Project description:N-glycoproteins are involved in various biological processes. More than one-third of plasma tumor protein biomarkers approved by the Food and Drug Administration (FDA) are glycoproteins which would enhance the specificity and/or sensitivity of cancer diagnosis. Therefore, the characterization of plasma N-glycoproteome is essential. In previous studies, we developed an integrated method based on combinatorial peptide ligands library (CPLL) and stepped collision energy/higher-energy collisional dissociation (sceHCD) for in-depth and comprehensive N‑glycoproteome profiling of human plasma. Recently, we presented a new mass spectrometry fragmentation method (EThcD-sceHCD) which outperformed sceHCD in the accuracy of identification. Herein, we integrated CPLL into EThcD-sceHCD, and compared the performance of EThcD-sceHCD with those previous approaches (EThcD and sceHCD) in pooled prostatic cancer (PCa) patients’ plasma intact N-glycopeptide analysis. We found that EThcD-sceHCD outperformed other methods in both the depth and accuracy of intact N-glycopeptides identification, and sceHCD and EThcD-sceHCD have good complementarity. Combining sceHCD and EThcD-sceHCD can cover almost all glycoproteins and intact N-glycopeptides. Our study holds great potential for human plasma biomarker discovery.

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:Monoclonal immunoglobulin produced by clonal plasma cells is the main cause in multiple myeloma and monoclonal gammopathy of renal significance. Because of the complicated purification method and the low stoichiometry of purified protein and glycans, site-specific N-glycosylation characterization for monoclonal immunoglobulin is still challenging. Studies reporting the N-glycosylation profiles for this monoclonal immunoglobulin have been rare until now. Therefore, in this study, we presented an integrated workflow for micro serum monoclonal IgA and IgG purification from patients with multiple myeloma in the HYDRASYS system, in-agarose-gel digestion, LC‒MS/MS analysis without intact N-glycopeptide enrichment, and compared the identification performance of different mass spectrometry dissociation methods (EThcD-sceHCD, sceHCD, EThcD and sceHCD-pd-ETD). The results showed that EThcD-sceHCD was a better choice for site-specific N-glycosylation characterization of micro in-agarose-gel immunoglobulin proteins (~2 μg) because it can cover more unique intact N-glycopeptides (37 and 50 intact N-glycopeptides from IgA1 and IgG2, respectively) and provide more high-quality spectra than sceHCD, EThcD and sceHCD-pd-ETD. We demonstrated the benefits of the alternative strategy in site-specific N-glycosylation characterizing micro disease-related proteins obtained from bands separated by electrophoresis. This work could promote the development of clinical N-glycoproteomics and related immunology.

Project description:The envelope (Env) glycoprotein on the surface of human immunodeficiency virus type 1 (HIV-1) which decorated with a dense array of glycans is a determinant for viral invasion and host immune response of HIV-1 and a major target for a preventive HIV-1 vaccine. Improved vaccine design requires an understanding of the detailed information about the glycan type on each glycosite. Here, we used our well-established sequential glycoproteomic workflow to characterize the N/O-glycosylation of HIV-1 gp120 at the level of native intact glycopeptides based on a stepped collision energy/higher-energy collisional dissociation (sceHCD) mass spectrometry (sceHCD-MS/MS), and a combined electron transfer/higher-energy collisional dissociation (EThcD) and sceHCD mass spectrometry (EThcD-sceHCD-MS/MS).

Project description:Immunoglobulin G (IgG) molecules modulate an immune response. However, site-specific N-glycosylation signatures of plasma IgG in patients with chronic kidney disease (CKD) remain unclear. This study aimed to propose a novel method to explore the N-glycosylation pattern of IgG and to compare it with reported methods. We separated human plasma IgG from 58 healthy controls (HC) and 111 patients with CKD. Purified IgG molecules were digested by trypsin. Tryptic peptides with-out enrichment were analyzed using a combination of electron-transfer/higher-energy collisional dissociation (EThcD) and stepped collision energy/higher-energy collisional dissociation (sceHCD) mass spectrometry (EThcD-sceHCD-MS/MS). This resulted in higher spectral quality, more informative fragment ions, higher Byonic score, and nearly twice the depth of intact N-glycopeptide identification than sceHCD or EThcD alone. Site-specific N-glycosylation mapping revealed that intact N-glycopeptides were differentially expressed in HC and CKD patients; thus, it can be a diagnostic tool. This study provides a method for the determination of glycosylation patterns in CKD and a framework for understanding the role of IgG in the pathophysiology of CKD.

Project description:Site-specific N-glycosylation characterization requires intact N-glycopeptide analysis based on suitable tandem mass spectrometry (MS/MS) method. Electron-transfer/higher-energy collisional dissociation (EThcD), stepped collision energy/higher-energy collisional dissociation (sceHCD), and higher-energy collision dissociation-product-dependent electron-transfer dissociation (HCD-pd-ETD) have emerged as valuable approaches for clinical glycoproteomics. However, each of them incurs some compromise, necessitating the performance comparisons when applied to the analysis of complex clinical samples (e.g., plasma, urine, cells, and tissue). Herein, we developed a hybrid mass spectrometry fragmentation method, EThcD-sceHCD, by combining EThcD and sceHCD. Moreover, we compared the performance of this method with those previous approaches (EThcD, sceHCD, HCD-pd-ETD, and sceHCD-pd-ETD) in the intact N-glycopeptide analysis, and determined its applicability for clinical N-glycoproteomic study.

Project description:The recently described O-glycoprotease OpeRATOR presents exciting opportunities for O-glycoproteomics. This bacterial enzyme purified from A. muciniphila cleaves N-terminally to serine and threonine residues that are modified with (preferably asialylated) O-glycans, providing orthogonal cleavage relative to canonical proteases (e.g., trypsin) to improve O-glycopeptide characterization with tandem mass spectrometry (MS/MS). O-glycopeptides with a modified N-terminal residue, such as those generated by OpeRATOR, present several potential benefits, perhaps the most notable being de facto O-glycosite localization without the need of glycan-retaining fragments in MS/MS spectra. Indeed, O-glycopeptides modified exclusively at the N-terminus would enable O-glycoproteomic methods to rely solely on collision-based fragmentation rather than electron-driven dissociation, but modified peptides would need to reliably contain only a single O-glycosite. Here we characterize the number of O-glycosites (i.e., missed cleavages) that are present in OpeRATOR-derived O-glycopeptides using methods that combine collision- and electron-based fragmentation. Our data show that over 50% of O-glycopeptides generated from combined digestion using OpeRATOR and trypsin contain multiple O-glycosites, indicating that collision-based fragmentation is not sufficient for OpeRATOR-centric studies and that electron-driven dissociation remains a requirement for site-specific O-glycopeptide characterization.

Project description:Mass spectrometry is the premier tool for identifying and quantifying site-specific protein glycosylation globally. Analysis of intact glycopeptides often requires an enrichment step, after which the samples remain highly complex and exhibit a broad dynamic range of abundance. Here, we evaluated the analytical benefits of high-field asymmetric waveform ion mobility spectrometry (FAIMS) coupled to nano-liquid chromatography mass spectrometry (nLC-MS) for analyses of intact glycopeptide devoid of any enrichment step. We compared the effects of compensation voltage on the transmission of N- and O-glycopeptides derived from heterogeneous protein mixtures using two FAIMS devices. We comprehensively demonstrate the performance characteristics of the FAIMS device for glycopeptide analysis and recommend optimal electrode temperature and compensation voltage (CV) settings for N- and O-glycopeptide analysis. Under optimal CV settings, FAIMS-assisted gas-phase fractionation in conjunction with chromatographic reverse phase separation resulted in a 31% increase in the detection of both N- and O-glycopeptide compared to control experiments without FAIMS. Overall, our results demonstrate that FAIMS provides an alternative means to access glycopeptides without any enrichment providing an unbiased global glycoproteome landscape. In addition, our work provides the framework to verify ‘difficult-to-identify’ glycopeptide features.

Project description:A comprehensive screening of glycopeptides as candidate biomarkers from human serum for early diagnosis of NASH hepatocellular carcinoma using a stepped HCD method and PRM evaluation. Glycopeptides from vitronectin(VTNC) has been reported as biomarkers for NASH-related HCCs.

Project description:N-glycosylation is an essential post-translational modification (PTM) of human milk proteins for the promotion of infant health. N-glycosylation is relevant regarding proteolytic susceptibility and functions as a competitive inhibitor of pathogen binding and immunomodulators. Due to the individual uniqueness of human milk, the overall complexity and temporal changes of N-glycosylation, the analysis for site-specific information of this PTM must take these factors into consideration. Here we demonstrate, by adapting the automated platform and hydrophilic-interaction chromatography (HILIC)-based cartridge with 150 μg of milk protein digestion, that proteome-wide N-glycopeptides can be reproducibly enriched in technical triplicates and biological samples across lactation. With higher energy c-trap dissociation (HCD) triggered electron-transfer/higher-energy collision dissociation (EThcD), we were able to map, to our knowledge, the most comprehensive human milk N-glycoproteome to date. We found 1697 glycopeptides from 110 glycoproteins and 191 glycosites of which 43 novel sites were not yet reported in experimental evidence. We next quantified the glycopeptides in targeted monitoring mode with scheduled selective ion monitoring (SIM) and parallel reaction monitoring (PRM). Co-trending HCD fragment ions enabled us to pinpoint the MS1 extracted ion chromatogram (XIC) of intact glycopeptide. In a 90 min gradient, we could measure 318 glycopeptides from 51 glycoproteins, catching at least 10 data points in their chromatographic peaks. We observed distinctive quantitative site-specific glycosylation trends, indicating the potential of specific temporal changes associated with functions that support the developing infant’s health.