Fig. 1. Phenotype, cadmium (Cd) accumulation, root cell wall Cd fixation capacity, nitric oxide (NO) accumulation, and effect of NO inhibitor cPTIO on Cd accumulation of Tianyouhuazhan (TYHZ) and Xiushui 14 (XS14) plants. A, Soil Cd content between two rice cultivars in field experiments in 2021 and 2022. B, Rice grain Cd content between two rice cultivars in field experiments in 2021 and 2022. C, Growth performances of two rice cultivars after treated with (+Cd) or without (-Cd) 1 μmol/L Cd. Scale bar, 5 cm. D, Root elongation of two rice cultivars with or without 1 μmol/L Cd treatments. E and F, Root (E) and shoot (F) biomass of two rice cultivars with or without 1 μmol/L Cd treatments. G and H, Accumulation of Cd in roots (G) and shoots (H) of two rice cultivars treated with or without 1 μmol/L Cd. I, The ratio of Cd accumulation in the shoots to the roots of two rice cultivars when treated with or without 1 μmol Cd. J, The amount of Cd in the xylem of two rice cultivars treated with or without 1 μmol/L Cd. K‒M, Cd concentrations in the root cell walls (K), hemicellulose (L), and pectin (M). N‒P, Cd concentrations in the shoot cell walls (N), hemicellulose (O), and pectin (P). Q, Production of NO after subjected to either 1 μmol/L Cd or Cd-free treatment. Scale bars, 1 mm. R, Relative fluorescence intensity (percentage of -Cd production) of NO production. S and T, Cd content in roots (S) and shoots (T) after two rice cultivar seedlings were given a 1 μmol/L Cd treatment with or without cPTIO. Data are Mean ± SD (n = 2‒32 in A and B, 5 in D to F, 3 in G to J, and 4 in K to P, and R to T). The lowercase letters and asterisks above the bars indicate significant differences at P < 0.05.