Nanoprobe-based immobilized metal affinity chromatography for sensitive and complementary enrichment of multiply phosphorylated peptides

Magnetic nanoparticles (MNP, <100 nm) have rapidly evolved as sensitive affinity probes for phosphopeptide enrichment. By taking advantage of the easy magnetic separation and flexible surface modification of the MNP, we developed a surface‐blocked, nanoprobe‐based immobilized metal ion affinity chromatography (NB‐IMAC) method for the enhanced purification of multiply phosphorylated peptides. The NB‐IMAC method allowed rapid and specific one‐step enrichment by blocking the surface of titanium (IV) ion‐charged nitrilotriacetic acid‐conjugated MNP (Ti⁴⁺‐NTA‐PEG@MNP) with low molecular weight polyethylene glycol. The MNP demonstrated highly sensitive and unbiased extraction of both mono‐ and multiply phosphorylated peptides from diluted β‐casein (2×10^?10 M). Without chemical derivation or fractionation, 1283 phosphopeptides were identified from 400 μg of Raji B cells with 80% purification specificity. We also showed the first systematic comparison on the particle size effect between nano‐sclae IMAC and micro‐scale IMAC. Inductively coupled plasma‐mass spectrometry (ICP‐MS) analysis revealed that MNP had a 4.6‐fold higher capacity for metal ions per unit weight than did the magnetic micro‐sized particle (MMP, 2–10 μm), resulting in the identification of more phosphopeptides as well as a higher percentage of multiply phosphorylated peptides (31%) at the proteome scale. Furthermore, NB‐IMAC complements chromatography‐based IMAC and TiO₂ methods because <13% of mono‐ and 12% of multiply phosphorylated peptide identifications overlapped among the 2700 phosphopeptides identified by the three methods. Notably, the number of multiply phosphorylated peptides was enriched twofold and threefold by NB‐IMAC relative to micro‐scale IMAC and TiO₂, respectively. NB‐IMAC is an innovative material for increasing the identification coverage in phosphoproteomics.