Insights into heme degradation and hydrogen peroxide-induced dimerization of human neuroglobin.

Abstract

In this present study, we investigated the H2O2-induced oligomerization of wild-type human neuroglobin (hNgb) and of some selected variants (C46AC55A, Y44A, Y44F, Y44AC46AC55A, Y44AC46AC55A) to clarify how the process is affected by the Cys46/Cys55 disulfide bond and the distal H-bonding network and to figure out the molecular determinants of the H2O2-induced formation of amyloid-type structures and hNgb aggregates. It turns out that hydrogen peroxide exerts a two-fold effect on hNgb, inducing both heme breakdown and protein dimerization/polymerization. The enhanced resistance to the oxidizing effect of H2O2 of the disulfide-free variants indicates that both effects are strictly influenced by the heme accessibility for H2O2. Most importantly, the H2O2-induced neuroglobin dimerization/polymerization turns out to be triggered by tyrosyl radicals resulting from the oxidizing action of Compound I ([Por•Fe(IV) = O]+). Peptide mapping indicates that the H2O2-induced dimerization/polymerization of hNgb mainly involves Tyr44, which forms covalent bonds with all the other tyrosine residues, with a minor contribution from Tyr88. The presented findings contribute further important pieces of information in the quest of identifying all capabilities of hNgb and ultimately its physiological task.