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:Multi-modal single cell RNA sequencing enables the precise mapping of transcriptional and phenotypic features of cellular differentiation states, but does not allow for simultaneous integration of critical post-translational modification data. Here, we describe SUrface-protein Glycan And RNA-seq (SUGAR-seq); a method that enables detection and analysis of N-linked glycosylation, extracellular epitopes and the transcriptome at the single cell level. Integrated SUGAR-seq and glycoproteome analysis identified tumor infiltrating T cells with unique surface glycan properties that report their epigenetic and functional state.

Project description:Multi-modal single cell RNA sequencing enables the precise mapping of transcriptional and phenotypic features of cellular differentiation states, but does not allow for simultaneous integration of critical post-translational modification data. Here, we describe SUrface-protein Glycan And RNA-seq (SUGAR-seq); a method that enables detection and analysis of N-linked glycosylation, extracellular epitopes and the transcriptome at the single cell level. Integrated SUGAR-seq and glycoproteome analysis identified tumor infiltrating T cells with unique surface glycan properties that report their epigenetic and functional state.

Project description:Multi-modal single cell RNA sequencing enables the precise mapping of transcriptional and phenotypic features of cellular differentiation states, but does not allow for simultaneous integration of critical post-translational modification data. Here, we describe SUrface-protein Glycan And RNA-seq (SUGAR-seq); a method that enables detection and analysis of N-linked glycosylation, extracellular epitopes and the transcriptome at the single cell level. Integrated SUGAR-seq and glycoproteome analysis identified tumor infiltrating T cells with unique surface glycan properties that report their epigenetic and functional state.

Project description:Multi-modal single cell RNA sequencing enables the precise mapping of transcriptional and phenotypic features of cellular differentiation states, but does not allow for simultaneous integration of critical post-translational modification data. Here, we describe SUrface-protein Glycan And RNA-seq (SUGAR-seq); a method that enables detection and analysis of N-linked glycosylation, extracellular epitopes and the transcriptome at the single cell level. Integrated SUGAR-seq and glycoproteome analysis identified tumor infiltrating T cells with unique surface glycan properties that report their epigenetic and functional state.

Project description:Alpha fetoprotein (AFP) is a circulating cancer biomarker implicated in multiple neoplastic malignancies, including hepatocellular carcinoma (HCC). AFP glycoforms with core fucosylation structure (AFP-L3) are used clinically as a biomarker, to predict risk of developing HCC and to monitor its recurrence. Mature AFP has a single glycosylation site, while there is a high degree of structural variation in AFP-glycan modifications. Because AFP has single glycosylation site, masses of intact AFP proteoforms can be used to differentiate and identify PTM in their native states. We developed a method for intact AFP glycoform analysis that utilizes AFP-specific immune-enrichment, followed by LC-high resolution mass spectrometry (LC-HRMS) analysis to differentiate and quantitate the relative abundance of AFP glycoforms and evaluated the method’s performance.

Project description:To understand biological and pathological functions of protein glycosylations, it is crucial to uncover glycan heterogeneities, which depend on the type and status of cells, for each glycosite of single glycoprotein. For evaluating the glycan heterogeneities at macro-, micro-, and meta-levels, a reliable strategy is needed to compare site-specific glycoforms of glycoproteins in two and more samples, such as different tissues, in a comprehensive manner. To analyze this "inter-heterogeneity" of samples, we have developed a MS1-based glycopeptide detection method named "Glycan heterogeneity-based Relational Identification of Glycopeptide signals on Elution profile (Glyco-RIDGE)." In the present study, to elucidate inter-tissue glycan heterogeneities, the Glyco-RIDGE method was applied to site-specific N-glycoform analysis of six mouse tissues. To improve the sensitivity of analysis, glycopeptides prepared from the tissues were desialylated and fractioned, and then analyzed using the Glyco-RIDGE method. The validity of the MS1-based method was confirmed for the liver using MS2 spectra. This method estimated 11,325 site-specific N-glycoforms with 239 glycan compositions on 1,260 sites of 800 glycoproteins, revealing inter-tissue differences in macro-, micro-, and meta-glycan heterogeneities.

Project description:The biological consequences of various IL-6 glycoforms are unknown. To uncover the function of N-glycosylation of IL-6 in lung cancer, we compare the gene expression profiles in NSCLC cells induced by conditioned medium containing IL-6 with complete N-glycosylation (NG-IL6) or defective N-glycosylation (deNG-IL6).

Project description:Glycosylation is an important post-translational modification (PTM) mechanism of proteins, that modulates protein function. Measurement of clinically adopted cancer protein biomarkers is commonly performed using affinity-based techniques, which often suffer from poor specificity and inability to distinguish between closely related proteoforms. Alpha fetoprotein (AFP) is a circulating cancer biomarker implicated in multiple neoplastic malignancies, including hepatocellular carcinoma (HCC). AFP glycoforms with core fucosylation structure (AFP-L3) are used clinically as a biomarker, to predict risk of developing HCC and to monitor its recurrence. Mature AFP has a single glycosylation site, while there is a high degree of structural variation in AFP-glycan modifications. Because AFP has single glycosylation site, masses of intact AFP proteoforms can be used to differentiate and identify PTM in their native states. We developed a method for intact AFP glycoform analysis that utilizes AFP-specific immune-enrichment, followed by LC-high resolution mass spectrometry (LC-HRMS) analysis to differentiate and quantitate the relative abundance of AFP glycoforms and evaluated the method’s performance.

Project description:The multifunctional -galactoside-binding protein galectin-3 is found in many distinct subcellular compartments including the cell nucleus. Expression and distribution of galectin-3 between the cell nucleus and the cytosol changes during cell differentiation and cancer development. Nuclear functions of galectin-3 and how they contribute to tumorigenesis are not understood. In order to identify nuclear galectin-3 interaction partners, we used affinity chromatography and co-immunoprecipitation. Spatial proximity in the nucleus was assessed by immunofluorescence and proximity ligation assay. We also investigated the function of galectin-3 on mRNA-export by fluorescence in situ hybridization and on mRNA-processing by RNA-sequencing.