Center for Agricultural Water Research in China, China Agricultural University, Beijing 100083, China; Shiyanghe Experimental Station for Improving Water Use Efficiency in Agriculture, Ministry of Agriculture and Rural Affairs, Ministry of Education and Gansu Government, Wuwei, Gansu Province 733009, China.
School of Natural Resources, University of Missouri, Columbia, MO 65211, USA.
Sci Total Environ. 2022 Jan 20;805:150364. doi: 10.1016/j.scitotenv.2021.150364. Epub 2021 Sep 16.
Water and salt stress often occur simultaneously in heavily irrigated arid agricultural areas, yet they are usually studied in isolation. To understand the physiological bases of water use efficiency (WUE) of field-grown maize (Zea mays) at multi-scales under combined water and salt stress, we investigated the joint effects of water and salt stress on physiology, growth, yield, and WUE of two genotypes (XY335 and ZD958). We measured leaf stomatal conductance (g), net photosynthesis rate (A) and hydraulic traits, whole-plant growth and water use (ET), and final biomass and grain yield. Leaf osmotic adjustment was a key trait of the physiological differences between XY335 and ZD958 under water and salt stress. Although the responses of the two genotypes were different, mild water and salt stress improved intrinsic water use efficiency (iWUE = A/g) by (i) decreasing gvia increasing osmotic adjustment and hydraulic resistance, and (ii) declining A via increasing stomatal limitations rather than reducing photosynthetic capacity. Joint water and salt stress had a synergistic effect on reproductive growth and grain formation of maize. Mild water and salt stress reduced ET, stabilized grain yield, and improved grain WUE via declining g, maintaining photosynthetic capacity, and improving harvest index. Collectively, our study provides a novel insight into the physiological mechanisms of WUE and demonstrates an approach for the efficient management of water and salt by using a growth stage-based deficit irrigation strategy or/and selecting genotypes with strong osmotic adjustment capacity and high harvest index.
在灌溉密集的干旱农业区,水和盐胁迫通常同时发生,但它们通常是分开研究的。为了在多尺度下理解田间生长玉米(Zea mays)在水盐胁迫下的水分利用效率(WUE)的生理基础,我们研究了水盐胁迫对两种基因型(XY335 和 ZD958)的生理、生长、产量和 WUE 的联合影响。我们测量了叶片气孔导度(g)、净光合速率(A)和水力特性、整株生长和水分利用(ET)以及最终生物量和籽粒产量。叶片渗透调节是 XY335 和 ZD958 在水盐胁迫下生理差异的关键特征。尽管两种基因型的响应不同,但轻度水盐胁迫通过(i)通过增加渗透调节和水力阻力降低 g,(ii)通过增加气孔限制而不是降低光合能力来降低 A,从而提高内在水分利用效率(iWUE = A/g)。水盐胁迫联合对玉米生殖生长和籽粒形成有协同作用。轻度水盐胁迫通过降低 g、维持光合能力和提高收获指数来减少 ET、稳定籽粒产量和提高籽粒 WUE。总之,本研究为 WUE 的生理机制提供了新的见解,并展示了一种通过基于生长阶段的亏缺灌溉策略或/和选择具有较强渗透调节能力和高收获指数的基因型来有效管理水盐的方法。
