What does this research mean for the field?

Melatonin alleviates lithium toxicity in wheat by regulating redox and potassium homeostasis. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to explore how melatonin can alleviate lithium toxicity in wheat by regulating redox levels and potassium homeostasis.

February 27, 2026Open Access

Melatonin alleviates Li toxicity in wheat via regulating redox and K+ homeostasis

Key Points

This research aims to explore how melatonin can alleviate lithium toxicity in wheat by regulating redox levels and potassium homeostasis.
Employed integrated approaches including microelectrode ion flux estimation, confocal imaging, and qPCR analysis.
Examined the effects of melatonin on ROS production, antioxidant activity, and potassium transporters in wheat under lithium stress.
Analyzed calcium signalling pathways and plasma membrane H+-ATPase activity in the presence of lithium.
Melatonin suppressed ROS production from NADPH oxidase under lithium stress.
Enhanced antioxidant activities were observed, showing improved plant resilience.
Restored potassium retention by regulating K+-efflux channels GORK and influx transporters HAK5 and AKT1.

Abstract

Lithium (Li) pollution in agricultural soils poses a significant environmental hazard, impairing crop growth by inducing oxidative stress and disrupting nutrient homeostasis. Not only does Li⁺ compete with K⁺ for uptake, but Li-induced reactive oxygen species (ROS) accumulation may potentially trigger massive K + loss via ROS-sensitive K + -efflux channels, leading to major disruption in the cell’s metabolic activity and programmed cell death. Melatonin (Mel) has emerged as a potential mitigator of abiotic stresses, but its role in regulating ROS levels and K⁺ transport under Li toxicity remains unexplored. Here, we employed an integrated approach, combining non-invasive microelectrode ion flux estimation, confocal imaging, and qPCR analysis, to demonstrate that Mel alleviates Li-induced K⁺ loss in wheat via several concurrent mechanisms: (i) suppressing NADPH oxidase ( RBOH )-derived ROS production while enhancing antioxidant activities; (2) modulating Ca²⁺ signalling by regulating Ca²⁺-ATPases ( ACA / CAX ) and CBL / CIPK ; (3) downregulating the K⁺-efflux channel GORK and upregulating influx transporters ( HAK5 , AKT1 ) to restore K⁺ retention; and (4) regulating plasma membrane H⁺-ATPase activity. Our results show that Mel simultaneously regulates ROS and K⁺ homeostasis to confer Li tolerance, providing critical insights for sustainable phytoremediation and safe crop production in Li-affected soils. • Lithium is an emerging contaminant that poses a serious threat to agriculture • Li-induced ROS accumulation and triggered K + -efflux • Melatonin suppressed RBOH -derived ROS accumulation and enhanced antioxidants under Li stress • Melatonin restores K + homeostasis by regulating plasma membrane H⁺-ATPase activity and Ca 2+ signalling

Melatonin alleviates Li toxicity in wheat via regulating redox and K+ homeostasis

Key Points

Abstract

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