Optimized silicon fertilization regime weakens cadmium translocation and increases its biotransformation in rice tissues

• Published in: The Crop journal Vol. 12; no. 4; pp. 1041 - 1053
• Main Authors: Pan, Bogui, Cai, Yixia, Cai, Kunzheng, Tian, Jihui, Wang, Wei
• Format: Journal Article
• Language: English
• Published: Beijing Elsevier B.V 01.08.2024; KeAi Publishing Communications Ltd
• Subjects: Agricultural production; Biotransformation; Cadmium; Cell walls; Chelation; Detoxification; Fertilization; Fertilizers; Flavonoids; Food; Grain; Growth stages; Heavy metals; Jointing; Phenols; Phytic acid; Potassium; Proteins; Rice; Rice fields; Safety production; Silicon; Toxicity; Translocation; Translocation and accumulation; Xylem; China; Cadmium; Translocation and accumulation; Safety production; Silicon; Growth stages; Rice
• ISSN: 2214-5141; 2095-5421; 2214-5141
• DOI: 10.1016/j.cj.2024.05.014

In acidic paddy fields of South China, rice (Oryza sativa L.) faces the dual challenges of cadmium (Cd) toxicity and silicon (Si) deficiency. Although previous studies have highlighted the functions of Si application timing and strategies in mitigating Cd-stressed rice, the precise mechanisms underlying the health restoration of Cd-toxic rice and the assurance of grain safety remain elusive. This study explored Cd translocation and detoxification in the shoots of rice regulated by various Si fertilization regimes: Si(T) (all Si added before transplanting), Si(J) (all Si added at jointing), and Si(TJ) (half Si added both before transplanting and at jointing). The findings revealed that the regime of Si(TJ) was more beneficial to rice health and grain safety than Si(T) and Si(J). The osmotic regulators such as proline, soluble sugars, and soluble proteins were significantly boosted by Si(TJ) compared to other Si treatments, and which enhanced membrane integrity, balanced intracellular pH, and increased Cd tolerance of rice. Furthermore, Si(TJ) was more effective than Si(T) and Si(J) on the Cd sequestration in the cell wall, Cd bio-passivation, and the down-regulated expression of the Cd transport genes. The concentrations of Cd in the xylem and phloem treated with Si(TJ) were reduced significantly. Additionally, Si(TJ) facilitated much more Cd bound with the outer layer proteins of grains, and promoted Cd chelation and complexation by phytic acid, phenolics, and flavonoids. Overall, Si (TJ) outperformed Si(T) and Si(J) in harmonizing the phycological processes, inhibiting Cd translocation, and enhancing Cd detoxification in rice plant. Thereby the split Si application strategy offers potential for reducing Cd toxicity in rice grain.