Variations in some metabolic compounds in the roots of rice varieties (Oryza sativa L.) with different salinity tolerance under salinity stress during the seedling stage

• Published in: Plant Physiology Reports Vol. 29; no. 3; pp. 660 - 677
• Main Authors: Quoc, Cuong Duong, Lan, Anh Bui, Ngoc, Tuan Nguyen, Le Hong, Thia, Thanh, Truc Tran, Tran, Gia-Buu, Hoa, Son Pham, Hung, Thinh Nguyen, Ngoc, Tuan Nguyen Huu, Cong, Ha Nguyen, Le, Ngoc Nguyen Thi, Ngoc, Nam Trinh
• Format: Journal Article
• Language: English
• Published: New Delhi Springer India 01.09.2024
• Subjects: Biomedical and Life Sciences; Cell Biology; Life Sciences; Original Article; Plant Biochemistry; Plant Ecology; Plant Genetics and Genomics; Plant Physiology; Plant Sciences; L.; Salt stress; Phenolic compounds; Organic acids; Sugars; Rice
• ISSN: 2662-253X; 2662-2548
• DOI: 10.1007/s40502-024-00804-5

Salinity stress exerts a significant influence on plant growth and productivity, underscoring the critical importance of comprehending how plants react to stressors. Rice, as a fundamental global food source, is particularly susceptible to salt stress during its early developmental stages. This study employs both qualitative (GC–MS) and quantitative (HPLC) analyses to assess metabolic compounds in the roots of five rice varieties exhibiting varying degrees of salt tolerance during the seedling phase under NaCl-induced stress. The objectives are multifaceted: to ascertain alterations in these compounds and to delineate their metabolic profiles across biochemical pathways. The findings demonstrate that metabolite levels undergo fluctuations corresponding to NaCl concentration, and these fluctuations vary among the rice varieties examined. Specifically, the study identified 44 metabolites, comprising 23 organic acids, 18 sugars, and 3 amino acids. Furthermore, we quantified the concentrations of several key compounds, which play a crucial role in osmotic balance, oxidative balance, and precursors for synthesizing other compounds, such as 9 sugars (mannose, ribose, rhamnose, glucuronic acid, glucose, galactose, xylose, arabinose, and fucose), 6 acids in the group of phenolic compounds (gallic, chlorogenic, caffeic, syringic, ferulic, and salicylic acids), two compounds (rutin and quercetin) and 12 organic acids (D-gluconic, 2-ketogluconic, nicotic, pyruvic, succinic, malic, itaconic, dimethyl fumarate, trans-aconitic, quinic, shikimic, and malonic) were elucidated. These findings partly contribute to understanding the mechanism and important compounds participating in the NaCl stress response mechanism. Those also illustrate the coordination and interrelationship of metabolites with metabolic and biosynthetic processes to help rice adapt to NaCl stress.