Detection of trans,trans-2,4-decadienal adducts in cytochrome c. Effects on isolated mitochondrial functions

Lipid hydroperoxide-derived α,β-unsaturated aldehydes are involved in several cellular processes such as gene expression, aging, Alzheimer disease and mitochondrial dysfunction. In this work we have investigated adduct formation in lysine, histidine and cytochrome c by trans,trans-2,4-decadienal (DDE), an endogenously lipoperoxidation product. DDE is also a widespread environment aldehyde found, for example, in food and as a contaminant in water. Alterations in rat liver mitochondrial parameters such as oxygen consumption, membrane potentials, swelling and lipoperoxidation were also investigated. LC-ESI/MS experiments indicated that DDE react with aminoacids lysine and histidine producing adducts. In addition, MALDI-TOF experiments indicated increases in the molecular weight of cytochrome c consistent with the formation of DDE adducts via the Schiff base mechanism. Our data shows that the protein modification was time, pH and DDE-concentration dependent, leading to the formation of at least six adducts after 2 h incubation at pH 7.4. ESI-Q-TOF MS analysis of tryptic digests indicated that H-33, K-39, K-72 and K-100 were modified by DDE. These adducts are present in clusters of basic amino acid residues, which are believed to participate in the interaction of cytochrome c with mitochondrial membrane and cytochrome c oxidase. A blue shift in the Soret band from 409 to 406 nm was also observed, indicating heme crevice opening and displacement of heme sixth ligand (Met-80) coordination in modified protein. DDE (180 µM) treatment increases the rate of mitochondrial oxygen consumption, suggesting a partial mitochondrial uncoupling. Moreover, extensive mitochondrial swelling upon treatment with DDE (900 nM-162 &#181M) was observed by light scattering and transmission electron microscopy experiments. These effects were not prevented by the mitochondrial permeability transition inhibitor cyclosporin A. A DDE concentration-dependent loss in the inner mitocondrial membrane potential, monitored by safranin O fluorescence and an increase in lipoperoxidation were also observed. All together, these results suggest that reactive aldehydes can induce inner mitochondrial membrane damage playing a role in mitochondrial dysfunction associated with oxidative stress. (AU)