Project description:We monitored longitudinal changes in bovine milk IgG in samples from four cows at 9 time points in between 0.5-28 days following calving. We used peptide-centric LC-MS/MS on proteolytic digests of whole bovine milk, resulting in the combined identification of 212 individual bovine milk protein sequences, with IgG making up >50% of the protein content of every 0.5 d colostrum sample, which reduced to ≤3% in mature milk. In parallel, we analysed IgG captured from the bovine milk samples to characterise its N-glycosylation, using dedicated methods for bottom-up glycoproteomics employing product ion-triggered hybrid fragmentation. The bovine milk IgG N-glycosylation profile was revealed to be very heterogeneous, consisting of >40 glycoforms. Furthermore, these N-glycosylation profiles changed substantially over the period of lactation, but consistently across the four individual cows. We identified NeuAc sialylation as the key abundant characteristic of bovine colostrum IgG, significantly decreasing in the first days of lactation, and barely detectable in mature bovine milk IgG. We also report, for the first time to our knowledge, the identification of subtype IgG3 in bovine milk, alongside the better-documented IgG1 and IgG2. The detailed molecular characteristics we describe of the bovine milk IgG, and their dynamic changes during lactation, are important not only for the fundamental understanding of the calf’s immune development, but also for understanding bovine milk and its bioactive components in the context of human nutrition.

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: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:Mass spectrometry has become an indispensable tool for the characterisation of glycosylation across biological systems. Our ability to generate rich fragmentation data of glycopeptides has dramatically improved over the last decade yet our informatic approaches still lag be hide. This is especially true for the study of bacterial glycosylation where manual determination of glycopeptides is still heavily used. This dependence on manual assignment/identification is not scalable, extremely time consuming and limits accessibility of bacterial glycosylation studies to field specialists. As such computational approaches to examine bacterial glycosylation and determine glycan diversity within samples are desperately needed. Here we describe the use of wide-tolerance (up to 2000 Da) open searching as a means to rapidly examine bacterial glycoproteomes. We benchmarked this approach using N-linked glycopeptides of Campylobacter fetus subsp. fetus as well as O-linked glycopeptides of Acinetobacter baumannii and Burkholderia cenocepacia revealing glycopeptides modified with a range of glycans can be readily identified without defining the glycan masses prior to database searching. Utilising this approach, we demonstrate how wide tolerance searching can be used to compare glycan utilisation across bacterial species by examining the glycoproteomes of eight Burkholderia species (B. pseudomallei; B. multivorans; B. dolosa; B. humptydooensis; B. ubonensis, B. anthina; B. diffusa; B. pseudomultivorans). Finally, we also demonstrate how open searching enables the identification of low frequency glycoforms based on shared modified peptides sequences. Combined these results show that open searching is a robust computational approach for the determination of glycan diversity within novel microbial glycosylation systems.

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:HKU1 is a human betacoronavirus and infects host cells via highly glycosylated spike protein (S). At present, N-glycosylation of HKU1 S has been reported, however, little is known about its O-glycosylation, which hinders an in-depth understanding of its biological functions. Herein, a comprehensive study of O-glycosylation of HKU1 S was carried out based on dual-functional histidine-bonded silica materials (HBS). The enrichment method for O-glycopeptides with HBS was developed and validated using standard proteins. The application of the developed method to HKU1 S1 subunit resulted in 61 novel O-glycosylation sites, among which 56% were predicted to be exposed on protein outer surface. Moreover, the O-linked glycans and their abundance on each HKU1 S1 site were also analyzed. The obtained O-glycosylation dataset would provide valuable insights for the understanding of the structure of HKU1 S.

Project description:Intact glycopeptide analysis has been of great interest because it can elucidate glycosylation site information and glycan structural composition at the same time. However, mass-spectrometry (MS)-based glycoproteomic analysis is hindered by the low stoichiometry of glycosylation and poor ionization efficiency of glycopeptides. Due to the relatively large amounts of starting materials needed for enrichment, identification and quantification of intact glycopeptides in some size-limited biological systems are especially challenging. To overcome these limitations, here we developed an improved boosting strategy to enhance N,N-dimethyl leucine tagging-based quantitative glycoproteomic analysis, termed as Boost-DiLeu. With integration of one-tube sample processing workflow and high pH fractionation, 3514 quantifiable N-glycopeptides were identified from 30 µg HeLa cell tryptic digests with reliable quantification performance. Furthermore, this strategy was applied to human cerebrospinal fluid (CSF) samples to differentiate N-glycosylation profiles between Alzheimer’s disease patients and healthy donors. The results revealed processes and pathways affected by dysregulated N-glycosylation in AD, including platelet degranulation, cell adhesion, and extracellular matrix, which highlighted the involvement of N-glycosylation aberrations in AD pathogenesis. Moreover, co-expression network analysis (WGCNA) showed 3 modules of glycoproteins, one of which are associated with AD phenotype. Our results demonstrated the feasibility of using this strategy for comprehensive glycoproteomic analysis of size-limited clinical samples. Taken together, we developed and optimized a strategy for enhanced comprehensive quantitative intact glycopeptide analysis with DiLeu labeling, which is especially promising for identifying novel therapeutic targets or biomarkers in sample size limited models or systems.

Project description:The molecular processes underlying human milk production and the effects of mastitic infection are largely unknown because of limitations in obtaining tissue samples. Determination of gene expression in normal lactating women would be a significant step towards understanding why some women display poor lactation outcomes. Here we demonstrate the utility of RNA obtained directly from human milk cells to detect mammary epithelial cell (MEC)-specific gene expression. Milk cell RNA was collected from 5 time points (24 hours pre-partum during the colostrum period, mid lactation, two involution, and during a bout of mastitis) in addition to an involution series comprising three time points. Gene expression profiles were determined by use of human Affymetrix arrays. Milk cells collected during milk production showed that the most highly expressed genes were involved in milk synthesis (eg. CEL, OLAH, FOLR1, BTN1A1, ARG2), while milk cells collected during involution showed a significant down regulation of milk synthesis genes and activation of involution associated genes (eg. STAT3, NF-kB, IRF5, IRF7). Milk cells collected during mastitic infection revealed regulation of a unique set of genes specific to this disease state, whilst maintaining regulation of milk synthesis genes. Use of conventional epithelial cell markers was used to determine the population of MECâ??s within each sample. This paper is the first to describe the milk cell transcriptome across the human lactation cycle and during mastitic infection, providing valuable insight into gene expression of the human mammary gland. Human milk sampling throughout lactation cycle and during mastitic infection.

Project description:Detection of breast cancer (BC) in young women is challenging because mammography, the most common tool for detecting BC, is not effective on the dense breast tissue characteristic of young women. In addition to the limited means for detecting their BC, young women face a transient increased risk of pregnancy-associated BC. As a consequence, reproductively active women could benefit significantly from a tool that provides them with accurate risk assessment and early detection of BC. One potential method for detection of BC is biochemical monitoring of proteins and other molecules in bodily fluids such as serum, nipple aspirate, ductal lavage, tear, urine, saliva and breast milk. Of all these fluids, only breast milk provides access to a large volume of breast tissue, in the form of exfoliated epithelial cells, and to the local breast environment, in the form of molecules in the milk. Thus, analysis of breast milk is a non-invasive method with significant potential for assessing BC risk. Here we analyzed human breast milk by mass spectrometry (MS)-based proteomics to build a biomarker signature for early detection of BC. Ten milk samples from 8 women provided 5 paired-groups (cancer versus control) for analysis of differentially expressed proteins: 2 within woman comparisons (milk from a diseased breast versus a healthy breast of the same woman) and 3 across women comparisons (milk from a woman with cancer versus a woman without cancer). Despite a wide range in the time between milk donation and cancer diagnosis (cancer diagnosis occurred from 1 month before to 24 months after milk donation), the levels of some proteins differed significantly between cancer and control in several of the 5 comparison groups. These pilot data are supportive of the idea that molecular analysis of breast milk will identify proteins informative for early detection and accurate assessment of BC risk, and warrant further research.

Project description:Protein post-translational modifications (PTMs) are pivotal molecular events in plant cells, encompassing processes such as protein folding and enzyme activation. Among these PTMs, N-glycosylation and phosphorylation hold particular importance, as they play essential roles in regulating plant growth and stress responses. The intricate PTM landscape is exemplified by the identification of multiple plant membrane-localized proteins subject to both phosphorylation and N-glycosylation, hinting at potential interplay influencing protein functionality. To investigate the crosstalk between phosphorylation and glycosylation in plant signaling, immobilized metal affinity chromatography (IMAC) and hydrophilic interaction chromatography (HILIC) have been primarily utilized for large-scale phosphopeptide and glycopeptide enrichment, respectively. In this work, we introduce a novel streamlined tandem S-Trap-IMAC-HILIC strategy, termed TIMAHAC, to enable serial enrichment of phosphopeptides and glycopeptides. This approach successfully integrates the two methods through tandem tip enrichment, eliminating the need for buffer exchange and sample transfer. As a result, it significantly minimizes sample loss during serial enrichment steps, and streamlines experimental procedures, ultimately saving time. We demonstrated the efficiency of the TIHAMAC strategy in the glycoproteomics and phosphoproteomics analyses using 200 μg of Arabidopsis digests. Up to 1,954 N-glycopeptides and 11,255 phosphopeptides were identified by timsTOF HT. Remarkably, 69% of N-glycopeptides were consistently quantified with a coefficient of variation less than 20%. Furthermore, more than one-third identified glycoproteins exhibited phosphorylation modifications. These results suggest that the applicability of the TIMAHAC method for studying the potential crosstalk of N-glycoproteome and phosphoproteome within complex plant signaling networks.