Key Laboratory of Plant Molecular Physiology, Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China.
China National Botanical Garden, Beijing, China.
Plant Cell Physiol. 2024 Jan 19;65(1):20-34. doi: 10.1093/pcp/pcad114.
Salinity and phosphate (Pi) starvation are the most common abiotic stresses that threaten crop productivity. Salt cress (Eutrema salsugineum) displays good tolerance to both salinity and Pi limitation. Previously, we found several Phosphate Transporter (PHT) genes in salt cress upregulated under salinity. Here, EsPHT1;5 induced by both low Pi (LP) and salinity was further characterized. Overexpression of EsPHT1;5 in salt cress enhanced plant tolerance to LP and salinity, while the knock-down lines exhibited growth retardation. The analysis of phosphorus (P) content and shoot/root ratio of total P in EsPHT1;5-overexpressing salt cress seedlings and the knock-down lines as well as arsenate uptake assays suggested the role of EsPHT1;5 in Pi acquisition and root-shoot translocation under Pi limitation. In addition, overexpression of EsPHT1;5 driven by the native promoter in salt cress enhanced Pi mobilization from rosettes to siliques upon a long-term salt treatment. Particularly, the promoter of EsPHT1;5 outperformed that of AtPHT1;5 in driving gene expression under salinity. We further identified a transcription factor EsANT, which negatively regulated EsPHT1;5 expression and plant tolerance to LP and salinity. Taken together, EsPHT1;5 plays an integral role in Pi acquisition and distribution in plant response to LP and salt stress. Further, EsANT may be involved in the cross-talk between Pi starvation and salinity signaling pathways. This work provides further insight into the mechanism underlying high P use efficiency in salt cress in its natural habitat, and evidence for a link between Pi and salt signaling.
盐度和磷酸盐(Pi)饥饿是威胁作物生产力的最常见非生物胁迫。盐荠(Eutrema salsugineum)对盐度和 Pi 限制均表现出良好的耐受性。先前,我们在盐荠中发现了几种在盐度胁迫下上调的磷酸盐转运蛋白(PHT)基因。在这里,EsPHT1;5 受低 Pi(LP)和盐度诱导,进一步进行了表征。在盐荠中过表达 EsPHT1;5 增强了植物对 LP 和盐度的耐受性,而敲低系表现出生长迟缓。EsPHT1;5 过表达盐荠幼苗和敲低系的磷(P)含量和总 P 的茎叶比以及砷酸盐摄取分析表明,EsPHT1;5 在 Pi 限制下的 Pi 吸收和根-茎转运中发挥作用。此外,在长期盐处理下,由盐荠中内源启动子驱动的 EsPHT1;5 过表达增强了 Pi 从莲座丛向蒴果的动员。特别是,EsPHT1;5 的启动子在盐度下驱动基因表达的表现优于 AtPHT1;5。我们进一步鉴定了一个转录因子 EsANT,它负调控 EsPHT1;5 的表达以及植物对 LP 和盐度胁迫的耐受性。总之,EsPHT1;5 在植物对 LP 和盐胁迫的响应中在 Pi 吸收和分布中发挥整体作用。此外,EsANT 可能参与 Pi 饥饿和盐胁迫信号通路之间的串扰。这项工作为盐荠在其自然栖息地中高磷利用效率的机制提供了进一步的见解,并为 Pi 和盐信号之间的联系提供了证据。
