Bifunctional Anti-/Prooxidant Potential of Metallothionein: Redox Signaling of Copper Binding and Release

Abstract

Metallothioneins (MTs) are cysteine-rich metal-binding proteins that exert cytoprotection during metal exposure and oxidative stress. The roles of MT in copper (Cu) binding and release and modulation of redox cycling are unresolved. We hypothesized that Cu-binding to MT renders Cu redox inactive, but that oxidation of free thiols critical for metal binding can reduce MT/Cu interactions and potentiate Cu redox cycling. Overexpression of MT in cells by cadmium pretreatment or ectopic overexpression by gene transfer confers protection from Cu-dependent lipid oxidation and cytotoxicity. Using a chemically defined model system (Cu/ascorbate/H₂O₂) to study Cu/MT interactions, we observed that MT inhibited Cu-dependent oxidation of luminol. In the absence of H₂O₂, MT blocked Cu-dependent ascorbyl radical production with a stoichiometry corresponding to Cu/MT ratios ≤12. In the presence of H₂O₂, Cu-dependent hydroxyl radical formation was inhibited only up to Cu/MT ratios ≤6. Using low-temperature EPR of free Cu²⁺ to assess Cu/MT physical interactions, we observed that the maximal amount of Cu¹⁺ bound to MT corresponded to 12 molar equivalents of Cu/MT with Cu and ascorbate alone and was reduced in the presence of H₂O₂. 2,2′-Dithiodipyridine titration of MT SH-groups revealed a 50% decrease after H₂O₂, which could be regenerated by dihydrolipoic acid (DHLA). DHLA regeneration of thiols in MT was accompanied by restoration of MT's ability to inhibit Cu-dependent oxidation of ascorbate. Thus, optimum ability of MT to inhibit Cu-redox cycling directly correlates with its ability to bind Cu. Some of this Cu, however, appears releasable following oxidation of the thiolate metal-binding clusters. We speculate that redox-dependent release of Cu from MT serves both as a mechanism for physiological delivery of Cu to specific target proteins, as well as potentiation of cellular damage during oxidative stress.