1,975 research outputs found

    12PLECTIN GALACTOSIDE-BINDING SOLUBLE 3 BINDING PROTEIN (LGALS3BP) IS A CANCER-ASSOCIATED LIGAND FOR INHIBITORY SIGLECS

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    Tumor cells subvert the control of the immune system by downregulation of their antigenicity and production of an immunosuppressive microenvironment including the upregulation and engagement of inhibitory receptors on immune cells. Therapeutic strategies have demonstrated that the immune system can be reactivated and control established cancers by blocking inhibitory receptors on immune cells such CTLA-4 and PD1. While such activation of the immune system is successful in some patients, many patients still show cancer progression after some time. Thus, the definition of new targetable immunomodulatory pathways is needed to improve the outcome in those patients. Recent evidence suggests that sialic acid dependent ligands on tumor cells can engage inhibitory sialic acid binding immunoglobulin-like lectins (Siglecs) on NK cells and cells of the myelomonocytic lineage and thereby facilitate evasion of immune-mediated killing. Moreover, the presence of a natural variant of Siglec-9 with reduced binding capacity to sialic acid dependent ligands in patients with non-small cell lung cancer improved the two year survival in a retrospective multivariate analysis. Here we identify a novel cancer-associated ligand for immuno-inhibitory Siglecs by affinity chromatography and subsequent proteomic analysis. LectinGalactoside-Binding Soluble 3 Binding Protein (LGALS3BP) bound to various inhibitory Siglecs including Siglec-5, Siglec-9 and Siglec-10 with high affinity. LGALS3BP was previously found to be upregulated in various carcinomas such as breast, colorectal, prostate and lung cancer and linked to advanced stage and poor prognosis. The exact function during cancer progression, however, was not yet defined. Our findings provide a novel insight into how LGALS3BP could promote immune evasion by inhibiting immune cell activation through engagement of Siglecs and defines LGALS3BP-Siglec interactions as potential novel target to interfere with cancer progression and reactivate the immune system against carcinomas. Disclosure: All authors have declared no conflicts of interes

    Conformational Studies of Oligosaccharides

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    The conformation of a molecule strongly affects its function, as demonstrated for peptides and nucleic acids. This correlation is much less established for carbohydrates, the most abundant organic materials in nature. Recent advances in synthetic and analytical techniques have enabled the study of carbohydrates at the molecular level. Recurrent structural features were identified as responsible for particular biological activities or material properties. In this Mini-review, recent achievements in the structural characterization of carbohydrates, enabled by systematic studies of chemically defined oligosaccharides, are discussed. These findings can guide the development of more potent glycomimetics. Synthetic carbohydrate materials by design can be envisioned

    Glyconanoparticles for colorimetric bioassays

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    Carbohydrate molecules are involved in many of the cellular processes that are important for life. By combining the specific analyte targeting of carbohydrates with the multivalent structure and change of solution colour as a consequence of plasmonic interactions with the aggregation of metal nanoparticles, glyconanoparticles have been used extensively for the development of bioanalytical assays. The noble metals used to create the nanocore, the methodologies used to assemble the carbohydrates on the nanoparticle surface, the carbohydrate chosen for each specific target, the length of the tether that separates the carbohydrate from the nanocore and the density of carbohydrates on the surface all impact on the structural formation of metal based glyconanoparticles. This tutorial review highlights these key components, which directly impact on the selectivity and sensitivity of the developed bioassay, for the colorimetric detection of lectins, toxins and viruses

    Centralized Modularity of N-Linked Glycosylation Pathways in Mammalian Cells

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    Glycosylation is a highly complex process to produce a diverse repertoire of cellular glycans that are attached to proteins and lipids. Glycans are involved in fundamental biological processes, including protein folding and clearance, cell proliferation and apoptosis, development, immune responses, and pathogenesis. One of the major types of glycans, N-linked glycans, is formed by sequential attachments of monosaccharides to proteins by a limited number of enzymes. Many of these enzymes can accept multiple N-linked glycans as substrates, thereby generating a large number of glycan intermediates and their intermingled pathways. Motivated by the quantitative methods developed in complex network research, we investigated the large-scale organization of such N-linked glycosylation pathways in mammalian cells. The N-linked glycosylation pathways are extremely modular, and are composed of cohesive topological modules that directly branch from a common upstream pathway of glycan synthesis. This unique structural property allows the glycan production between modules to be controlled by the upstream region. Although the enzymes act on multiple glycan substrates, indicating cross-talk between modules, the impact of the cross-talk on the module-specific enhancement of glycan synthesis may be confined within a moderate range by transcription-level control. The findings of the present study provide experimentally-testable predictions for glycosylation processes, and may be applicable to therapeutic glycoprotein engineering

    Epidermolysa bullosa in Danish Hereford calves is caused by a deletion in LAMC2 gene

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    BACKGROUND Heritable forms of epidermolysis bullosa (EB) constitute a heterogeneous group of skin disorders of genetic aetiology that are characterised by skin and mucous membrane blistering and ulceration in response to even minor trauma. Here we report the occurrence of EB in three Danish Hereford cattle from one herd. RESULTS Two of the animals were necropsied and showed oral mucosal blistering, skin ulcerations and partly loss of horn on the claws. Lesions were histologically characterized by subepidermal blisters and ulcers. Analysis of the family tree indicated that inbreeding and the transmission of a single recessive mutation from a common ancestor could be causative. We performed whole genome sequencing of one affected calf and searched all coding DNA variants. Thereby, we detected a homozygous 2.4 kb deletion encompassing the first exon of the LAMC2 gene, encoding for laminin gamma 2 protein. This loss of function mutation completely removes the start codon of this gene and is therefore predicted to be completely disruptive. The deletion co-segregates with the EB phenotype in the family and absent in normal cattle of various breeds. Verifying the homozygous private variants present in candidate genes allowed us to quickly identify the causative mutation and contribute to the final diagnosis of junctional EB in Hereford cattle. CONCLUSIONS Our investigation confirms the known role of laminin gamma 2 in EB aetiology and shows the importance of whole genome sequencing in the analysis of rare diseases in livestock
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