Project description:Protein glycosylation is a critical post-translational modification that plays vital roles in cellular function and disease, including infection, autoimmunity and cancer. Techniques that measure specific glycosylated proteins face challenges in sensitivity and throughput, preventing applications in single cells. We introduce Glycan Proximity Sequencing (GPS) for the integrated profiling of proteins, glycosylation and protein-specific glycoforms, as well as mRNA in single cells. GPS achieves affinity-based detection of proteins and their modifications via proximity-based single-cell RNA sequencing. Experiments using mixtures of T and B cells, together with a GnTI-knockout mutant, demonstrated sensitive detection of both global and protein-specific glycosylation differences. Applied to human peripheral blood mononuclear cells, GPS revealed dynamic glycan remodeling patterns during T cell differentiation and potential galectin-binding glycoproteins for modulating immune responses. Notably, we identified a new CD45:LELhigh subcluster of terminally differentiated effector memory CD8+ T cells that are enriched for poly-LacNAc and 2,3-sialylation modifications and associated with exhaustion and susceptibility to galectin-1–induced apoptosis. GPS also captured glycosylation changes in response to perturbations like sialidase treatment and T cell activation. GPS is a scalable and sensitive platform for single-cell glycoproteomics and protein-specific biomarker discovery, and it can reveal mechanistic insights on the role of glycosylation in T cell differentiation.

Project description:Glycosylation is the most common post-translational modification of proteins, yet genes relevant to the synthesis of glycan structure and function are incompletely represented and poorly annotated on the commercially available arrays. To fill the need for expression analysis of such genes we employed the Affymetrix technology to develop a focused and highly annotated glycogene chip representing human and murine glycogenes, including glycosyltranferases, nucleotide sugar transporters, glycosidases, proteoglycans and glycan-binding proteins. In this report the array has been used to generate glycogene expression profiles of nine murine tissues. Global analysis with a hierarchical clustering algorithm, reveals that expression profiles in immune tissues (thymus, spleen, lymph node and bone marrow) are more closely related, relative to those of non-immune tissues (kidney, liver, brain and testes). Of the biosynthetic enzymes, those responsible for synthesis of the core regions of N-and O-linked oligosaccharides are ubiquitously expressed, while glycosyltransferase that elaborate terminal structures are expressed in a highly tissue-specific manner, accounting for tissue and ultimately cell type-specific glycosylation. Comparison of gene expression profiles with MALDI-TOF profiling of N-linked oligosaccharides suggested that the alpha-1-3 fucosyltransferase IX, Fut9, is the enzyme responsible for terminal fucosylation in kidney and brain, a finding validated by analysis of Fut9 knockout mice. Two families of glycan-binding proteins, C-type lectins and siglecs, are predominately expressed in the immune tissues, consistent with their emerging functions in both innate and acquired immunity. The glycogene chip reported in this study is available to the scientific community through the Consortium for Functional Glycomics (http://www.functionalglycomics.org). Keywords: Glycogenes, Glycomics, Glycosyltransferase, Lectin, Glycosylation, Glycome, Microarray, Kidney, Fut9

Project description:Metastatic melanoma (MM) has a five-year survival rate of only 37%. The major causes of MM-related mortality are distant organ involvement and treatment resistance. These metastatic activities are often potentiated by the persistence of tumor-initiating cells (TICs) thriving in areas of hypoxia. To enhance therapy success, it is, thus, critical to understand MM TIC properties and devise MM TIC-specific treatment strategies. Our recent data suggest that MM cells have a distinct MM glycome signature characterized by fetal i-linear poly-N-acetyllactosamines (poly-LacNAc) and loss of I-branching enzyme β1,6 N-acetylglucosaminyltransferase 2 (GCNT2) that promote tumorigenicity. Whether hypoxia can instruct MM TIC development by modulating the MM glycome signature remains unknown. Here, comparative analysis of GCNT2 levels on patient melanoma cells and clinical outcome confirmed the relationship between loss of GCNT2 and poor patient survival. Moreover, MM cells with low GCNT2 showed elevated TIC marker expression and increased TIC potential, in vivo. Under hypoxia, MM cells further lost GCNT2 and I-branched poly-LacNAc expression and showed corresponding elevations in TIC markers and other glycome-related alterations. Galectin (Gal)-8, notably, was upregulated under hypoxia, preferred binding to i-linear poly-LacNAcs, increased TIC marker CD271, and was significantly elevated in sera of melanoma patients. Knockdown of Gal-8 in MM cells significantly decreased CD271 levels, even under hypoxia. Results from this investigation reveal a key role for hypoxia in enforcing the MM glycome signature and for Gal-8 as a pro-tumorigenic lectin and putative biomarker of MM.

Project description:Single-cell glycome and transcriptome profiling uncovers the glycan signature of each cell subpopulation of human iPSC-derived neurons

Project description:Somatic mutations can lead to the transformation of healthy cells into malignant cells and allow their evasion from immune surveillance. To uncover genes that play a role in the detection and lysis of tumor cells by natural killer (NK) cells, a B lymphoblastoid cell line was subjected to a genome-wide CRISPR screen. Deletion of genes for death receptor and ligands for NK activation receptors was found in cells that survived incubation with primary NK cells. Among the top hits that facilitated NK evasion was SPPL3, a gene for an endoprotease that cleaves transmembrane glycosyl transferases. SPPL3-deficient cells accumulated glycosyl transferases, such as MGAT5, and displayed increased N-glycosylation. Binding of NK receptors NKG2D and CD2 to their corresponding ligands MICB and CD58, and binding of rituximab to CD20, was disrupted. Inhibition of N-glycan maturation restored receptor binding and sensitivity to NK cells. To investigate the cause of this resistant phenotype, a secondary CRISPR screen using a glycosylation-focused library was performed in SPPL3-deficient cells. This screen identified transferases that promote the formation of highly branched N-glycans and N-acetyl-lactosamine (LacNAc) extensions as key regulators that prevent killing. A significant enrichment of poly-LacNAc-containing tetra-antennary species was confirmed by glycoproteomic analysis. These findings provide a basis for understanding why SPPL3 deletions have been linked to cancer.

Project description:single cell RNA sequencing of iPSC and Human dermal fibroblasts using 10x Genomics with 3-prime, 5-prime poly(dT) primer, and 5-prime random primer. For comparison in gene, ncRNA and enhancer detection.

Project description:This report develops a novel lectin-based affinity chromatography (LAC) method for extracellular vesicles (EVs) and demonstrates the possibility of subclassification based on their surface glycan.　EVs are lipid bilayer vesicles enclosing various biomolecules and represent their promising potential as a sensitive biomarker for detecting and monitoring various diseases. However, EVs have heterogeneous molecular compositions, even from identical donor cells by the same purification methods, which is a significant obstacle to elucidating objective biological functions. Therefore, subclassification based on their molecular compositions has been an urgent subject for addressing their heterogeneity. Here, as a novel LAC platform for EVs, we utilized a spongy-like monolithic polymer (named spongy monolith, SPM), which consists of poly(ethylene-co-glycidyl methacrylate) with continuous micropores that allowed efficient in-situ protein reaction with the epoxy groups. Two distinct lectins with different specificity, Sambucus sieboldiana agglutinin and concanavalin A, were effectively immobilized on SPM with remaining binding activity. Moreover, the large flow-through pores (>10 μm) of the SPM allowed high recovery rates of liposomal nanoparticles as a model of EVs. Finally, we employed lectin-immobilized SPMs for the subclassification of EVs based on their surface glycan structures and demonstrated their different subpopulations by proteome profiling.

Project description:Hematopoietic stem and progenitor cells (HSPCs) are required to establish and maintain the adult blood system in vertebrates. During development, HPSCs are generated from hemogenic endothelial cells that undergo an endothelial-to-hematopoietic transition (EHT). Growth factors and epigenetic changes can promote EHT, but these mechanisms do not explain its tight spatiotemporal regulation during development. Here, we show that microRNA (miR) miR-223-mediated regulation of N-glycan biosynthesis intrinsically restrains EHT, representing a new pathway that prevents excessive HSPC production. We find that miR-223 is uniquely expressed in hemogenic endothelial cells undergoing EHT and in nascent HSPCs. Loss of miR-223 promotes the expansion of these cells in the zebrafish and mouse aorta-gonad-mesonephros (AGM), where EHT occurs. miR-223 targets alg2 (alpha 1,3/ 1,6 mannosyltransferase) in the AGM endothelium to restrict hemogenic and HSPC specification. This enzyme is involved in the attachment of the N-glycans, a common co-translational modification9-12 that influences several pathophysiological processes, but has not yet been implicated in EHT. Using an N-glycosensor, we demonstrate that abundant protein N-glycan attachment occurs in vascular cells during EHT, and this process is required for HSPC production. High-throughput glycome analysis upon loss of miR-223 revealed that terminal alpha 1,3/6 mannose modifications are increased at the expense of alpha 2,3/6 sialic acid sugars. Importantly, pharmacological manipulation targeting these N-glycan types in wild-type embryos phenocopies the loss of miR-223 and enhances EHT as well as HSPC production. Thus, the N-glycome plays a previously unappreciated role as an intrinsic regulator of EHT, with specific mannose and sialic acid modifications serving as key endothelial determinants to restrict the hematopoietic fate.

Project description:Hexanucleotide repeat expansion in the C9ORF72 gene is the most frequent inherited cause of amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Poly-GR is one of the most toxic dipeptide repeat (DPR) proteins translated from the RNA repeats. It has been shown to affect protein synthesis, but how this contributes to neurodegeneration is not clear. Here, we found that poly-GR inhibits global translation by perturbing translation elongation. We identified that the transcripts with relatively slow elongation rate tend to be further stalled by poly-GR in iPSC-differentiated neurons. This increases ribosome collision and ZAKα-mediated ribotoxic stress response (RSR), which elevates the phosphorylation of p38 and promotes cell death. Knockdown of ZAKα or pharmacological inhibition of p38 can ameliorate the GR toxicity, and improve the survival of C9ORF72-ALS/FTD patient-derived iPSC-neurons. Our study reveals molecular mechanism of poly-GR mediated toxicity on global translatome, and identifies RSR as a potential therapeutic target for C9ORF72-ALS/FTD.

Project description:Healthy brain function is mediated by several complementary signalling pathways, many of which are driven by extracellular vesicles (EVs). EVs are heterogeneous in both size and cargo and are constitutively released from cells into the extracellular milieu. They are subsequently trafficked to recipient cells, whereupon their entry can modify the cellular phenotype. Here, in order to further understand the functional role of EVs in neurons, we isolated EVs by size exclusion chromatography from human induced pluripotent stem cell (iPSC)-derived neurons. Electron microscopy and dynamic light scattering revealed that the isolated EVs had a diameter of 30-100 nm. Transcriptomic and proteomics analyses of the EVs and neurons identified key molecules enriched in the EVs involved in cell surface interaction (integrins and collagens), internalisation pathways (clathrin- and caveolin-dependent), downstream signalling pathways (phospholipases, integrin-linked kinase and MAPKs), and long-term impacts on cellular development and maintenance. Overall, we show that key signalling networks and mechanisms are enriched in EVs isolated from human iPSC-derived neurons, and identify subpopulations of EVs defined by differential tetraspanin expression.