Abstract
Rice is susceptible to salt stress at the seedling stage. To explore the molecular mechanisms underlying salt tolerance, the metabolic responses to salt stress were investigated with a metabolite-profiling technique. Gas chromatography–mass spectrometry was used to profile metabolite changes in five rice lines with a similar genetic background, but with obviously diverse growth performances under saline conditions. A total of 84 metabolites were detected in rice leaf extracts under control and saline conditions. The data revealed that amino acids were enriched more in three salt-tolerant lines (G58, G1710, and IR64) than in two salt-sensitive lines (G45 and G52) under control conditions, suggesting that there were basal metabolite differences between the tolerant and sensitive lines. Additionally, significantly higher allantoin levels in G58, G1710, and IR64 under both stress and control conditions were observed, implying allantoin was important for the better growth of the three rice lines. Moreover, sorbitol, melezitose, and pipecolic acid levels increased considerably in response to salt stress in the five lines, indicating they contribute to rice responses to salt stress significantly. Interestingly, the similar metabolic patterns were regulated by salt stress in the salt-sensitive and salt-tolerant lines, and the main difference was quantitative. The sensitive lines had more pronounced increases during the early stages of the stress treatment than the tolerant lines. Thus, monitoring the metabolome changes of plants may provide crucial insights into how plants tolerate stress. The results presented herein provide valuable information for further elucidating the molecular mechanisms underlying rice salt tolerance.
Highlights
Salt stress is a major constraint in many rice-producing regions because modern rice varieties are highly sensitive to this abiotic stress especially at the seedling and floweringElectronic supplementary material The online version of this article contains supplementary material, which is available to authorized users.Plants under saline conditions are exposed to hyperosmotic and hyperionic stresses, resulting in considerable productivity losses (Singh et al 2017; Anwar et al 2016)
We identified 84 metabolites based on gas chromatography-mass spectrometry (GC–MS) technology, and observed that the abundance of most metabolites significantly increased under saline conditions
An analysis of plants grown under control conditions revealed the SDW and RDW were significantly higher for G58, G1710, and IR64 than for G45 and G52
Summary
Plants under saline conditions are exposed to hyperosmotic and hyperionic stresses, resulting in considerable productivity losses (Singh et al 2017; Anwar et al 2016). This ion-specific toxicity results mostly from altered ratios of potassium and sodium ions (K+/Na+) and/or N a+ and chloride (Cl−) concentrations that adversely affect cellular. One of the essential mechanisms underlying salt tolerance in plants involves decreasing the effects of ionic stress by minimizing the Na+ accumulation in the cytosol, in the transpiring leaves (Sharma et al 2016). Avoiding ion accumulation and osmotic stress are important features of salt stress tolerance
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