Search results for " glycosylation"

showing 7 items of 27 documents

Conformational response to ligand binding in phosphomannomutase2: insights into inborn glycosylation disorder.

2014

Background: Mutations in phosphomannomutase2 cause glycosylation disorder, a disease without a cure that will largely benefit from accurate ligand-bound models. Results: We obtained two models of phospomannomutase2 bound to glucose 1,6-bisphosphate and validated them with limited proteolysis. Conclusion: Ligand binding induces a large conformational transition in PMM2. Significance: We produce and validate closed-form models of PMM2 that represent a starting point for rational drug discovery.

Models MolecularPELEGlycosylationProtein Conformation1Molecular Sequence DataGlucose-6-PhosphateGlycosylation Inhibitor6-bisphosphate; PELE; computer modeling; drug discovery; glycosylation; glycosylation inhibitor; ligand-binding protein; phosphomannomutaseLigandsDrug DiscoveryAnimalsHumansAmino Acid Sequence16-BisphosphateProtein UnfoldingTemperatureLigand-binding Proteinphosphomannomutase 2 and mass spectrometryPhosphotransferases (Phosphomutases)PhosphomannomutaseMutationProteolysisMetabolism Inborn ErrorsMolecular BiophysicsPeptide HydrolasesProtein BindingComputer ModelingThe Journal of biological chemistry
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Biological properties of extracellular vesicles and their physiological functions

2015

The authors wish to thank Dr R Simpson and Dr D Taylor for critical reading of the manuscript and acknowledge the Horizon 2020 European Cooperation in Science and Technology programme and its support of our European Network on Microvesicles and Exosomes in Health & Disease (ME-HaD; BM1202 www.cost.eu/COST_Actions/bmbs/Actions/BM1202). In the past decade, extracellular vesicles (EVs) have been recognized as potent vehicles of intercellular communication, both in prokaryotes and eukaryotes. This is due to their capacity to transfer proteins, lipids and nucleic acids, thereby influencing various physiological and pathological functions of both recipient and parent cells. While intensive invest…

ProteomicsCellular distributionMATURE DENDRITIC CELLSReviewReview ArticleUrineEmbryo developmentMonocyteProtein processingVascular biologyFecesVesícules seminalsSYNCYTIOTROPHOBLAST MICROVILLOUS MEMBRANESCell selectionPregnancyT lymphocyteBileCELL-DERIVED EXOSOMESBiogenesisLung lavageUterus fluidInnate immunityMale genital systemlcsh:CytologyMicrovesicleOUTER-MEMBRANE VESICLESBlood clottingprokaryoteEukaryotaExtracellular vesicleRNA analysisCell biologyBloodCerebrospinal fluidLiver metabolismmicrovesicleMorphogenHumanNervous systemCell signalingBreast milkNatural killer cellFisiologiaExtracellular vesiclesExosomelcsh:QH573-671SalivaBiologyBiology and Life SciencesDNAPlantRNA transportCell functionMacrophageMolecular biologyPhysiologyMedizinProteomicsFACTOR PATHWAY INHIBITOReukaryoteProtein glycosylationExtracellular spaceTissue repairEspai extracel·lularReticulocyteSeminal plasmaMesenchymal stem cellAntigen presenting cellSeminal vesiclesNose mucusBiofilmNeutrophilMicroRNAPLANT-MICROBE INTERACTIONSLipidAmnion fluidProkaryotamicroparticleCell interactionCell transporteukaryote exosome extracellular vesicle microparticle microvesicle physiology prokaryoteBone mineralizationMicroorganismHistologyAdaptive immunityMembrane vesicleComputational biologyMembrane receptorBiologyStressCell communicationMast cellMESENCHYMAL STEM-CELLSHUMAN ENDOTHELIAL-CELLSexosomeCytokineSynovial fluidCell BiologyNonhumanIMMUNE-MODULATORY FEATURESReview articleDNA contentphysiologyRNAINTESTINAL EPITHELIAL-CELLSextracellular vesicleBody fluidLectinBiogenesis
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N-Glycosyl Amides as Glycosyl Donors in Stereoselective Glycosylation Reactions

2004

Due to their high stability, N-glycosyl amides have so far not been considered as glycosyl donors for glycosylation reactions. Two new procedures for the cleavage of the anomeric amide functionality under mild reaction conditions and further stereoselective in situ conversions of the activated glycosyl donors with alcohols and amines to give β-configured O- and N-glycosides are described in this article.

Reaction conditionsanimal structuresAnomerGlycosylationStereochemistryChemical glycosylationOrganic ChemistryGeneral Medicinemacromolecular substancesCleavage (embryo)Koenigs–Knorr reactionCatalysiscarbohydrates (lipids)chemistry.chemical_compoundchemistryAmidelipids (amino acids peptides and proteins)GlycosylStereoselectivityGlycosyl donorSynthesis
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Apical transport of osteopontin is independent of N-glycosylation and sialylation.

2002

Studies of how epithelial surface polarity into apical and basolateral domains is generated and maintained have proposed that carbohydrate modifications serve as apical targeting signals for proteins by interacting with lectin sorters. However, the experimental evidence in support of N-glycans, O-glycans and sialic acids mediating apical transport is still very controversial. This could be partly due to the fact that in most studies exogenously expressed proteins were analysed. One has, therefore, examined the role of carbohydrate moieties in apical targeting of the endogenous secretory protein osteopontin in MDCK cells. It was found, however, that sorting of osteopontin does not require N-…

Signal peptideAcetylgalactosamineGlycosylationProtein ConformationSialoglycoproteinsOligosaccharidesBiologyProtein Sorting SignalsKidneyCell Linechemistry.chemical_compoundDogsN-linked glycosylationLectinsCell polarityBenzyl CompoundsAnimalsOsteopontinMolecular BiologyCell PolarityEpithelial CellsCell BiologySialic acidTransport proteincarbohydrates (lipids)Molecular WeightProtein TransportProtein Sorting SignalsSecretory proteinchemistryBiochemistrybiology.proteinSialic AcidsOsteopontinMolecular membrane biology
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N-Glycosyl Amides: Removal of the Anomeric Protecting Group and Conversion into Glycosyl Donors.

2003

chemistry.chemical_classificationGlycosylationAnomerMolecular StructureStereochemistryChemical glycosylationGlycosideGeneral ChemistryGeneral MedicineAmidesCatalysischemistry.chemical_compoundchemistryOrganic chemistryGlycosylGlycosidesGlycosyl donorProtecting groupChemInform
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N-glycosylation efficiency is determined by the distance to the C-terminus and the amino acid preceding an Asn-Ser-Thr sequon

2010

N-glycosylation is the most common and versatile protein modification. In eukaryotic cells, this modification is catalyzed cotranslationally by the enzyme oligosaccharyltransferase, which targets the β-amide of the asparagine in an Asn-Xaa-Ser/Thr consensus sequon (where Xaa is any amino acid but proline) in nascent proteins as they enter the endoplasmic reticulum. Because modification of the glycosylation acceptor site on membrane proteins occurs in a compartment-specific manner, the presence of glycosylation is used to indicate membrane protein topology. Moreover, glycosylation sites can be added to gain topological information. In this study, we explored the determinants of N-glycosylati…

chemistry.chemical_classificationGlycosylationbiologyOligosaccharyltransferaseSequonBiochemistryAmino acidcarbohydrates (lipids)chemistry.chemical_compoundN-linked glycosylationBiochemistrychemistryO-linked glycosylationbiology.proteinlipids (amino acids peptides and proteins)AsparagineGlycoproteinMolecular BiologyProtein Science
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Response to: Is newly diagnosed diabetes a stronger risk factor than pre‐existing diabetes for COVID ‐19 severity?

2020

medicine.medical_specialty2019-20 coronavirus outbreakdiabetesglycosylationCoronavirus disease 2019 (COVID-19)COVID-19 Coronavirus diabetes glycosylationbusiness.industryEndocrinology Diabetes and MetabolismMEDLINECOVID-19medicine.diseasemedicine.disease_causeCoronavirusNewly diagnosed diabetesInternal medicineDiabetes mellitusmedicineRisk factorbusinessPre existing diabetesCoronavirusJournal of Diabetes
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