Radiation-induced lysosomal iron reactivity: implications for radioprotective therapy

Abstract

A novel mechanism of radiosensitization involves radiation-enhanced autophagy of damaged mitochondria and various metalloproteins, by which iron accumulates within lysosomes. Hydrogen peroxide, formed by the radiolytic cleavage of water, generates in the presence of lysosomal redox-active iron extremely reactive hydroxyl radicals by Fenton-type chemistry. Subsequent peroxidative damage of lysosomal membranes initiates release of harmful content from ruptured lysosomes that triggers a cascade of events eventuating in DNA damage and apoptotic or necrotic cell death. This article reviews the role of lysosomal destabilization in radiation-induced cell damage and death. The potential effects of iron chelation therapy targeted to the lysosomes for protection of normal tissues against unwanted effects by radiation is also discussed.