On the Cytoprotective Role of Ferritin in Macrophages and its Ability to Enhance Lysosomal Stability

Abstract

Macrophages have a great capacity to take up (eg. by endocytosis and phagocytosis) exogenous sources of iron which could potentially become cytotoxic, particularly following the intralysosomal formation of low-molecular weight, redox active iron, and under conditions of oxidative stress. Following autophago-cytosis of endogenous ferritin/apoferritin, these compounds may serve as chelators of such lysosomal iron and counteract the occurrence of iron-mediated intralysosomal oxidative reactions. Such redox-reactions have been shown to lead to destabilisation of lysosomal membranes and result in leakage of damaging lysosomal contents to the cytosol. In this study we have shown: (i) human monocyte-derived macrophages to accumulate ferritin in response to iron exposure; (ii) iron to destabilise macrophage secondary lysosomes when the cells are exposed to H₂O₂; and (iii) endocytosed apoferritin to act as a stabiliser of the acidic vacuolar compartment of iron-loaded macrophages. While the endogenous ferritin accumulation which was induced by iron exposure was not sufficient to protect cells from the damaging effects of H₂O₂, exogenously added apoferritin, as well as the potent iron chelator desferrioxamine, afforded significant protection. It is suggested that intralysosomal formation of haemosiderin, from partially degraded ferritin, is a protective strategy to suppress intralysosomal iron-catalysed redox reactions. However, under conditions of severe macrophage lysosomal iron-overload, induction of ferritin synthesis is not enough to completely prevent the enhanced cytotoxic effects of H₂O₂.