| Abstract: | Nitric oxide (NO) mediates a substantial part of its physiologic functions via S-nitrosylation, however the cellular substrates for NO-mediated S-nitrosylation are largely unknown. Here we describe the S-nitrosoproteome using a high-density protein microarray chip containing 16,368 unique human proteins. We identified 834 potentially S-nitrosylated human proteins. Using a unique and highly specific labeling and affinity capture of S-nitrosylated proteins, 138 cysteine residues on 131 peptides in 95 proteins were determined, defining critical sites of NO''s actions. Of these cysteine residues 113 are novel sites of S-nitrosylation. A consensus sequence motif from these 834 proteins for S-nitrosylation was identified, suggesting that the residues flanking the S-nitrosylated cysteine are likely to be the critical determinant of whether the cysteine is S-nitrosylated. We identify eight ubiquitin E3 ligases, RNF10, RNF11, RNF41, RNF141, RNF181, RNF208, WWP2, and UBE3A, whose activities are modulated by S-nitrosylation, providing a unique regulatory mechanism of the ubiquitin proteasome system. These results define a new and extensive set of proteins that are susceptible to NO regulation via S-nitrosylation. Similar approaches could be used to identify other post-translational modification proteomes.It is known that NO regulates the majority of its physiologic function through S-nitrosylation (1). Protein-assisted or small molecule, S-nitrosoglutathione (GSNO)1 trans-nitrosylation, oxidative S-nitrosation, and metalloprotein-catalyzed S-nitrosylation are the prominent cellular mechanisms that are utilized to S-nitrosylate proteins (2). A number of proteins are known to be S-nitrosylated and this post-translational modification can either activate or inactivate a protein''s biologic activity (1, 3). A number of attempts at probing tissue-specific S-nitrosoproteomes have been made, but the results of these are limited to proteins that are S-nitrosylated to a great degree and which are present at high concentrations (2, 4–6). Recently, to investigate determinants of S-nitrosylation, yeast and human target protein microarrays have been studied. However, these assay were limited because of the small number of proteins present on the chip (7). In addition, many proteins that are known to be S-nitrosylated have been studied through a targeted and biased approach (8). To overcome these shortcomings, we report the use of a 16,368 human protein microarray chip to better define the human S-nitrosoproteome.Ubiquitin is a 76-amino-acid long polypeptide that can be covalently added to lysine residues on targeted proteins either as single monomers or in chains. Ubiquitination of proteins can dramatically alter their function or localization depending on the number of ubiquitin attached and the nature of their linkages. The most well characterized ubiquitin-mediated process is targeting of the protein for degradation by the 26S proteasome, which occurs via poly-ubiquitination linked together through lysine 48 on the ubiquitin monomers. Ubiquitination occurs in a three-step enzymatic process in which the third enzyme, the ubiquitin protein ligase (E3) determines protein target specificity (9). NO S-nitrosylates the RING finger E3 ligases, parkin and XIAP, modifying their function (10, 11). In the case of parkin, S-nitrosylation transiently activates its E3 ligase activity, but ultimately inhibits its activity (12). In contrast, XIAP''s E3 ligase activity is unaffected by S-nitrosylation, but its anti-apoptotic function is compromised (11). Using the 16,368 human protein microarray, we identify a number of NO-regulated E3 ligases, the majority of which are activated by NO-dependent S-nitrosylation. |
