The reprogramming of mitochondrial energy metabolism in Rice: The role of the TCA cycle and GABA shunt under Arsenic exposure

Abstract Arsenic (As) pollution is hazardous for all living organisms. Plants growing in As‐contaminated soil are less performant. Recently, seed priming has attracted significant attention for its beneficial effects on plants. Numerous studies have associated priming technique with the induction of stress memory against traumatic conditions, but its relation to crop's energy balance is under‐researched. The present study highlights variations in energy metabolic pathways, particularly TCA (tricarboxylic acid) cycle and GABA (gamma‐aminobutyric acid)‐shunt in multi‐nutrient [silicon (Si), iron (Fe), zinc (Zn), and ascorbic acid (AA)] primed rice seedlings under As stress. Arsenic exposure decreased the TCA cycle enzymes' activity while intensifying GABA accumulation and metabolism. This enhancement in GABA shunt provides an alternative energy source for As‐stressed seedlings. However, priming and further Fe‐supplementation reduced As‐toxicity by accelerating the activity of both energy pathways, namely, TCA and GABA cycle. Improved energy regulation by priming and Fe‐augmentation also enhanced the functionality of anabolic respiratory‐interactive‐pathway, i.e., carbon‐nitrogen metabolism. The As‐tolerance response of priming and Fe‐augmentation was further analyzed from the expression profiling of nitrogen and phosphorous utilization genes. Out of 10 genes, particular enhancement was observed in OsNiR, OsGS, and OsGOGAT expression with improved macro‐micronutrient content of the seedlings. Thus, irrespective of As infestations, multi‐nutrient (Si, Fe, Zn, and AA) seed priming approach along with Fe‐supplementation may emerge as a beneficial strategy to improve plant metabolic capacity in terms of nitrogen, phosphorous, and carbon assimilation to support normal vigor because they balance cellular energy levels.