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Chelation and nanoparticle delivery of monomeric dopamine to increase plant salt stress resistance

Jiang Du, Hua‐Zhen Xu, Da‐xia Zhang, Shouqian Feng

2025Nature Communications24 citationsDOIOpen Access PDF

Abstract

Soil salinization hinders sustainable development of global agriculture. Dopamine (DA) delivery is promising for mitigating the detrimental effects of salt on plants. However, self-polymerization limits delivery and effectiveness. Here we chelated DA with ethylenediamine tetraacetic acid and zinc to reduce self-polymerization. To reduce soil adsorption, a sodium lignosulfonate and octadecyl dimethyl benzyl ammonium chloride nanocarrier is made for delivery to the plant. Compared with DA monomer, the soil adsorption rate of the DA in the nanocarrier is 46.02% lower. Salt stress experiments reveal, compared with NaCl and DA groups, the nanocarrier group exhibits significant increases in growth indicators for tomato plants. The beneficial effect is attributed to the increases in proline content, antioxidant capacity, and K+/Na+ ratios in the plants. Similar results are also observed with woody pear seedlings. These findings provide insights into alleviating crop salt stress. Soil salinisation hinders sustainable development of global agriculture. Here the authors report on a carrier designed to delivery dopamine to plants to improve salt resistance, avoiding dopamine self-polymerisation and soil adsorption, demonstrating increased tomato and pear seedling growth under salt stress.

Topics & Concepts

ChelationDopamineNanoparticleSalt (chemistry)Stress (linguistics)ChemistryNanotechnologyMaterials scienceMedicineInternal medicineInorganic chemistryOrganic chemistryLinguisticsPhilosophyCarbon and Quantum Dots ApplicationsPolymer-Based Agricultural EnhancementsNanoparticles: synthesis and applications
Chelation and nanoparticle delivery of monomeric dopamine to increase plant salt stress resistance | Litcius