Selective enrichment of glycopeptides from complex sample followed by cleavage of N-glycans by PNGase F to expose an easily detectable mark on the former glycosylation sites has become the popular protocol for comprehensive glycoproteome analysis. On account of the high enrichment specificity, hydrazide chemistry based solid-phase extraction of N-linked glycopeptides technique has sparked numerous interests. However, the enzymatic release of glycopeptides captured by hydrazide beads through direct incubation of the beads with PNGase F is not efficient due to the inherent steric hindrance effect. In this study, we developed a hydroxylamine assisted PNGase F deglycosylation (HAPD) method using the hydroxylamine to release glycopeptides captured on the hydrazide beads through the cleavage of hydrazone bonds by transamination followed with the PNGase F deglycosylation of the released glycopeptides in the free solution. Because of the homogeneous condition for the deglycosylation, the recovery of deglycosylated peptides (deglycopeptides) was improved significantly. It was found that 27% more N-glycosylation sites were identified by the HAPD strategy compared with the conventional method. Moreover, the ratio of identified N-terminal glycosylated peptides was improved over 5-fold.

A problem for “shot-gun” proteomics is that the peptides generated in the proteolysis step overwhelm the analytical capacity of current LC–MS/MS systems. A straightforward approach to overcome this problem is to reduce the sample complexity by isolating the representative peptides of each protein. In this study, we presented a facile solid-phase capture-release approach to selectively enrich the peptides with N-terminal serine/threonine from protein digests. This method exploited the highly efficient reaction between an aldehyde group and a hydrazine group. The excellent performance of this approach was validated using synthetic peptides as well as complex protein digests. It was found that high enrichment specificity could be obtained and the identifications for complex samples with and without enrichment were highly complementary. Besides, the enrichment of peptides with serine/threonine adjacent to different protease cleavage sites demonstrated that our method was able to enrich peptides from protein digests in a sequence specific way. As a result, this new approach provides a simple way to reduce sample complexity and facilitates the identification of low-abundance proteins.

Selective enrichment of glycopeptides from complex sample followed by cleavage of N-glycans by PNGase F to expose an easily detectable mark on the former glycosylation sites has become the popular protocol for comprehensive glycoproteome analysis. On account of the high enrichment specificity, hydrazide chemistry based solid-phase extraction of N-linked glycopeptides technique has sparked numerous interests. However, the enzymatic release of glycopeptides captured by hydrazide beads through direct incubation of the beads with PNGase F is not efficient due to the inherent steric hindrance effect. In this study, we developed a hydroxylamine assisted PNGase F deglycosylation (HAPD) method using the hydroxylamine to release glycopeptides captured on the hydrazide beads through the cleavage of hydrazone bonds by transamination followed with the PNGase F deglycosylation of the released glycopeptides in the free solution. Because of the homogeneous condition for the deglycosylation, the recovery of deglycosylated peptides (deglycopeptides) was improved significantly. It was found that 27% more N-glycosylation sites were identified by the HAPD strategy compared with the conventional method. Moreover, the ratio of identified N-terminal glycosylated peptides was improved over 5-fold.

A problem for “shot-gun” proteomics is that the peptides generated in the proteolysis step overwhelm the analytical capacity of current LC–MS/MS systems. A straightforward approach to overcome this problem is to reduce the sample complexity by isolating the representative peptides of each protein. In this study, we presented a facile solid-phase capture-release approach to selectively enrich the peptides with N-terminal serine/threonine from protein digests. This method exploited the highly efficient reaction between an aldehyde group and a hydrazine group. The excellent performance of this approach was validated using synthetic peptides as well as complex protein digests. It was found that high enrichment specificity could be obtained and the identifications for complex samples with and without enrichment were highly complementary. Besides, the enrichment of peptides with serine/threonine adjacent to different protease cleavage sites demonstrated that our method was able to enrich peptides from protein digests in a sequence specific way. As a result, this new approach provides a simple way to reduce sample complexity and facilitates the identification of low-abundance proteins.