A Combined Chemical Derivatization/Mass Spectrometric Method for the Enhanced Detection and Relative Quantification of Protein Ubiquitination.

Mass spectrometry (MS) is a sensitive analytical technique with wide application across the sciences including for the detection of peptides and proteins in biological analysis. Ubiquitinated (Ub) proteins are typically analyzed by proteolytic digestion and subsequent chromatographic separation followed by MS detection of the resulting isopeptides. Here we describe a novel method which enables enhanced detection of this important posttranslational modification (PTM) by use of a simple chemical labeling strategy prior to Data-Independent Acquisition (DIA) using a SWATH-based acquisition approach on a suitable Quadrupole-Time-Of-Flight (Q-TOF) mass spectrometer.

The application of targeted mass spectrometry-based strategies to the detection and localization of post-translational modifications.

This review describes some of the more interesting and imaginative ways in which mass spectrometry has been utilized to study a number of important post-translational modifications over the past two decades; from circa 1990 to 2013. A diverse range of modifications is covered, including citrullination, sulfation, hydroxylation and sumoylation. A summary of the biological role of each modification described, along with some brief mechanistic detail, is also included. Emphasis has been placed on strategies specifically aimed at detecting target modifications, as opposed to more serendipitous modification discovery approaches, which rely upon straightforward product ion scanning methods. The authors have intentionally excluded from this review both phosphorylation and glycosylation since these major modifications have been extensively reviewed elsewhere.

Mass spectral enhanced detection of Ubls using SWATH acquisition: MEDUSA--simultaneous quantification of SUMO and ubiquitin-derived isopeptides.

Protein modification by ubiquitination and SUMOylation occur throughout the cell and are responsible for numerous cellular functions such as apoptosis, DNA replication and repair, and gene transcription. Current methods for the identification of such modifications using mass spectrometry predominantly rely upon tryptic isopeptide tag generation followed by database searching with in vitro genetic mutation of SUMO routinely required. We have recently described a novel approach to ubiquitin and SUMO modification detection based upon the diagnostic a' and b' ions released from the isopeptide tags upon collision-induced dissociation of reductively methylated Ubl isopeptides (RUbI) using formaldehyde. Here, we significantly extend those studies by combining data-independent acquisition (DIA) with alternative labeling reagents to improve diagnostic ion coverage and enable relative quantification of modified peptides from both MS and MS/MS signals. Model synthetic ubiquitin and SUMO-derived isopeptides were labeled with mTRAQ reagents (Δ0, Δ4, and Δ8) and subjected to LC-MS/MS with SWATH acquisition. Novel diagnostic ions were generated upon CID, which facilitated the selective detection of these modified peptides. Simultaneous MS-based and MS/MS-based relative quantification was demonstrated for both Ub and SUMO-derived isopeptides across three channels in a background of mTRAQ-labeled Escherichia coli digest.

Chemically facilitating the generation of diagnostic ions from SUMO(2/3) remnant isopeptides.

RATIONALE: Mapping sites of wild-type SUMO modification is a challenging endeavour. Here we postulate that a combination of chemical derivatistation and collision-induced dissociation (CID) could be used to generate SUMO remnant diagnostic ions to aid both detection of these isopeptides and increase the analytical value of the product ion spectra required to characterize the nature and position of modification. METHODS: SUMO(2/3)ylated proteins were digested with trypsin to generate isopeptides bearing TGG and QTGG isotags. The resulting digests were then dimethyl labelled followed by liquid chromatography/tandem mass spectrometry (LC/MS/MS) utilising CID in a data-dependent acquisition on a QSTAR XL. Product ion spectra were interrogated for the presence of iso-N-terminal fragment ions in addition to backbone sequence ions. The ability to diagnostically detect these isopeptides was tested by generation of co-XICs of the iso-N-terminal fragments in a semi-complex background. RESULTS: Dimethyl labelling facilitated the robust detection of a1', b2' & b3' (TGG isotag) and a1', b2' & b4' (QTGG isotag) ions. The abundance of both N-terminal and iso-N-terminal fragment ions, supported by dimethyl labelling, facilitated the generation of information-rich product ion spectra of these isopeptides to aid confident site assignment. Moreover, the diagnostic nature of the combined XICs of the iso-N-terminal fragments supported detection of the isopeptide signals from a semi-complex background. CONCLUSIONS: A combination of dimethyl labelling and CID does indeed lead to the generation of SUMO remnant isopeptide product ion spectra which are more analytically rich. This enables an improvement in characterization of both the isotag and backbone sequences and the site of modification. The diagnostic value of iso-N-terminal fragment ions allows for post-acquisition XIC interrogation to detect putative isopeptides of interest.

Enhanced detection of ubiquitin isopeptides using reductive methylation.

Identification of ubiquitination (Ub) sites is of great interest due to the critical roles that the modification plays in cellular regulation. Current methods using mass spectrometry rely upon tryptic isopeptide diglycine tag generation followed by database searching. We present a novel approach to ubiquitin detection based upon the dimethyl labeling of isopeptide N-termini glycines. Ubiquitinated proteins were digested with trypsin and the resulting peptide mixture was derivatized using formaldehyde-D2 solution and sodium cyanoborohydride. The dimethylated peptide mixtures were next separated by liquid chromatography and analyzed on a quadrupole-TOF based mass spectrometer. Diagnostic b2' and a1' ions released from the isopeptide N-terminus upon collision-induced dissociation (CID) were used to spectrally improve the identification of ubiquitinated isopeptides. Proof of principle was established by application to a ubiquitinated protein tryptic digest spiked into a six-protein mix digest background. Extracted ion chromatograms of the a1' and b2' diagnostic product ions from the diglycine tag resulted in a significant reduction in signal complexity and demonstrated a selectivity towards the identification of diglycine branched isopeptides. The method was further shown to be capable of identifying diglycine isopeptides resulting from in-gel tryptic digests of ubiquitin enriched material from a His-Ub transfected cell line. We envisage that these ions may be utilized in global ubiquitination studies with post-acquisition MS/MS (or MSe) data interrogation on high resolution hybrid mass spectrometers. ᅟ

A novel approach to the analysis of SUMOylation with the independent use of trypsin and elastase digestion followed by database searching utilising consecutive residue addition to lysine.

RATIONALE: Identification of sites of protein SUMOylation is of great importance due its functional diversity within the cell. To date, most approaches to this problem rely on site-directed mutagenesis and/or highly specialised mass spectrometry approaches. We present a novel alternative approach to the site mapping of SUMOylation using trypsin and elastase digestion, routine mass spectrometry and an unbiased isotag database searching strategy. METHODS: SUMOylated protein samples were digested with a number of enzymes and the resulting peptides separated using liquid chromatography. Analysis was carried out on both linear ion trap Orbitrap and quadrupole-time-of-flight (Q-TOF)-based mass spectrometers equipped with electrospray ionisation. The data files were subsequently searched using the Mascot algorithm with multiple variable tag modifications corresponding to SUMO-derived fragments. The utility of this approach was demonstrated with di-SUMO 2, di-SUMO 3, SUMO 1-RanGap(418-587) 1 and an enriched population of SUMOylated proteins. RESULTS: Unbiased database searches led to the identification of a number of analytically useful isotags ranging in length from two to four residues. Isopeptide fragments were generated including QTGG (di-SUMO-2/3), TGG (di-SUMO-2/3) and GG (SUMO-1). The method was validated by successfully mapping a number of sites of SUMO modification on SUMO-modified proteins enriched from a cell lysate. CONCLUSIONS: This combination of relaxed enzyme specificity, shortened isotag generation and unbiased database searching enabled confident identification of novel analytically useful SUMOylated isopeptides without a requirement for mutagenesis.