Abstract
Arginine phosphorylation is an emerging post-translational protein modification implicated in the bacterial stress response. Although early reports suggested that arginine phosphorylation also occurs in higher eukaryotes, its overall prevalence was never studied using modern mass spectrometry methods, owing to technical difficulties arising from the acid lability of phosphoarginine. As shown recently, the McsB and YwlE proteins from Bacillus subtilis function as a highly specific protein arginine kinase and phosphatase couple, shaping the phosphoarginine proteome. Using a B. subtilis ΔywlE strain as a source for arginine-phosphorylated proteins, we were able to adapt mass spectrometry (MS) protocols to the special chemical properties of the arginine modification. Despite this progress, the analysis of protein arginine phosphorylation in eukaryotes is still challenging, given the great abundance of serine/threonine phosphorylations that would compete with phosphoarginine during the phosphopeptide enrichment procedure, as well as during data-dependent MS acquisition. We thus set out to establish a method for the selective enrichment of arginine-phosphorylated proteins as an initial step in the phosphoproteomic analysis. For this purpose, we developed a substrate-trapping mutant of the YwlE phosphatase that retains binding affinity toward arginine-phosphorylated proteins but cannot hydrolyze the captured substrates. By testing a number of active site substitutions, we identified a YwlE mutant (C9A) that stably binds to arginine-phosphorylated proteins. We further improved the substrate-trapping efficiency by impeding the oligomerization of the phosphatase mutant. The engineered YwlE trap efficiently captured arginine-phosphorylated proteins from complex B. subtilis ΔywlE cell extracts, thus facilitating identification of phosphoarginine sites in the large pool of cellular protein modifications. In conclusion, we present a novel tool for the selective enrichment and subsequent MS analysis of arginine phosphorylation, which is a largely overlooked protein modification that might be important for eukaryotic cell signaling.
Highlights
Selective enrichment and subsequent mass spectrometry (MS) analysis of arginine phosphorylation, which is a largely overlooked protein modification that might be important for eukaryotic cell signaling
McsB does not display any homology to known serine/threonine or tyrosine protein kinases, but it does to phosphagen kinases that phosphorylate the guanidinium group of free arginine or creatine, which are used as shortterm energy storage molecules
A single amino acid substitution in the highly conserved protein-tyrosine phosphatases (PTPs) signature motif localized at the active site establishes a polarity filter that is responsible for the pronounced phosphoarginine selectivity (9)
Summary
Selective enrichment and subsequent MS analysis of arginine phosphorylation, which is a largely overlooked protein modification that might be important for eukaryotic cell signaling. We used the developed methodology to study protein arginine phosphorylation in the Gram-positive bacterium Bacillus subtilis, revealing the central role of phosphoarginine in the regulation of the bacterial stress response (3). To this end it has been shown that arginine phosphorylation is an important but largely unexplored protein modification. Conventional phosphoproteomic studies are able to identify over 10,000 phosphopeptides in eukaryotic cell lines (12) Such abundant phosphorylations could compete with phosphoarginine during the phosphopeptide enrichment procedure, as well as get preferentially selected during data-dependent MS acquisition. The resulting reduction in sample complexity should greatly facilitate the identification of arginine phosphorylation in eukaryotic samples
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