Abstract

Nitrate (NO3−) and nitrite (NO2−) are known to be cardioprotective and to alter energy metabolism in vivo. NO3− action results from its conversion to NO2− by salivary bacteria, but the mechanism(s) by which NO2− affects metabolism remains obscure. NO2− may act by S-nitrosating protein thiols, thereby altering protein activity. But how this occurs, and the functional importance of S-nitrosation sites across the mammalian proteome, remain largely uncharacterized. Here we analyzed protein thiols within mouse hearts in vivo using quantitative proteomics to determine S-nitrosation site occupancy. We extended the thiol-redox proteomic technique, isotope-coded affinity tag labeling, to quantify the extent of NO2−-dependent S-nitrosation of proteins thiols in vivo. Using this approach, called SNOxICAT (S-nitrosothiol redox isotope-coded affinity tag), we found that exposure to NO2− under normoxic conditions or exposure to ischemia alone results in minimal S-nitrosation of protein thiols. However, exposure to NO2− in conjunction with ischemia led to extensive S-nitrosation of protein thiols across all cellular compartments. Several mitochondrial protein thiols exposed to the mitochondrial matrix were selectively S-nitrosated under these conditions, potentially contributing to the beneficial effects of NO2− on mitochondrial metabolism. The permeability of the mitochondrial inner membrane to HNO2, but not to NO2−, combined with the lack of S-nitrosation during anoxia alone or by NO2− during normoxia places constraints on how S-nitrosation occurs in vivo and on its mechanisms of cardioprotection and modulation of energy metabolism. Quantifying S-nitrosated protein thiols now allows determination of modified cysteines across the proteome and identification of those most likely responsible for the functional consequences of NO2− exposure.

Highlights

  • Nitrate (NO3؊) and nitrite (NO2؊) are known to be cardioprotective and to alter energy metabolism in vivo

  • In exploring how NO2Ϫ might lead to protein S-nitrosation, and to infer proteins with potential physiological roles, we wanted to identify the sites of S-nitrosation in vivo and quantify the extent of modification on individual targets

  • We extended the redox-proteomic method OxICAT, which uses Cys-isotope-coded affinity tag (ICAT) chemistry to both quantify and identify thiols that are reversibly oxidized, which has been applied to Escherichia coli [22], Saccharomyces cerevisiae [25], Caenorhabditis elegans [23], Drosophila melanogaster [24], and to the mouse heart [26]

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Summary

Results and discussion

Using SNOxICAT to identify and quantify S-nitrosation of cardiac proteins in vivo. In exploring how NO2Ϫ might lead to protein S-nitrosation, and to infer proteins with potential physiological roles, we wanted to identify the sites of S-nitrosation in vivo and quantify the extent of modification on individual targets. To further examine the selective quantitative effects of S-nitrosation by NO2Ϫ in the ischemic heart, we clustered proteins with cysteine thiols exhibiting a differential S-nitrosation status (defined as Ͼ10 percentage points between conditions) using gene ontology term enrichment, with the total identified population of cysteine thiol containing proteins as the reference background. This approach identified S-nitrosation targets specific to each intervention that clustered in specific cellular pathways (Fig. 5A and supplemental Table S5). To further explore how ischemic exposure to NO2Ϫ might affect mitochondrial oxidoreductase function, we examined the Condition

E FCCP Val
Conclusions
Experimental procedures

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