Most current technologies for the enrichment of phosphopeptides rely on a tandem combination of different chromatography modes. Here, a fully automatic two-dimensional liquid chromatography mass spectrometry method was developed for global phosphopeptide identification. The peptide mixtures were loaded on a strong anion exchange (SAX) column under basic pH conditions and eluted with a continuous gradient to pH 2.0. This SAX system could be coupled online with reversed-phase liquid chromatography mass spectrometry (RP-LC-MS/MS). For peptide digests from a standard protein mixture spiked with synthesized phosphopeptides, most of the nonphosphorylated peptides were eluted in more basic pH than phosphopeptides, and the phosphopeptides were focused to acidic pH ranges and gradually eluted according to the phosphorylated states of peptides. Compared with the pH step elution method, the continuous gradient method displayed better repeatability and less peptide cross-overlap between fractions. This system provided a robust and fully automatic approach to large-scale phosphoproteomic profiling. For protein tryptic digests from HeLa cells, 1833 nonredundant phosphorylation sites were identified based on this two-phase separation. Compared with the method combining cation exchange and titanium dioxide, this anion-exchange based system preferred to identify more acidic and multiphosphorylated peptides. It also covered a more complete series of phosphorylation states of peptides.
The complexity of canonical Wnt signaling comes not only from the numerous components but also from multiple post-translational modifications. Protein phosphorylation is one of the most common modifications that propagates signals from extracellular stimuli to downstream effectors. To investigate the global phosphorylation regulation and uncover novel phosphoproteins at the early stages of canonical Wnt signaling, HEK293 cells were metabolically labeled with two stable isotopic forms of lysine and were stimulated for 0, 1, or 30 min with purified Wnt3a. After phosphoprotein enrichment and LC-MS/MS analysis, 1057 proteins were identified in all three time points. In total 287 proteins showed a 1.5-fold or greater change in at least one time point. In addition to many known Wnt signaling transducers, other phosphoproteins were identified and quantitated, implicating their involvement in canonical Wnt signaling. k-Means clustering analysis showed dynamic patterns for the differential phosphoproteins. Profile pattern and interaction network analysis of the differential phosphoproteins implicated the possible roles for those unreported components in Wnt signaling. Moreover 100 unique phosphorylation sites were identified, and 54 of them were quantitated in the three time points. Site-specific phosphopeptide quantitation revealed that Ser-20 phosphorylation on RRM2 increased upon 30-min Wnt3a stimulation. Further studies with mutagenesis, the Wnt reporter gene assay, and RNA interference indicated that RRM2 functioned downstream of -catenin as an inhibitor of Wnt signaling and that Ser-20 phosphorylation of RRM2 counteracted its inhibition effect. Our systematic profiling of dynamic phosphorylation changes responding to Wnt3a stimulation not only presented a comprehensive phosphorylation network regulated by canonical Wnt signaling but also found novel molecules and phosphorylation involved in Wnt signaling.
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