Project description:Recombinant proteins are of great interest in glycobiology and proteomics, known especially for their reproducibility and accessibility. However, variation in glycosylation among recombinant glycoproteins is not well understood and may depend on numerous conditions in the biomanufacturing process. In order to confidently assess variation in glycosylation measurements, it is vital to both optimize the measurement of, and determine the degree of variation between, distributions of glycosylation on specific sites of glycoproteins. This is especially important for glycoproteins that are known to have rapid sequence changes, such as with different influenza strains. In this study, eight strains of recombinant influenza hemagglutinin and neuraminidase produced from HEK293 cell line were obtained from four vendors and digestion was conducted using a series of complex multi-enzymatic methods designed to isolate glycopeptide sequons. Site-specific glycosylation profiles of intact glycopeptides were produced using mass spectrometric evaluation on an orbitrap system and compared using spectral similarity scores. Variation in glycan abundances and distribution was most pronounced between different strains of virus (similarity score = 383 out of 1000), whereas replicates resulted in low variation (similarity score = 957 out of 1000). Glycan variation was also measured based on differences between vendors, lots, batches, protease digestion, and intra-protein site. The most abundant glycans in all of these influenza glycoproteins were monofucosylated and complex, as reported by other laboratories. However, it was found that different vendors can produce very different glycan distributions for the same glycosylation site. Notably, it is demonstrated that glycan distributions are similar for conserved regions of influenza glycoproteins. Overall, these methods present a potential use in developing reproducible measurements of glycosylated biologics for quality control or making more informed decisions in biomanufacturing.

Project description:Dr. Esko's laboratory focuses on the structure, function, and biosynthesis of glycoproteins and proteoglycans. This laboratory also works on the design and synthesis of small molecule inhibitors of glycosylation. Gene expression in F9 teratocarcinoma cells: Study of the differential expression of glycosyltransferases, sulfotransferases and proteoglycan core proteins in F9 teratocarcinoma cells before and after differentiation with retinoic acid/theophylline/cAMP. Published data indicated that differentiation of the cells induces the synthesis of anticoagulant heparin-like compounds and a large increase in overall glycosaminoglycan synthesis. Glyco-gene Chip microarray analysis of RNA samples (in triplicate) from the cells before and after differentiation to reveal factors that regulate the assembly process and how it leads to the generation of binding sites for glycan-binding proteins.

Project description:Impaired T cell immunity in the elderly increases mortality from infectious disease. The branching of Asparagine-linked glycans is a critical negative regulator of T cell immunity. We found that N-glycan branching increases with age in female > male, naïve > memory and CD4+ > CD8+ T cells, likely contributing to immunosenescence. To investigate the mechanisms driving these changes, we performed RNA-seq analysis on highly purified young and old naive (CD3+CD4+CD25-CD62L+CD44-) and effector memory (CD3+CD4+CD25-CD62L-CD44+) CD4+ T cells from male and female mice. Comparing young and old CD4+ TN cells, 158 and 192 differentially expressed genes (DEGs) were identified in females and males, respectively. Remarkably, only 44 of these overlapped between the sexes. There were no significant differences in gene expression of N-glycan branching enzymes or other relevant glycosylation genes. Among the 114 DEGs in female but not male CD4+ TN cells, four were within the IL-7 signaling pathway, a pathway previously implicated in regulating N-glycan branching. This included reduced expression of IL7Rα (CD127) and increased expression of Suppressor of cytokine signaling 1 (Socs1), Socs3, and Janus kinase 3 (Jak3). Other IL-7 signaling pathway genes were unchanged.

Project description:The UT-A1 urea transporter is crucial to the kidney’s ability to generate concentrated urine. Native UT-A1 from kidney inner medulla (IM) is a heavily glycosylated protein with two glycosylation forms of 97 and 117 kDa. In diabetes, UT-A1 protein abundance, particularly the 117 kD isoform, is significantly increased corresponding to an increased urea permeability in perfused IM collecting ducts, which plays an important role in preventing the osmotic diuresis caused by glucosuria. In this study, using sugar-specific binding lectins, we found that the carbohydrate structure of UT-A1 is also changed under diabetic conditions with increased amounts of sialic acid, fucose, and increased glycan branching. These changes were accompanied by altered UT-A1 association with the galectin proteins, α-galactoside glycan binding proteins. To explore the molecular basis of the alterations of glycan structures, the highly sensitive next generation sequencing (NGS) technology, Illumina RNA-seq, was employed to analyze genes involved in the process of UT-A1 glycosylation using streptozotocin (STZ) - induced diabetic rat kidney as the tissue source. Differential expression analysis combining quantitative PCR revealed that a number of important glycosylation related genes were changed under diabetic conditions. These genes include the glycosyltransferase genes Mgat4a, the sialylation enzymes St3gal1 and St3gal4and glycan binding protein galectin-3, -5, -8 and -9. In contrast, although highly expressed in kidney IM, the glycosyltransferase genes Mgat1, Mgat2, and fucosyltransferase Fut8, did not show any changes. We conclude that the alteration of these glycosylation related genes may contribute to changing the UT-A1 glycan structure, and therefore modulate kidney urea transport activity under diabetic conditions.

Project description:Tunicamycin inhibits the first step of protein N-glycosylation modification. However, the physiological, transcriptomic, and N-glycomic effects of tunicamycin on important marine diatom Phaeodactylum tricornutum are still unknown. In this study, comprehensive approaches were used to study the effects. The results showed that cell growth and photosynthesis were significantly inhibited in P. tricornutum under the tunicamycin stress. The soluble protein content was significantly decreased, while the soluble sugar and neutral lipid were dramatically increased to orchestrate the balance of carbon and nitrogen metabolism. 0.3 μg m-1 tunicamycin could not complete inhibited the N-glycosylation of protein, but it resulted in the differentially expression of ERQC and ERAD related genes. The upregulation of genes involved in ERQC and the activation of anti-oxidases were speculated to alleviate the tunicamycin stress. The differentially expression of genes related to ERAD was suggested to degrade the unfolded and/or incorrect N-glycoproteins induced by tunicamycin. The identification of mannose-type and complex-type N-glycan structures enriched the N-glycan database of diatom P. tricornutum and provided important information for studying the function of N-glycosylation modification on proteins. All in all, the proposed working models of ERQC and ERAD will provide a solid foundation for further in-depth study the related mechanism and the diatom expression system.

Project description:Analysis of mucin-type O-glycan regulation of gene expression in murine intestinal epithelial cells isolated from a mouse. The hypothesis tested in the current study was that loss of Cosmc (by Cre/Lox: Vil-Cre+ X Cosmcflox/+), which is required for core 1-based O-glycan extension, influences gene expression. Transcripts from colorectum and from small intestine were compared to also evaluate whether O-glycans control different genes in different regions of the gut. We had particular interest in identifying transcripts or pathways important in regulating the microbiota or influencing intestinal inflammation. Results provide important information on how cell surface glycosylation controls gene transcription in in vivo.

Project description:Aberrant glycosylation is a characteristic of tumor cells. The expression of certain glycan structures has been associated with poor prognosis. In cervical carcinoma has been reported changes in the gene expression level of some glycogenes that has been associated with lymph invasion. Human papilloma virus (HPV) infection is one of the most important factors to develop cervical cancer. HPV oncoproteins E6 and E7 have been implicated in cervical carcinogenesis. The role of these oncoproteins in glycosylation changes has not been reported. To know the effect of these oncoproteins on glycogene expression we realized a partial silencing of oncogenes E6 and E7 in HeLa cells, we made a microarray expression assay and we identified glycogenes that modified its expression. The analysis showed alteration in some glycosylation pathways, like glycosphingolipid, O-glycan mucin-type, and O-glycan non mucin-type glycosylation. Our results suggest that E6 and E7 oncoproteins could modified glycosylation of structures implicated in proliferation, adhesion, and apoptosis.

Project description:Glycoproteins, representing over 50% of human proteins and most biopharmaceuticals, are crucial for regulating various biological processes. The complexity of multiple glycosylation sites often leads to incomplete sequence coverage and ambiguous glycan modification profiles. Here, we developed an integrative mass spectrometry-based approach for decoding unknown glycoproteins, which is featured with the combination of deglycosylation-mediated de novo sequencing with glycosylation site characterization. We utilized enzymatic deglycosylation of N-/ O- glycans to achieve comprehensive sequence coverage. Additionally, EThcD fragmentation enables the identification of high-quality long peptides, facilitating precise protein assembly. We subsequently applied this method to de novo sequencing of the highly glycosylated therapeutic fusion protein Etanercept (Enbrel®). We also sequenced three new tumor necrosis factor receptor (TNFR): Fc-fusion biologics with largely unknown sequences, unveiling subtle distinctions in the primary sequences. Furthermore, we characterized N- and O-glycosylation modifications of these proteins at subunit, glycopeptide, and glycan levels. This strategy bridges the gap between the de novo sequencing and glycosylation modification, providing comprehensive information of the primary structure and glycosylation modifications for glycoproteins. Notably, our method could be a robust solution for accurate sequencing of the glycoproteins and has practical value not only in basic research but also in the biopharmaceutical industry.

Project description:Aberrant mucin type O-linked glycosylation is a common occurrence in cancer. This type of O-linked glycosylation can occur on many cell surface glycoproteins where only a small number of sites may be present. EGFR is one such glycoprotein. Upon EGF ligation, EGFR induces a signaling cascade but can also translocate to the nucleus where it can directly regulate gene transcription. Here we show that upon EGF binding, breast cancer cells carrying different O-linked glycans respond by transcribing differential gene expression signatures. This is not a result of changes in signal transduction but due to the differential nuclear translocation of EGFR in the two glyco-phenotypes. This appears to be regulated by the formation of a EGFR/galectin-3/MUC1 complex at the cell surface that is present in cells carrying short core1-based O-glycans characteristic of tumour cells but absent in core 2 O-glycan carrying cells representative of normal mammary epithelial cells.

Project description:Our studies provide direct evidence that O-glycosylation pathways play a role in the regulation of cell growth through apoptosis and proliferation pathways. Eight small molecular weight analogues of the GalNAc-alpha-1-O-serine/threonine structure based on 1-benzyl-2-acetamido-2- deoxy-alpha-O-D-galactopyranoside have been synthesised and tested in 5 human colorectal cancer cell lines. Three inhibitors, 1-benzyl-2-acetamido-2-deoxy-alpha-O-D-galactopyranoside and the corresponding 2-azido- and C-glycoside analogues, were screened in two colorectal cancer cell lines at 0.5mM and showed induction of apoptosis. Proliferation was down regulated in the same two cell lines with all three inhibitors, as detected by Ki67 staining and gene array. Treatment both cell lines with inhibitors led to changes in glycosylation detected with peanut lectin. The competitive action of the inhibitors resulted in the intracellular formation of 28 aryl-glycan products which were identified by MALDI and electrospray mass spectroscopy. The structures found map onto known O-glycosylation biosynthetic pathways and showed a differential pattern for each of the inhibitors in both cell lines. Gene array analysis of the glycogenes illustrated a pattern of glycosytransferases that matched the glycan structures found in glycoproteins and aryl-glycans formed in the PC/AA/C1/SB10C cells, however there was no action of the three inhibitors on glycogene transcript levels. The inhibitors act at both intermediary metabolic and genomic levels, resulting in altered protein glycosylation and arylglycan formation. These events may play a part in growth arrest. Keywords: Response to inhibitors, Apoptosis, Aryl-glycans, Benzyl-O-GalNAc, Growth Inhibition, O-Glycans