Project description:The UDP-N-acetylgalactosamine polypeptide:N-acetylgalactosaminyltransferase (GalNAc-T) family of enzymes initiates O-linked glycosylation by catalyzing the addition of the first GalNAc sugar to serine or threonine on proteins destined to be membrane-bound or secreted. Defects in individual isoforms of the GalNAc-T family can lead to certain congenital disorders of glycosylation (CDG). The GALNT3-CDG, is caused by mutations in GALNT3, resulting in hyperphosphatemic familial tumoral calcinosis (HFTC) due to impaired glycosylation of the phosphate-regulating hormone FGF23 within osteocytes of the bone. Patients with hyperphosphatemia present altered bone density, abnormal tooth structure and calcified masses throughout the body. It is therefore important to identify all potential substrates of GalNAc-T3 throughout the body to understand the complex disease phenotypes. Here, we compared the Galnt3-/- mouse model, which partially phenocopies GALNT3-CDG, with wild-type mice and employed a multi-component approach utilizing chemoenzymatic conditions, a product-dependent method constructed using EThcD triggered scans in a mass spectrometry workflow, quantitative O-glycoproteomics, and global proteomics to identify 663 Galnt3-specific O-glycosites from 269 glycoproteins across multiple tissues. Consistent with the mouse and human phenotypes, functional networks of glycoproteins that contain GalNAc-T3-specific O-glycosites involved in skeletal morphology, mineral level maintenance and hemostasis were identified. This library of in vivo GalNAc-T3-specific substrate proteins and O-glycosites will serve as a valuable resource to understand the functional implications of O-glycosylation and to unravel the underlying causes of complex human GALNT3-CDG phenotypes.

Project description:The UDP-N-acetylgalactosamine polypeptide:N-acetylgalactosaminyltransferase (GalNAc-T) family of enzymes initiates O-linked glycosylation by catalyzing the addition of the first GalNAc sugar to serine or threonine on proteins destined to be membrane-bound or secreted. Defects in individual isoforms of the GalNAc-T family can lead to certain congenital disorders of glycosylation (CDG). The GALNT3-CDG, is caused by mutations in GALNT3, resulting in hyperphosphatemic familial tumoral calcinosis (HFTC) due to impaired glycosylation of the phosphate-regulating hormone FGF23 within osteocytes of the bone. Patients with hyperphosphatemia present altered bone density, abnormal tooth structure and calcified masses throughout the body. It is therefore important to identify all potential substrates of GalNAc-T3 throughout the body to understand the complex disease phenotypes. Here, we compared the Galnt3-/- mouse model, which partially phenocopies GALNT3-CDG, with wild-type mice and employed a multi-component approach utilizing chemoenzymatic conditions, a product-dependent method constructed using EThcD triggered scans in a mass spectrometry workflow, quantitative O-glycoproteomics, and global proteomics to identify 663 Galnt3-specific O-glycosites from 269 glycoproteins across multiple tissues. Consistent with the mouse and human phenotypes, functional networks of glycoproteins that contain GalNAc-T3-specific O-glycosites involved in skeletal morphology, mineral level maintenance and hemostasis were identified. This library of in vivo GalNAc-T3-specific substrate proteins and O-glycosites will serve as a valuable resource to understand the functional implications of O-glycosylation and to unravel the underlying causes of complex human GALNT3-CDG phenotypes.

Project description:A large family of GalNAc transferases (GalNAc-Ts) catalyzes the covalent attachment of N-Acetylgalactosamine (GalNAc) to serine and threonine residues on proteins that pass through the secretory pathway in the first committed step of mucin-type O-glycosylation. Abnormalities in the activity of individual GalNAc-Ts can result in congenital disorders of O-glycosylation (CDG) and influence other biological functions. Although ~85% of proteins that pass through the secretory pathway are modified with O-glycans, only 47 O-glycosylation sites (O-glycosites) from 22 mouse glycoproteins and 17 publications are present on UniProt and an O-glycoprotein database (http://www.oglyp.org/). A compilation of all in vivo O-glycosites (the O-glycoproteome) would be an invaluable step in determining the function of proteins decorated with N-Acetylgalactosamine and what role(s), if any, the O-glycans play. While approaches to delineate O-glycosites have been developed for simple, genetically engineered cell lines, there is no universal approach to mapping the O-glycosites of glycoproteins in complex tissue extracts or biological fluids. We have developed chemical and enzymatic conditions that cleave solitary O-glycans while leaving the modified core protein/peptides assayable by mass spectrometry (MS). The methodology permits the mapping of thousands of O-glycosites decorated with Tn or T antigen from tissues or biological fluids. We then integrated an HCD-pd-EThcD MS workflow and software, including MSFragger-Glyco, pGlyco3, and O-Pair, to study the mouse brain, heart, lung, liver, spleen, kidney, colon, muscle, submandibular gland, and whole blood. The integrated approach identified 2154 solitary O-glycosites from 595 glycoproteins. The O-glycosites and glycoproteins displayed consensus motifs and Gene Ontology (GO) terms for O-glycoproteins. Limited overlap of O-glycosites was observed with protein O-GlcNAcylation and phosphorylation sites. Integrating quantitative glycoproteomics and proteomics revealed a tissue-specific regulation of O-glycosites that the differential expression of Galnt isoenzymes in tissues partly contributes to. We next used established quantitative glycoproteomics and proteomics methods to identify site-specific substrates that may contribute to biologically relevant phenotypes when Galnt2 was genetically ablated in a Galnt2-null mouse model, which presents with lipid and metabolic dysregulation. Our findings suggest networks of Galnt2 direct and indirect interactions that may explain the complex metabolic phenotypes. The mouse O-glycoproteome-map and quantitative glycoproteomics/proteomics approach will provide a valuable foundation for revealing the significance of O-glycosylation biology in CDGs and other diseases and conditions.

Project description:Corticosteroid-binding globulin (CBG) delivers anti-inflammatory cortisol to inflamed tissues through the proteolytic cleavage of an exposed reactive centre loop (RCL) by neutrophil elastase (NE). We previously demonstrated that RCL-localised Asn347-linked N-glycans impact NE proteolysis, but a comprehensive structure-function characterisation of the RCL glycosylation is still required to better understand CBG glycobiology. Herein, we firstly performed RCL-centric glycoprofiling of serum-derived CBG to elucidate the Asn347-glycans and then used molecular dynamics (MD) simulations to study their impact on NE proteolysis. Importantly, we also identified novel O-glycosylation (di/sialyl T) across four RCL sites (Thr338/Thr342/Thr345/Ser350) of serum CBG close to the NE-targeted Val344-Thr345 cleavage site. A restricted N- and O-glycan co-occurrence pattern on the RCL involving exclusively Asn347 and Thr338 sites was experimentally observed and supported in silico by modelling of a CBG-GalNAc-transferase (GalNAc-T) complex with various RCL glycans. GalNAc-T2 and -T3 abundantly expressed by liver and gallbladder, respectively, showed in vitro a capacity to transfer GalNAc (Tn) to multiple RCL sites suggesting their involvement in RCL O-glycosylation. Recombinant CBG (rCBG) was then used to determine roles of RCL O-glycosylation through longitudinal NE-centric proteolysis experiments, which demonstrated that both sialo- (disialyl T) and asialo-glycans (T) decorating Thr345 inhibit NE proteolysis. Synthetic RCL O-glycopeptides expanded on these findings by showing that Thr345-Tn and Thr342-Tn confer strong and moderate protection against NE cleavage, respectively. MD substantiated that short Thr345-linked O-glycans abrogate NE interactions. In conclusion, we report on strategically-positioned and biologically-relevant CBG RCL glycans, which improve our understanding of mechanisms governing cortisol delivery to inflamed tissues.

Project description:In this project, CSF samples from healthy volunteers and patients diagnosed with congenital disorders of glycosylation (CDG) were analyzed with MS-based glycoproteomics to characterize the glycoproteome in the two cohorts. In order to identify highly truncated glycopeptides and glycopeptides that show the complete loss of glycosylation, we chose to not perform a glycopeptide enrichment. Using the high identification rate of the timsTOF Pro including PASEF fragmentation, we were able to detect over 800 unique glycopeptides. We show that changes in protein N-glycosylation of CDG patients can be different on brain-derived proteins compared to blood derived proteins.

Project description:The densely glycosylated spike (S) proteins that are highly exposed on the surface of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) facilitate viral attachment, entry, and membrane fusion. We have previously reported all the 22 N-glycosites and site-specific N-glycans in the S protein protomer. Herein, we report the comprehensive site-specific O-glycosylation landscapes of SARS-CoV-2 S proteins, which were characterized using high-resolution mass spectrometry. Following digestion using trypsin and trypsin/Glu-C, and de-N-glycosylation using PNGase F, we determined the mucin-type (GalNAc-type) O-glycosylation pattern of S proteins, including O-glycosites and the 6 most common O-glycans occupying them, via Byonic identification and manual validation. Finally, 43 O-glycosites were identified by higher energy collision-induced dissociation (HCD), and 11 O-glycosites were verified by electron transfer/higher energy collision-induced dissociation (EThcD) in the insect cell-expressed S protein. Most glycosites were modified by non-sialylated O-glycans such as HexNAc(1) and HexNAc(1)Hex(1). In contrast, 30 O-glycosites were identified by HCD, and 14 O-glycosites were verified by EThcD in the human cell-expressed S protein S1 subunit. Most glycosites were modified by sialylated O-glycans such as HexNAc(1)Hex(1)NeuAc(1) and HexNAc(1)Hex(1)NeuAc(2). Our results are the first to reveal that the SARS-CoV-2 S protein is a mucin-type glycoprotein; clustered O-glycans often occur in the N- and the C-termini of the S protein, and the O-glycosite and O-glycan compositions vary with the host cell type. These site-specific O-glycosylation landscapes of the SARS-CoV-2 S protein are expected to provide novel insights into the viral binding mechanism and present a strategy for the development of vaccines and targeted drugs.

Project description:Protein glycosylation is a highly diverse post-translational modification, modulating key cellular processes such as cell signaling, adhesion and cell-cell interactions. Its deregulation has been associated with various pathologies, including cancer and neurological diseases. Methods capable of quantifying glycosylation dynamics are essential to start unraveling the biological functions of protein glycosylation. Here we present Deep Quantitative Glycoprofiling (DQGlyco), a method that combines high-throughput sample preparation, high-sensitivity detection, and precise multiplexed quantification of protein glycosylation. We used DQGlyco to profile the mouse brain glycoproteome, in which we identify more than 200,000 unique N-glycopeptides - this amounts to 25-fold more glycopeptides identified compared to previous studies. We observed extensive heterogeneity of glycoforms and determined their functional and structural preferences. We used our quantitative approach to map surface-exposed glycoforms as well as to characterize glycosites tissue-specificity. The presence of a defined gut microbiota resulted in extensive remodeling of the brain glycoproteome when compared to that of germ-free animals, exemplifying how the gut microbiome may affect brain protein functions.

Project description:Most proteins trafficking the secretory pathway of metazoan cells will acquire GalNAc-type O-glycosylation. GalNAc-type O-glycosylation is differentially regulated in cells by the expression of a repertoire of up to twenty genes encoding polypeptide GalNAc-transferase isoforms (GalNAc-Ts) that initiate O-glycosylation by catalyzing the attachment of GalNAc residues to select Ser and Thr residues. These GalNAc-Ts orchestrate the positions and patterns of O-glycans on proteins in poorly understood coordinated ways guided partly by the kinetic properties and substrate specificities of their catalytic domains and modulatory effects of their unique GalNAc-binding lectin domains. Here, we provide the hereto most comprehensive characterization of the non-redundant contributions of individual GalNAc-T isoforms to the O-glycoproteome of the human HEK293 cell line using quantitative differential O-glycoproteomics on a panel of isogenic HEK293 cell lines with knockout of GalNAc-T genes (GALNT1, T2, T3, T7, T10, or T11). We confirm that a major part of the O-glycoproteome is covered by redundancy, while distinct subsets of O-glycosites are covered by non-redundant GalNAc-T isoform-specific functions. We demonstrate that GalNAc-T7 and T10 as predicted from in vitro studies function in completion of high density O-glycosylated regions, while GalNAc-T11 selectively controls the site-specific O-glycosylation of low-density lipoprotein-related receptors in the linker regions between the ligand-binding LDLR class A repeats.

Project description:N-acetylgalactosaminyl transferases (GalNAc-Ts) initiate mucin-type O-glycosylation, an abundant and complex post-translational modification that regulates host-microbe interactions, tissue development, and metabolism. GalNAc-Ts contain a C-terminal lectin domain consisting of three homologous repeats (, , where and can potentially interact with O-GalNAc on substrates to enhance activity towards a nearby acceptor Thr/Ser. The ubiquitous isoenzyme GalNAc-T1 modulates diverse biological functions, including heart development, immunity, and SARS-CoV-2 infectivity, but its substrates are largely unknown. Here, we show that both and in GalNAc-T1 uniquely orchestrate the O-glycosylation of various glycopeptide substrates. The repeat directs O-glycosylation to acceptor sites C-terminal to an existing GalNAc, while the repeat directs O-glycosylation to N-terminal sites. Additionally, GalNAc-T1 incorporates and binding into various substrate binding modes to cooperatively increase the specificity towards an intermediate acceptor site. Our studies highlight a unique mechanism by which dual lectin repeats expand substrate specificity and inform on identifying the biological substrates affected by disruptions in GalNAc-T1 function.

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.