Cotton adapts to Na2SO4 stress by regulating the metabolic intensity and distribution of metabolites in roots and leaves

Abstract

Significant Na2SO4 stress severely restricts cotton production in Xinjiang. However, the tolerance mechanism of cotton to Na2SO4 stress is not yet fully understood. This study set up two treatments, normal soil (control, CK) and Na2SO4 stress (Na2SO4, SS), to explore the effects of Na2SO4 stress on the physiological metabolism of cotton leaves and roots. Compared with CK, the total biomass and net photosynthetic stress rate decreased significantly (P < 0.05) by 49.0 and 14.7%, respectively. Additionally, the relative conductivity, malondialdehyde content, superoxide dismutase, peroxidase, and catalase activities of leaves increased significantly by 114.5, 99.8, 160, 16.8, and 117%, respectively. A tandem mass tag (TMT) proteomics analysis identified 319 and 583 differentially expressed proteins in roots and leaves, respectively. They mainly participate in amino acid metabolism, such as alanine, aspartic acid, and glutamate metabolism; histidine metabolism; tyrosine metabolism; tryptophan metabolism; energy metabolism, such as glycolysis; the tricarboxylic acid cycle; phosphorus oxide metabolism; lipid metabolism, such as fatty acid biosynthesis; glycerol phospholipid metabolism; steroid biosynthesis; and steroid hormone biosynthesis. Metabolomic data also showed significant changes in amino acid metabolism, organic acid metabolism, and carbohydrate metabolism in the roots and leaves. Na2SO4 stress inhibited metabolism in cotton roots but promoted metabolism in cotton leaves. Under Na2SO4 stress, cotton may prioritize the use of limited photosynthetic products to maintain the health and life activities of its leaves, while also transporting some organic matter from the leaves to the roots to maintain normal metabolic activity of the roots.