Glycopeptide enrichment for MALDI-TOF mass spectrometry analysis by hydrophilic interaction liquid chromatography solid phase extraction (HILIC SPE).

Glycoproteins, and in particular glycopeptides, are highly hydrophilic and are often not retained by reversed phase (RP) chromatography. The separation principle of normal phase (NP) is based on hydrophilic interactions, which in many aspects is complementary to RP separations. Hydrophilic interaction liquid chromatography (HILIC) is a fairly new variation of the NP separations used in the 1970s, the major difference being the use of aqueous solvents. HILIC provides a versatile tool for enrichment of glycopeptides before mass spectrometric (MS) analysis, particularly when used for solid phase extraction (SPE), or in combination with other chromatographic resins or ion-pairing reagents. HILIC SPE can be used for glyco-profiling, i.e., for determining the glycan heterogeneity at one specific glycosylation site, for enrichment of glycopeptides from a complex mixture of peptides, as well as for pre-fractionation of complex samples at the protein or peptide level. In this chapter we present a straightforward HILIC SPE enrichment technique and then combine C18 RP and HILIC enrichment for analysis of glycopeptides. Finally, we demonstrate HILIC enrichment using trifluoroacetic acid as an ion-pairing reagent for the enrichment of glycopeptides prior to mass spectrometry analysis.

Challenges of determining O-glycopeptide heterogeneity: a fungal glucanase model system.

O-Linked glycosylation often occurs in mucin-type domains that are heavily and heterogeneously glycosylated and are challenging to analyze. The analysis of these domains is often overlooked because of these difficulties, but changes in mucinlike domain glycosylation are implicated in many diseases. Here we have explored several strategies to determine the heterogeneity of mucinlike O-glycosylated domains. Four glucanases secreted in large quantities from Trichoderma reesei, all containing heavily O-glycosylated mucinlike linker regions, were used as a model system. The strategies involved monosaccharide compositional analysis and identification of the released glycans by HPAEC-PAD and carbon-LC ESI-MS/MS. Glycosylated peptides were generated by different protease digestions (trypsin, papain, Asp-N, PreTAQ) and enriched by HILIC microcolumns, to determine the glycopeptide heterogeneity and glycosylation sites. The complex O-glycan heterogeneity on the intact glycoproteins and the enriched mucin-type domains was determined by MALDI-MS and ESI-MS, but the dense O-glycosylation in the mucin-type domains conferred high resistance to protease cleavage. ETD-MS/MS of the glycopeptide-enriched protease digests was unsuccessful for the de novo assignment of O-glycosylation at individual sites within the mucin-type domains but allowed several previously unknown O-linked sites outside the defined linker region to be found on two of the four glucanases. The protease digests produced many glycopeptides as determined by CID-MS/MS, but ETD fragmentation of these resulted in only a few interpretable spectra, suggesting that the use of ETD for determining the heterogeneous O-glycosylation at specific sites in regions of multiple occupancy is still in its infancy.

Posttranslational modifications in human plasma MBL and human recombinant MBL.

Mannan-binding lectin (MBL) is a complex serum protein that plays an important role in innate immunity. In addition to assuming several different oligomeric forms, the polypeptide itself is highly heterogeneous. This heterogeneity is due to post-translational modifications, which help to stabilize the intact protein in its active conformation. For the first time, positions and occupation frequency of partial hydroxylations and partial glycosylations are reported in MBL. Hydroxylation and glycosylation patterns of both recombinant and plasma derived MBL were determined, using a combination of mass spectrometry on reduced MBL and on enzyme cleaved MBL. Variations in the degree of hydroxylation and glycosylation seem to be an indigenous characteristic of collectins. In addition to these already known modifications, a new post-translational modification was identified. Cys(216) (and occasionally also Cys(202)) was modified in trace amounts to dehydroalanine, as detected by a 34 Da mass loss. This impairs the formation of a disulphide bond in the carbohydrate recognition domain. The dehydroalanine was identified in similar small amounts in both recombinant and plasma-derived MBL.

Combination primer polymerase chain reaction for multi-site mutagenesis of close proximity sites.

We describe a rapid and efficient polymerase chain reaction procedure for multi-site-directed mutagenesis for cases in which the sites to be mutated are in close proximity. The combination primer polymer chain reaction method is based on a multi-site directed mutagenesis protocol together with a splicing by overlapping extension polymerase chain reaction protocol. several different combinations of multiple mutations were successfully performed with this method and are reported in this study.