Project description:Heterogeneity of protein glycosylation poses great challenge for analysis that is key to un-puzzle systems glycobiology in diseases. Resolving this conundrum requires global enrichment of glycopeptides for identification and quantitation. To this aim, hydrophilic interaction chromatography (HILIC) has been proved to be an effective approach to enrich N-linked glycopeptides (N-glycopeptides). However, its effectiveness to enrich O-linked glycopeptides (O-glycopeptides) and isobaric labelled glycopeptides remains unclear. Here, we studied three different cartridges in HILIC mode. It was found that removal of N-glycosylation prior to enrichment improved identification of O-glycopeptides. It was noted that increased yield and number of glycosylation identification were seen when using cartridges having materials for strong anion exchange (SAX) chromatography. Remarkably, O-glycopeptides were found to be selectively enriched by HILIC with further improved enrichment being seen when Retain AX cartridge being used. Of particular note, isobaric labelled glycopeptides could be readily enriched by SAX cartridges in HILIC mode to enable quantitative glycoproteomics. It is anticipated that the use of SAX cartridges will facilitate broad applications of qualitative and quantitative glycoproteomics in diseases.

Project description:Large-scale identification of N-linked intact glycopeptides by liquid chromatography coupled tandem mass spectrometry (LC-MS/MS) in human serum is challenging due to the wide dynamic range of serum protein abundances, the lack of a complete serum N-Glycan database and the existence of non-specifically digested peptides and numerous modifications. In this regard, a spectral library search method was presented for serum N-linked intact glycopeptides identification with target-decoy and motif-specific false discovery rate (FDR) control. Low-abundant glycoproteins were firstly separated from high-abundant proteins by acetonitrile (ACN) precipitation. After digestion, the N-linked intact glycopeptides were enriched by hydrophilic interaction liquid chromatography (HILIC) column and a portion of the enriched N-linked intact glycopeptides were processed by N-Glycosidase F (PNGase F) to generate de-glycopeptides. Both N-linked intact glycopeptides and de-glycopeptides were analyzed by LC-MS/MS. From N-linked de-glycopeptides datasets, 764 N-linked glycoproteins, 1,699 N-linked glycosites and 3,328 unique N-linked de-glycopeptides were identified. The spectra of these N-linked de-glycopeptides were utilized for N-linked de-glycopeptides library construction and identification of N-linked intact glycopeptides. Four types of N-linked glycosylation motifs (NXS/T/C/V, X≠P) were used to recognize the N-linked de-glycopeptides, and two different N-Glycan mass databases including 27 modified N-Glycan masses and 712 unmodified N-Glycan masses were combined and utilized during spectral library search for identification of N-linked intact glycopeptides. In total, from the N-linked intact glycopeptides datasets, 526 N-linked glycoproteins, 1,036 N-linked glycosites, 22,677 N-linked intact glycopeptides and 738 N-Glycan masses were identified under 1% FDR, representing the most in-depth serum N-glycoproteome identified by LC-MS/MS at N-linked intact glycopeptide level and N-linked de-glycopeptides level.

Project description:We aimed to in-depth characterize and quantify salivary N-glycoproteomics. HILIC enrichment and LC-MS/MS were combined to investigate salivary glycosylation both at deglycopeptides level and glycopepeptides level, and alterations in site-specific glycoforms for human saliva were detected between lung cancer patients and healthy subjects. Firstly, intact glycopeptides were enriched from human saliva through using HILIC. Obtained intact glycopeptides were characterized by LC-MS/MS directly. Furthermore, the glycosylation sites were fully identified by LC-MS/MS followed by incubating with PNGase F. The developed workflow was applied to compare N-glycosites and intact N-glycopeptides in lung cancer group and healthy control group. Dysregulated N-glycosites as well as site-specific glycoforms were confidently observed in lung cancer and their potential value in clinical applications will be discussed.

Project description:In this work, we performed a fully descriptive analysis N- and O- linked glycosylation of SARS-COV-2 S glycoprotein. We investigated that dual-functionalized Ti-IMAC material enable the simultaneous enrichment and separation of neutral and sialyl glycopeptides of a recombinant SARS-CoV-2 S glycoprotein from HEK293, which will eliminate the signal suppression of neutral glycopeptides to sialyl glycopeptides and improve the glycoform coverage of S protein. We have profiled 19 of its 22 potential N-glycosylated sites with 398 unique glycoforms in dual-functional Ti-IMIAC approach that is 1.6-fold of that in conventional HILIC method. We also identified O-linked glycosylation site that was not found in dual-functional Ti-IMIAC approach. In addition, we have also identified mannose-6-phosphate (M6P) glycosylation, which substantially expands the current knowledge of the spike protein’s glycosylation and enables the investigation of the influence of mannose-6-Phosphate on its cell entry.

Project description:Both SKOV3 and IOSE80 cells were cultured and extracted the proteins. With sequential digestion by trypsin, enriched by Zwitterionic Hydrophilic Interaction chromatography (ZIC-HILIC), the intact N-glycopeptides were then isotopic diethyl labelled and analyzed using C18-RPLC-MS/MS (HCD).

Project description:This study introduced the use of cotton in 200µL tips, namely cotton HILIC as a convenient tool for enriching large-scale glycopeptides before MS analysis in this study. The optimal loading buffer for cotton HILIC was investigated by using mouse brain as a complex test sample. Subsequently, the performance of cotton HILIC was evaluated by comparing with other two commercial enrichment approaches, venusil HILIC and Oasis MAX in both mouse brain and seminal plasma. Moreover, capacity and recovery rate were evaluated using different milligram of cotton in 200µL tips. Thus, a simple, convenient, and cost-friendly cotton HILIC method was proposed to achieve highly selective intact glycopeptide profiling.

Project description:Ter-polymer (MMA/EGDMA/1,2-Epoxy-5-Hexene) is fabricated via the polymerization using ethylene glycol di-methacrylate (EGDMA) as polar crosslinker. The oxirane groups of ter-polymer are immobilized with cysteic acid to enhance the hydrophilicity of HILIC sorbent. The enrichment efficacy is evaluated using the tryptic digests of HRP and IgG. Cya@terpolymer shows good potential for the intact N-linked glycopeptides enrichment from human serum.

Project description:Intact glycopeptides in MEVs from bovines, caprines, porcines and humans were comprehensively analyzed by high-resolution mass spectrometry using the sceHCD followed by EThcD fragment method, revealing that protein glycosylation is abundant and heterogeneous in MEVs.

Project description:Cancer stem cells (CSCs) are reported to be responsible for tumor initiation, progression, metastasis, and therapy resistance where P-glycoprotein (P-gp) as well as other glycoproteins are involved. Identification of these glycoprotein markers is critical for understanding the resistance mechanism and developing therapeutics. Here we report our comparative N-glycoproteomics study of MCF‐7/ADR vs. MCF-7 cells. With zic-HILIC enrichment, isotopic diethyl labeling, RPLC-MS/MS (HCD) analysis and GPSeeker DB search, differentially expressed N-glycosylation was quantitatively characterized at the intact N-glycopeptides levels.

Project description:Protein glycosylation is ubiquitous and plays critical roles in biology. However, study of O-linked glycoproteome (O-glycoproteome), a major type of protein glycosylation, has been severely impeded due to paucity of technology. We presented a chemoenzymatic strategy for extraction of site-specific O-linked glycopeptides (SOGO), which enabled simultaneous enrichment and identification of O-linked glycosylation sites (O-glycosites) in an unprecedented depth. Central to SOGO is a tandem-use of solid-phase capture of peptides and an O-linked glycan (O-glycan) dependent endoprotease named OpeRATOR. Interestingly, OpeRATOR requires O-glycan to specifically cleave the N-terminus of glycan-occupied Ser and Thr leading to unambiguous identification of O-glycosites and corresponding glycoproteins. The identified O-glycosites facilitated downstream determination of microheterogeneity of intact O-linked glycopeptides (O-glycopeptides). We benchmarked the method using human serum and identified 805 peptides containing 777 O-glycosites from 1,345 site-specific O-glycopeptides and 302 glycoproteins. We applied the method to study change of protein-specific O-glycosylation in human T cells infected with human immunodeficiency virus (HIV-1). Strikingly, 1404 peptides containing 1,352 O-glycosites from 577 glycoproteins were identified. In addition, altered site-specific O-linked glycosylation (O-glycosylation) during HIV infection of T cells were observed. In total, 1989 O-glycosites from 789 glycoproteins were precisely pinpointed from human serum and T cells. We observed conserved motifs for O-glycoproteome. Finally, ontology analysis revealed diverse roles for O-glycoproteins arguing broad application of our method to study biology in respective to protein O-glycosylation.