy already being published https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/chem.202004004(s’ouvre dans une nouvelle fenêtre). Current activities focus on upscaling the developed synthesis and the implementation of the 13C label.

AIM 2 - Reveal PS release, re-uptake and molecular responses of contrasting barley cultivars under Zn, Cu and as a reference Fe deficiency in different experimental conditions (BOKU).
After several test trials to select suitable barley lines (collaboration James Hutton Institute, UK) and optimize growth conditions in micronutrient (MN) deficient soils from Spain, Turkey & Australia, we are currently investigating plant micronutrient uptake and related PS exudation and gene expression of four barely lines differing in micronutrient acquisition efficiency grown in three micronutrient deficient soils (Fe, Zn, Cu) and their respective fully fertilized controls during plant development. Furthermore, we are comparing results from soil grown plant to results obtained from artificial nutrient solution culture experiments that are typically used to investigate root exudation patterns.

AIM 3 - Uncover the efficiency and dynamics of PS-metal mobilization of all known PS in bulk and rhizosphere soil (BOKU).
A prerequisite to study phytosiderophores is the development and implementation of reliable analytical approaches to accurately quantify PS. Using our synthesized PS, we successfully adapted and implemented an LC-MS/MS based method to measure PS concentrations in biological samples. We are now starting to investigate geochemical interactions of PS with micronutrient deficient soils.

AIM 4 - Elucidate the partitioning dynamics of PS in the plant-soil-microbe system and identify the key microbial players involved (BOKU, UNIVIE). Experimental work is scheduled to start in Oct 2021.

- Successful development and implementation of a novel, unified, modular approach to chemically synthesize all eight identified phytosiderophores (PS). This modular approach now enables the installation of 13C2 isotopic labels into the middle fragments of all PS. Having achieved the most critical milestone of this project, allows us now to investigate and trace the fate and function of PS in the plant – microbe-soil system.
- Successful development and implementation of an advanced LC-MS/MS analysis of all eight PS including the use of a 13C labelled internal standard. This milestone now allows us to accurately identify and quantify PS in root exudation and soil samples.
- In contrast to the majority of studies related to phytosiderophores, we focus on soil grown plants instead of working with artificial nutrient solution culture including methodological development to improve soil-based exudation sampling techniques. Our results will therefore deliver insights into PS -related micronutrient acquisition efficiency of barley in natural soil environments.