Free-Radical-Induced Inactivation of Lysozyme and Carbonyl Residue Generation in Protein Are Not Necessarily Associated

The 2,2′-azobis(2-amidinopropane) (AAPH)-induced inactivation and oxidative modification of lysozyme, as determined by the loss of tryptophan-associated fluorescence (TAF) and the increase in dinitrophenylhydrazine-reactive carbonyl groups (CO), were studied in the absence and in the presence of antioxidants. AAPH induced a progressive inactivation of the enzyme and a parallel decrease of its TAF. Both changes were closely correlated (R2 = 0.97); however, the inactivation was only partially associated with an increase in CO. The latter reached maximal values at times half those needed to attain maximal losses in both lysozyme activity and TAF. A stoichiometric comparison reveals that whereas over 74% of the enzyme molecules had lost their activity, only 5% exhibited an increment in CO. CO formation was affected differentially by boldine and trolox. Both antioxidants fully protected against the early inactivation and loss of TAF; however, the increase in CO was completely unaffected by trolox. Exposure of lysozyme to Fe3+/ascorbate induced no loss of activity or TAF, but it led to an accumulation of CO similar to that induced by AAPH. Results indicate that CO formation and lysozyme inactivation are two mechanistically dissociable events and that changes in the former parameter can perfectly occur in the absence of changes in the latter.