Copper-transporting ATPase ATP7B and the lysosomal exocytosis pathway synergise to detoxify cadmium

Cadmium, being a highly toxic metal, perturbs cellular homeostasis by forming stable complexes with numerous thiol-active proteins, ultimately leading to severe liver and lung damage. Despite its well-documented toxicity, the molecular mechanisms governing cadmium export remain poorly understood. Given the chemical similarity between cadmium and copper, we investigated whether the canonical copper-exporting ATPases, ATP7A and ATP7B participate in cadmium handling. Upon Cd treatment in hepatocytes, ATP7B undergoes trafficking to lysosomes via the retromer complex, as also observed in the case of elevated copper, accompanied by the upregulation of acidic lysosomal populations. In contrast, ATP7A expressed in lung adenocarcinoma cells, though exhibit vesicular redistribution upon Cd exposure, does not mediate lysosomal sequestration, suggesting distinct deployment of late secretory pathways by the two copper ATPases in response to cadmium. We have also observed that ATP7B-/- hepatocytes exhibit increased sensitivity to Cd exposure compared to wild-type cells. Whereas, overexpressing the ATP7B amino-terminal copper-binding domain in bacteria alleviates cadmium-induced stress, indicating its capacity to sequester Cd. Caenorhabditis elegans lacking copper-ATPase cua-1, displayed increased Cd sensitivity, while mutants (glo-1-/-), deficient in lysosome-related organelles (LRO), and (lmp-1-/-), deficient in lysosomal membrane glycoprotein, showed reduced resistance to cadmium toxicity. Treatment of the worm with cadmium increases the abundance of lysosomes marked by elevation in lysosomal biogenesis and functional genes, reinforcing the importance of lysosomal pathways in cadmium detoxification. To summarise, we delineated the non-canonical role of copper ATPases and lysosomes in cadmium-induced cellular toxicity.