Haynes V, Traaseth NJ, Elfering S, Fujisawa Y, Giulivi C. Nitration of specific tyrosines in FoF1 ATP synthase and activity loss in aging. Am J Physiol Endocrinol Metab 298: E978 -E987, 2010. First published February 16, 2010 doi:10.1152/ajpendo.00739.2009.-It has been reported that C-nitration of proteins occurs under nitrative/oxidative stress; however, its role in pathophysiological situations is not fully understood. In this study, we determined that nitration of Tyr 345 and Tyr 368 in the -subunit of the mitochondrial FoF1-ATPase is a major target for nitrative stress in rat liver under in vivo conditions. The chemical characteristics of these Tyr make them suitable for a facilitated nitration (solvent accessibility, consensus sequence, and pKa). Moreover, -subunit nitration increased significantly with the age of the rats (from 4 to 80 weeks old) and correlated with decreased ATP hydrolysis and synthesis rates. Although its affinity for ATP binding was unchanged, maximal ATPase activity decreased between young and old rats by a factor of two. These changes directly impacted the available ATP concentration in vivo, and it was expected that they would affect multiple cellular ATP-dependent processes. For instance, at least 50% of available [ATP] in the liver of older rats would have to be committed to sustain maximal Na ϩ -K ϩ -ATPase activity, whereas only 30% would be required for young rats. If this requirement was not fulfilled, the osmoregulation and Na ϩ -nutrient cotransport in liver of older rats would be compromised. On the basis of our studies, we propose that targeted nitration of the -subunit is an early marker for nitrative stress and aging. adenosine 5=-triphosphate; adenosine 5=-triphosphatase; mitochondria; bioenergetics; biomarker IT HAS BEEN SHOWN THAT MITOCHONDRIA produce nitric oxide and that this molecule modulates the oxygen consumption of the organelle by competitive and noncompetitive inhibition of cytochrome c oxidase (18,30). Inhibition of oxygen consumption is transient as long as small quantities of nitric oxide are generated. However, at high or sustained levels of nitric oxide, the inhibition of the respiratory chain leads to an increased rate of formation of oxygen-free radicals that may damage mitochondria and/or initiate apoptosis (30). Other studies have demonstrated novel roles for nitric oxide through S-nitrosation of proteins (Ref. 43 and references therein). The finding that protein modification by nitrosation may be dynamically regulated and, in certain cases, coupled to cell surface signals has potential implications for other signaling pathways and cellular control mechanisms.However, in addition to its transient effects mediated through interaction with cytochrome c oxidase and/or S-nitrosation of proteins, nitric oxide may exhibit relatively long-term effects through the nitration of proteins (32,38). It has been proposed that C-nitration of proteins constitutes a novel chemical modification that occurs as a consequence of the "normal" oxidative background (39...
