University of Natural Resources and Life Sciences, Department of Forest and Soil Science, Institute of Soil Research, Konrad-Lorenz Strasse 24, Tulln an der Donau 3430, Austria; University of Natural Resources and Life Sciences, Department of Applied Genetics and Cell Biology, Institute of Molecular Plant Biology, Muthgasse 18, 1190 Vienna, Austria.
University of Natural Resources and Life Sciences, Department of Forest and Soil Science, Institute of Soil Research, Konrad-Lorenz Strasse 24, Tulln an der Donau 3430, Austria.
Plant Sci. 2024 Feb;339:111919. doi: 10.1016/j.plantsci.2023.111919. Epub 2023 Nov 20.
Efficient micronutrient acquisition is a critical factor in selecting micronutrient dense crops for human consumption. Enhanced exudation and re-uptake of metal chelators, so-called phytosiderophores, by roots of graminaceous plants has been implicated in efficient micronutrient acquisition. We compared PS biosynthesis and exudation as a response mechanism to either Fe, Zn or Cu starvation. Two barley (Hordeum vulgare L.) lines with contrasting micronutrient grain yields were grown hydroponically and PS exudation (LC-MS) and root gene expression (RNAseq) were determined after either Fe, Zn, or Cu starvation. The response strength of the PS pathway was micronutrient dependent and decreased in the order Fe > Zn > Cu deficiency. We observed a stronger expression of PS pathway genes and greater PS exudation in the barley line with large micronutrient grain yield suggesting that a highly expressed PS pathway might be an important trait involved in high micronutrient accumulation. In addition to several metal specific transporters, we also found that the expression of IRO2 and bHLH156 transcription factors was not only induced under Fe but also under Zn and Cu deficiency. Our study delivers important insights into the role of the PS pathway in the acquisition of different micronutrients.
高效获取微量营养素是选择人类食用的富含微量营养素作物的关键因素。禾本科植物根系对金属螯合剂(即植物铁载体)的增强分泌和再吸收,被认为与高效获取微量营养素有关。我们比较了 PS 生物合成和分泌作为对 Fe、Zn 或 Cu 饥饿的反应机制。两种具有不同微量营养素籽粒产量的大麦(Hordeum vulgare L.)系在水培条件下生长,在 Fe、Zn 或 Cu 饥饿后测定 PS 分泌(LC-MS)和根系基因表达(RNAseq)。PS 途径的反应强度随微量营养素的不同而变化,Fe 缺乏时最强,Zn 和 Cu 缺乏时依次减弱。我们观察到,在具有大量微量营养素籽粒产量的大麦系中,PS 途径基因的表达和 PS 分泌更强,这表明高度表达的 PS 途径可能是参与高微量营养素积累的一个重要特征。除了几种金属特异性转运蛋白外,我们还发现 IRO2 和 bHLH156 转录因子的表达不仅在 Fe 缺乏时诱导,在 Zn 和 Cu 缺乏时也诱导。我们的研究为 PS 途径在不同微量营养素获取中的作用提供了重要的见解。
