Deciphering the role of autophagy under Cd toxicity in Arabidopsis thaliana

Cadmium (Cd) is a toxic pollutant in soil and water affecting plants, animals, and humans. Autophagy, a cellular recycling process, is crucial for different biotic and abiotic plant stress responses. This study explores the autophagy role in Arabidopsis under Cd stress, using wild-type, autophagy-deficient mutants ( atg5 , and atg7 ) and overexpressing lines ( 35S:ATG5 , 35S:ATG7) . Cd exposure induced autophagy, as evidenced by ATG8a and ATG8a-PE accumulation, GFP-ATG8a fluorescence, and upregulation of ATG genes and proteins. Responses differed between Col-0 and Ws backgrounds, with Ws showing higher Cd tolerance. atg5 mutants were more sensitive to Cd, indicating the autophagy protective role, whereas ATG5/ATG7 overexpression did not significantly enhance Cd tolerance. Although oxidative stress may activate autophagy, ATG5/ATG7 overexpression did not significantly change the oxidative stress response. Notably, atg5 mutants displayed marked disruptions in metal/ion homeostasis under control and Cd conditions, reinforcing autophagy’s role inion homeostasis. In contrast, atg7 showed no significant differences from its WT (Ws), suggesting genotype-specific effects. Transcriptional analysis of metal transporters and ion flux analyses indicates that autophagy can regulate metal/ion accumulation through transcriptional control and post-translational modifications (e.g., ROS) with a differential response being observed between Ws and Col-0 plants.