Glutathionylspermidine in the modification of protein SH groups: the enzymology and its application to study protein glutathionylation.

Cysteine is very susceptible to reactive oxygen species. In response; posttranslational thiol modifications such as reversible disulfide bond formation have arisen as protective mechanisms against undesired in vivo cysteine oxidation. In Gram-negative bacteria a major defense mechanism against cysteine overoxidation is the formation of mixed protein disulfides with low molecular weight thiols such as glutathione and glutathionylspermidine. In this review we discuss some of the mechanistic aspects of glutathionylspermidine in prokaryotes and extend its potential use to eukaryotes in proteomics and biochemical applications through an example with tissue transglutaminase and its S-glutathionylation.

Characterization of protein serotonylation via bioorthogonal labeling and enrichment.

Protein serotonylation is a transglutaminase-mediated phenomenon whose biological mechanism of protein serotonylation is not yet fully understood, as the complete profiling of serotonylation targets in a proteome remains a critical challenge to date. Utilizing an alkyne-functionalized serotonin derivative bioorthogonally coupled to a cleavable linker, we developed a method to selectively enrich serotonylated proteins in a complex sample. With online nanoflow liquid chromatography and LTQ-Orbitrap Velos hybrid mass spectrometer detection, we identified 46 proteins with 50 serotonylation sites at their glutamine residues. Mass spectrometric analysis also generated direct residue-level evidence of various biological processes such as transglutaminase-chaperon interactions as well as actin assembly. An enrichment workflow utilizing click chemistry and on-bead digestion allowed us to achieve site-specific identification of protein serotonylation by mass spectrometry, and results obtained hereby also provided a great foundation in the elucidation of the true roles of protein serotonylation in biological systems.

An in vivo tagging method reveals that Ras undergoes sustained activation upon transglutaminase-mediated protein serotonylation.

Don't interrupt! Protein serotonylation has been implicated in living cells, yet its role remains poorly defined because of the lack of characterization tools. We synthesized a serotonin derivative to enable selective tagging of serotonylation and to investigate its effect on Ras; the latter displayed undisrupted interaction with Raf-1 at the Ras binding domain.

Characteristic tandem mass spectral features under various collision chemistries for site-specific identification of protein S-glutathionylation.

Protein S-glutathionylation is a reversible post-translational modification widely implicated in redox regulated biological functions. Conventional biochemical methods, however, often do not allow such a mixed disulfide modification to be reliably identified on specific cysteine residues or be distinguished from other related oxidized forms. To develop more efficient mass spectrometry (MS)-based analytical strategies for this purpose, we first investigated the MS/MS fragmentation pattern of S-glutathionylated peptides under various dissociation modes, including collision-induced dissociation (CID), higher-energy C-trap dissociation (HCD), and electron transfer dissociation (ETD), using synthetic peptides derived from protein tyrosine phosphatase as models. Our results indicate that a MALDI-based high energy CID MS/MS on a TOF/TOF affords the most distinctive spectral features that would facilitate rapid and unambiguous identification of site-specific S-glutathionylation. For more complex proteomic samples best tackled by LC-MS/MS approach, we demonstrate that HCD performed on an LTQ-Orbitrap hybrid instrument fairs better than trap-based CID and ETD in allowing more protein site-specific S-glutathionylation to be confidently identified by direct database searching of the generated MS/MS dataset using Mascot. Overall, HCD afforded more peptide sequence-informative fragment ions retaining the glutathionyl modification with less neutral losses of side chains to compromise scoring. In conjunction with our recently developed chemo-enzymatic tagging strategy, our nanoLC-HCD-MS/MS approach is sufficiently sensitive to identify endogenous S-glutathionylated peptides prepared from non-stressed cells. It is anticipated that future applications to global scale analysis of protein S-glutathionylation will benefit further from current advances in both speed and mass accuracy afforded by HCD MS/MS mode on the Orbitrap series.