Foliar-applied zinc promotes cadmium allocation from leaf surfaces to grains in rice

J Environ Sci (China). 2025 May:151:582-593. doi: 10.1016/j.jes.2024.04.033. Epub 2024 Apr 27.

Abstract

The accumulation of Cd by rice poses significant health risks. Foliar fertilization with Zn can reduce grain Cd contents in rice grown in Cd-contaminated soils. However, atmospheric deposition on leaves is another vector of Cd contamination, and it remains unclear how Zn application affects the allocation of such Cd. We conducted an experiment where the flag leaves of rice plants were treated with solutions with various Zn concentrations and a constant Cd concentration. The 111Cd stable isotope was used to trace the flux of foliar-applied Cd. Higher levels of foliar-applied Zn enhanced Cd efflux and grain allocation. This is attributed to limited sequestration of foliar-applied Cd in the leaf cell symplasm and increased Cd desorption from leaf cell walls when a high Zn2+ concentration occurs in the apoplast. Nonionic Zn oxide nanoparticles mitigated these effects. Additionally, the expressions of OsLCT1 and OsZIP7 in flag leaves and OsHMA2 and OsZIP7 in the uppermost nodes were upregulated under high-Zn2+ treatment, which may facilitate Cd phloem loading and grain allocation. Caution is advised in using foliar Zn in areas with high atmospheric Cd due to potential grain-contamination risks.

Keywords: Atmospheric deposition; Cell wall; Isotope labelling; Metal interaction; Phloem.

MeSH terms

  • Cadmium* / metabolism
  • Cadmium* / toxicity
  • Edible Grain / drug effects
  • Edible Grain / metabolism
  • Oryza* / drug effects
  • Oryza* / metabolism
  • Plant Leaves* / drug effects
  • Plant Leaves* / metabolism
  • Soil Pollutants* / metabolism
  • Zinc* / metabolism

Substances

  • Cadmium
  • Zinc
  • Soil Pollutants