Abstract

Psychophysiological stress has long been recognized as a risk factor for diverse pathologies including cardiovascular disease, psychiatric illnesses, and aging-related neurodegenerative disorders but molecular events linking stress to disease remain ill-defined. Mounting evidence supports a role for nitro-oxidative modifications of protein thiols in cellular signaling and toxicity. In light of numerous reports that acute stress can increase the activities and/or expression levels of multiple nitric oxide synthase isoforms in the brains of rodent models, we investigated the possibility that subjecting rats to acute restraint stress may promote S-nitrosylation of proteins from the brain measured by the classical biotin-switch method. Our results indeed show that restraint stress increased S-nitrosylation of brain proteins albeit transiently. S-nitrosylation was highest following 2 hours of restraint but returned to levels at or below the control by six hours. Among the S-nitrosylated proteins identified by LC-MS/MS were, from highest to lowest abundance, glyceraldehyde-3-phosphate dehydrogenase, peroxiredoxin-2, protein phosphatase 2B, and the ADP/ATP translocase all of which have immediate implications for cellular pathology. As protein nitrosthiols are generally unstable and readily convert to disulfides, efforts were also made to measure the impacts of restraint stress on disulfides involving proteins. Levels of protein-glutathione mixed disulfides appeared to be inversely related to S-nitrosylation but changes across groups were not statistically-significant. In addition, unique challenges to the trapping of the in vivo redox states of protein vicinal thiols and the determination of the effects of restraint stress on oxidations of these, resulting in protein disulfides, were noted and linked to the very high reactivity of the catalytic thiols of peroxiredoxins. These findings provide initial support for the notion that protein S-nitrosylation may link psychophysiological stress to neural insults and open the door for further investigations of nitro-oxidative modifications of protein thiols as potential links between life stresses and disease.

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