Abstract
Metal and metal oxide chelating-based phosphopeptide enrichment technologies provide powerful tools for the in-depth profiling of phosphoproteomes. One weakness inherent to current enrichment strategies is poor binding of phosphopeptides containing multiple basic residues. The problem is exacerbated when strong cation exchange (SCX) is used for pre-fractionation, as under low pH SCX conditions phosphorylated peptides with multiple basic residues elute with the bulk of the tryptic digest and therefore require more stringent enrichment. Here, we report a systematic evaluation of the characteristics of a novel phosphopeptide enrichment approach based on a combination of low pH SCX and Ti(4+)-immobilized metal ion affinity chromatography (IMAC) comparing it one-to-one with the well established low pH SCX-TiO(2) enrichment method. We also examined the effect of 1,1,1,3,3,3-hexafluoroisopropanol (HFP), trifluoroacetic acid (TFA), or 2,5-dihydroxybenzoic acid (DHB) in the loading buffer, as it has been hypothesized that high levels of TFA and the perfluorinated solvent HFP improve the enrichment of phosphopeptides containing multiple basic residues. We found that Ti(4+)-IMAC in combination with TFA in the loading buffer, outperformed all other methods tested, enabling the identification of around 5000 unique phosphopeptides containing multiple basic residues from 400 μg of a HeLa cell lysate digest. In comparison, ∼ 2000 unique phosphopeptides could be identified by Ti(4+)-IMAC with HFP and close to 3000 by TiO(2). We confirmed, by motif analysis, the basic phosphopeptides enrich the number of putative basophilic kinases substrates. In addition, we performed an experiment using the SCX/Ti(4+)-IMAC methodology alongside the use of collision-induced dissociation (CID), higher energy collision induced dissociation (HCD) and electron transfer dissociation with supplementary activation (ETD) on considerably more complex sample, consisting of a total of 400 μg of triple dimethyl labeled MCF-7 digest. This analysis led to the identification of over 9,000 unique phosphorylation sites. The use of three peptide activation methods confirmed that ETD is best capable of sequencing multiply charged peptides. Collectively, our data show that the combination of SCX and Ti(4+)-IMAC is particularly advantageous for phosphopeptides with multiple basic residues.
Highlights
Introduction5300 unique phosphorylation sites (58% of the total) were identified from the later SCX fractions (28 – 40) corresponding to the positive phosphopeptides
Our results showed that Ti4ϩ-IMACa is capable of achieving both the largest number of identification of positive phosphopeptides and the highest specificity (63%) of enrichment for the late SCX fractions compared with Ti4ϩIMACb (38%) and TiO2b (46%)
The data presented here indicate that a combination of SCX fractionation and Ti4ϩ-IMAC based enrichment, provides one of the most comprehensive phosphopeptide enrichment and analysis technologies up to date, enabling to further boost the number of phosphopeptide identifications in large scale phosphoproteomics analyses
Summary
5300 unique phosphorylation sites (58% of the total) were identified from the later SCX fractions (28 – 40) corresponding to the positive phosphopeptides. The filtering applied means any site observed in an earlier fraction would be the only site reported. A side effect of this filtering strategy is that it discriminates against phosphopeptides containing miss cleavages. As we have recently reported for regular peptides [53], HCD and CID were most effective for the earlier SCX fraction which contain peptides of lower net charge state, and the peptides carrying on 2ϩ charge. For the late SCX fractions, fractions 34 – 40, ETD outperformed HCD and CID, contributing 76% of the phosphopeptide identifications
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