Abstract
Modification of proteins with 4-hydroxynonenal (HNE) is known to alter the function of proteins and regulate the associated biological processes in eukaryotic cells. The development of mass spectrometry (MS) makes high-throughput analysis of HNE modification accessible. However, the identification of HNE modification is still hampered by the low frequency of this modification. Therefore, only a limited number of HNE modification sites have been identified. The enrichment of HNE-modified peptides is critical for the MS analysis of this modification because of its low abundance. Herein, we explored a novel strategy for specifically extracting the HNE-modified peptides using fluorous derivatization through oxime click chemistry combined with following fluorous solid-phase extraction (FSPE). This oxime click chemistry-based derivatization is highly efficient (with a yield of almost 100%) and fast (30 min). Because of the hydrophobicity of the fluorous tag, the signal of fluorous-derivatized HNE-modified peptides was greatly enhanced, making the detection of HNE-modified peptides sensitive. The FSPE further allowed the selective enrichment of fluorous-derivatized HNE-modified peptides from salt solutions and complex mixtures with specificity. Finally, 673 HNE modification sites (607 histidine sites, 60 cysteine sites, 5 lysine sites, and 1 arginine site) on 661 HNE-modified peptides mapped to 432 proteins were successfully identified using this novel approach, which presented the largest data set of HNE modification in MCF-7 cells. Three identified proteins were validated by Western blotting.