Nitric oxide ( ⅐ NO)-derived reactive species nitrate unsaturated fatty acids, yielding nitroalkene derivatives, including the clinically abundant nitrated oleic and linoleic acids. The olefinic nitro group renders these derivatives electrophilic at the carbon  to the nitro group, thus competent for Michael addition reactions with cysteine and histidine. By using chromatographic and mass spectrometric approaches, we characterized this reactivity by using in vitro reaction systems, and we demonstrated that nitroalkene-protein and GSH adducts are present in vivo under basal conditions in healthy human red cells. Nitro-linoleic acid (9-, 10-, 12-, and 13-nitro-9,12-octadecadienoic acids) (m/z 324.2) and nitro-oleic acid (9-and 10-nitro-9-octadecaenoic acids) (m/z 326.2) reacted with GSH (m/z 306.1), yielding adducts with m/z of 631.3 and 633.3, respectively. At physiological concentrations, nitroalkenes inhibited glyceraldehyde-3-phosphate dehydrogenase (GAPDH), which contains a critical catalytic Cys (Cys-149). GAPDH inhibition displayed an IC 50 of ϳ3 M M for both nitroalkenes, an IC 50 equivalent to the potent thiol oxidant peroxynitrite (ONOO ؊ ) and an IC 50 30-fold less than H 2 O 2 , indicating that nitroalkenes are potent thiol-reactive species. Liquid chromatography-mass spectrometry analysis revealed covalent adducts between fatty acid nitroalkene derivatives and GAPDH, including at the catalytic Cys-149. Liquid chromatography-mass spectrometry-based proteomic analysis of human red cells confirmed that nitroalkenes readily undergo covalent, thiol-reversible post-translational modification of nucleophilic amino acids in GSH and GAPDH in vivo. The adduction of GAPDH and GSH by nitroalkenes significantly increased the hydrophobicity of these molecules, both inducing translocation to membranes and suggesting why these abundant derivatives had not been detected previously via traditional high pressure liquid chromatography analysis. The occurrence of these electrophilic nitroalkylation reactions in vivo indicates that this reversible post-translational protein modification represents a new pathway for redox regulation of enzyme function, cell signaling, and protein trafficking.
Nitric oxide ( ⅐ NO)5 exerts a broad influence on cell and inflammatory signaling via both cGMP-dependent and -independent oxidative, nitrosative, and nitrative reactions (1, 2). The nitration of polyunsaturated fatty acids present in both membranes and lipoproteins is now emerging as a novel mechanism for transducing ⅐ NO-dependent redox signaling (3, 4). Recent evidence indicates that all major unsaturated fatty acids present in human blood contain some proportion of alkenyl nitro derivatives (R 1 HCϭC(NO 2 )R 2 ), also termed nitroalkenes. Because of the prevalence of fatty acid nitroalkenes in healthy humans, these species are now appreciated as an abundant pool of bioactive oxides of nitrogen in the vasculature (5). The two most clinically abundant nitroalkene fatty acid derivatives, nitro-oleic acid (9-and 10-nitro-9-cis-octadeca...
