Search results for "HAp"

showing 10 items of 2767 documents

Distribution of mitochondrial chaperonins in lung cells

2011

Lungmedicine.anatomical_structureChaperonins Hsp10 Hsp60 lung respiratory diseases fibroblasts epithelial cellsSettore BIO/16 - Anatomia UmanaGeneticsmedicineDistribution (pharmacology)BiologyMolecular BiologyBiochemistryBiotechnologyChaperoninCell biologyThe FASEB Journal
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Coupling of Contact Sensitizers to Thiol Groups is a Key Event for the Activation of Monocytes and Monocyte-Derived Dendritic Cells

2003

Strong contact sensitizers are able to induce distinct signal transduction mechanisms in antigen-presenting cells by coupling to cell proteins. The predominant target structures of haptens are thought to be thiol and amino groups in cysteine and lysine residues. We studied whether coupling of small reactive chemicals to thiol or amino groups might be responsible for the activation of monocytes and mature monocyte-derived dendritic cells. Human peripheral blood mononuclear cells were stimulated in vitro with subtoxic concentrations of the strong haptens 5-chloro-2-methylisothiazolinone plus 2-methylisothiazolinone and 2, 4, 6-trinitrochlorobenzene, the thiol-reactive reagents N-hydroxymaleim…

MAP Kinase Signaling SystemCD14SuccinimidesPicryl ChlorideDermatologyAcetatesPeripheral blood mononuclear cellBiochemistryamino groupsAntioxidantsMonocytesMaleimideschemistry.chemical_compoundAnti-Infective AgentsmedicineHumansCysteineSulfhydryl CompoundsPhosphorylationAntigen-presenting cellMolecular Biologythiol groupsChemistryMonocyteLysineSulfhydryl ReagentsTyrosine phosphorylationDendritic cellDendritic CellsCell BiologyThiazolesmedicine.anatomical_structureBiochemistryEthylmaleimidehaptenTyrosineSignal transductionsignal transductionCysteineInterleukin-1Journal of Investigative Dermatology
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Thapsigargin-stimulated MAP kinase phosphorylation via CRAC channels and PLD activation: inhibitory action of docosahexaenoic acid.

2004

AbstractThis study was conducted on human Jurkat T-cells to investigate the role of depletion of intracellular Ca2+ stores in the phosphorylation of two mitogen-activated protein kinases (MAPKs), i.e. extracellular signal-regulated kinase (ERK) 1 and ERK2, and their modulation by a polyunsaturated fatty acid, docosahexaenoic acid (DHA). We observed that thapsigargin (TG) stimulated MAPK activation by store-operated calcium (SOC) influx via opening of calcium release-activated calcium (CRAC) channels as tyrphostin-A9, a CRAC channel blocker, and two SOC influx inhibitors, econazole and SKF-96365, diminished the action of the former. TG-stimulated ERK1/ERK2 phosphorylation was also diminished…

MAPK/ERK pathwayThapsigarginDocosahexaenoic AcidsBiophysicschemistry.chemical_elementCalciumBiochemistryDiglycerideschemistry.chemical_compoundJurkat CellsStructural BiologyGeneticsPhospholipase DHumansPhosphorylationMolecular BiologyProtein kinase CProtein Kinase CDiacylglycerol kinaseMitogen-Activated Protein Kinase 1Mitogen-Activated Protein Kinase 3Phospholipase CChemistryKinasePhospholipase DRyanodine Receptor Calcium Release ChannelCell BiologyJurkat T-cellCell biologyEnzyme Activationenzymes and coenzymes (carbohydrates)Docosahexaenoic acidFatty Acids UnsaturatedThapsigarginlipids (amino acids peptides and proteins)CalciumMitogen-Activated Protein KinasesFEBS letters
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Di- and Tetrairon(III) μ-Oxido Complexes of an N3S-Donor Ligand: Catalyst Precursors for Alkene Oxidations

2019

The new di- and tetranuclear Fe(III) μ-oxido complexes [Fe 4 (μ-O) 4 (PTEBIA) 4 ](CF 3 SO 3 ) 4 (CH 3 CN) 2 ] (1a), [Fe 2 (μ-O)Cl 2 (PTEBIA) 2 ](CF 3 SO 3 ) 2 (1b), and [Fe 2 (μ-O)(HCOO) 2 (PTEBIA) 2 ](ClO 4 ) 2 (MeOH) (2) were prepared from the sulfur-containing ligand (2-((2,4-dimethylphenyl)thio)-N,N-bis ((1-methyl-benzimidazol-2-yl)methyl)ethanamine (PTEBIA). The tetrairon complex 1a features four μ-oxido bridges, while in dinuclear 1b, the sulfur moiety of the ligand occupies one of the six coordination sites of each Fe(III) ion with a long Fe-S distance of 2.814(6) A. In 2, two Fe(III) centers are bridged by one oxido and two formate units, the latter likely formed by methanol oxidati…

MECHANISMFe-S interactionoxidation116 Chemical sciencesThio-rautaSULFURHomogeneous catalysis02 engineering and technology010402 general chemistry01 natural sciencesMedicinal chemistrythioetherCatalysislcsh:Chemistrychemistry.chemical_compoundThioetheriron-oxo complexAcetonitrileta116Fe-S interaction; homogeneous catalysis; iron-oxo complex; oxidation; thioetherOriginal Researchchemistry.chemical_classificationeetteritFUNCTIONAL-MODELCOORDINATIONPEROXIDEAlkeneLigandACTIVE-SITEhapettuminenGeneral Chemistrykompleksiyhdisteet021001 nanoscience & nanotechnology540COPPER-COMPLEXEShomogeneous catalysis0104 chemical sciencesChemistrychemistrylcsh:QD1-999katalyysiACIDOXO0210 nano-technologySelectivityNONHEME IRON CATALYSTSFrontiers in Chemistry
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Effect of oxidative stress on UDP-glucuronosyltransferases in rat astrocytes.

2012

WOS:000309170300003; International audience; The present work reports data regarding effects of an induced oxidative stress on the mainly expressed isoforms of UDP-glucuronosyltransferases (UGTs) in the brain. UGT1A6 and UGT1A7 expression and enzymatic activities toward the 1-naphthol were analyzed in rat cultured astrocytes following the exposure for 48 h to redox-cycling xenobiotic compounds such as quinones and bipyridinium ions. The expression of NADPH:cytochrome P450 reductase and NAD(P)H:quinone oxidoreductase 1 (NQO1) was also investigated. Oxidative stress induced significant deleterious changes in astrocyte morphology, decreased cell viability and inhibited catalytic function of UG…

MESH : Oxidative StressMESH : RNA MessengerAntioxidantTranscription Geneticmedicine.medical_treatmentToxicologyNAD(P)H:quinone oxidoreductase 1MESH: GlucuronosyltransferaseAntioxidantsSubstrate SpecificityRats Sprague-Dawley0302 clinical medicineMESH: NADPH-Ferrihemoprotein ReductaseMESH: GlucuronidesNAD(P)H Dehydrogenase (Quinone)MESH : CatalysisMESH: AnimalsMESH : NAD(P)H Dehydrogenase (Quinone)GlucuronosyltransferaseCells Culturedchemistry.chemical_classificationMESH : Cell Survival0303 health sciencesMESH : Substrate SpecificityMESH : Animals NewbornCytochrome P450 reductaseGeneral MedicineMESH: Cell SurvivalMESH: Pyridinium CompoundsMESH : AntioxidantsMESH: Cells CulturedOxidative phosphorylationGene Expression Regulation EnzymologicMESH : QuinonesMESH : Glucuronides03 medical and health sciencesRNA MessengerCell ShapeNADPH-Ferrihemoprotein ReductaseMESH : Oxidation-ReductionMESH : Pyridinium CompoundsMESH: NaphtholsMESH : GlucuronosyltransferaseMESH: AntioxidantsMESH: CatalysischemistryOxidative stressAstrocytesReactive Oxygen Species030217 neurology & neurosurgeryMESH: Oxidation-ReductionTime Factors[ SDV.AEN ] Life Sciences [q-bio]/Food and NutritionMESH : Reactive Oxygen SpeciesNADPH:cytochrome P450 reductasePyridinium CompoundsNaphtholsMESH: Rats Sprague-DawleyProtein oxidationmedicine.disease_causeMESH: Animals NewbornMESH: NAD(P)H Dehydrogenase (Quinone)Protein CarbonylationMESH : OxidantsMESH: OxidantsMelatoninMESH: MelatoninMESH: Oxidative StressMESH : MelatoninMESH : RatsMESH: Gene Expression Regulation EnzymologicQuinonesMESH: Reactive Oxygen SpeciesOxidantsBiochemistryMESH : Protein CarbonylationOxidation-ReductionUDP-glucuronosyltransferaseMESH : Time FactorsMESH: Protein CarbonylationMESH: RatsCell SurvivalMESH : NaphtholsBiologyCatalysisMESH: QuinonesMESH : Gene Expression Regulation EnzymologicGlucuronidesMESH : Cells CulturedmedicineAnimalsMESH: Cell Shape030304 developmental biologyMESH: RNA MessengerReactive oxygen speciesMESH: Transcription GeneticMESH: Time FactorsMESH : AstrocytesMESH : Transcription GeneticNAD(P)H Dehydrogenase (Quinone)MESH : Rats Sprague-DawleyRatsMESH: AstrocytesAnimals NewbornMESH : NADPH-Ferrihemoprotein ReductaseMESH: Substrate SpecificityMESH : AnimalsNAD+ kinaseMESH : Cell Shape[SDV.AEN]Life Sciences [q-bio]/Food and NutritionOxidative stress
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Pig domestication and human-mediated dispersal in western Eurasia revealed through ancient DNA and geometric morphometrics.

2013

Zooarcheological evidence suggests that pigs were domesticated in Southwest Asia ∼8,500 BC. They then spread across the Middle and Near East and westward into Europe alongside early agriculturalists. European pigs were either domesticated independently or more likely appeared so as a result of admixture between introduced pigs and European wild boar. As a result, European wild boar mtDNA lineages replaced Near Eastern/Anatolian mtDNA signatures in Europe and subsequently replaced indigenous domestic pig lineages in Anatolia. The specific details of these processes, however, remain unknown. To address questions related to early pig domestication, dispersal, and turnover in the Near East, we …

MESH: Sequence Analysis DNAsequence analysisSwineSus scrofa[SHS.ANTHRO-BIO]Humanities and Social Sciences/Biological anthropologyinsightsshapephylogeography01 natural sciences11. SustainabilityexpansionsMESH: AnimalswildNeolithicMESH: Swineagriculture0303 health sciencesKUL-METH-ArchaeologyMESH: AsiaPig domesticationmitochondrialEuropeDomestic pigMESH: PhylogeographyAnimals DomestichistoryMESH: Molareuropewild boar010506 paleontologyKUL-CoE-CASoriginsAsialikelihoodneolithic; phylogeography; pig domestication; wild boar; animal distribution; animals; animals domestic; Asia; DNA mitochondrial; Europe; humans; molar; phylogeography; sequence analysis DNA; Sus scrofa; SwineZoologypig domesticationfarmersBiologyNeolithic.Animal Breeding and GenomicsSettore BIO/08Wild boarDNA Mitochondrial03 medical and health sciencesWild boarBronze Agebiology.animalGeneticsdomesticAnimalsHumansFokkerij en GenomicaMESH: Animals DomesticDomesticationMolecular BiologyEcology Evolution Behavior and SystematicsDiscoveries030304 developmental biology0105 earth and related environmental sciencesMESH: Humans[SDV.GEN.GPO]Life Sciences [q-bio]/Genetics/Populations and Evolution [q-bio.PE]MESH: Animal DistributionMESH: DNA MitochondrialDNASequence Analysis DNAMolarMESH: Sus scrofaAncient DNAIron AgeWIASBiological dispersalMESH: EuropeAnimal DistributionChronology
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The Molecular dYnamics SHAred PharmacophorE (MYSHAPE) approacha new tool to arise docking and pharmacophore modeling performance: virtues and vices

2017

In a recent paper, we presented a new virtual screening workflow that addresses the arising issues of molecular docking and pharmacophore modeling when using a single set of coordinates and a single active ligand [1]. MD simulations were carried out and ligand-protein interactions were analyzed and collected together with their appearance frequency. A pharmacophore model was then created using only the common feature patterns that all the ligands exhibited during MD simulations. This ‘Molecular dYnamics SHAred PharmacophorE’ was then used for virtual screening on active and inactive molecules library. MYSHAPE was also used as constraints for the creation of the docking grid. The application…

MYSHAPE Pharmacophore
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The Hsc/Hsp70 Co-Chaperone Network Controls Antigen Aggregation and Presentation during Maturation of Professional Antigen Presenting Cells

2011

The maturation of mouse macrophages and dendritic cells involves the transient deposition of ubiquitylated proteins in the form of dendritic cell aggresome-like induced structures (DALIS). Transient DALIS formation was used here as a paradigm to study how mammalian cells influence the formation and disassembly of protein aggregates through alterations of their proteostasis machinery. Co-chaperones that modulate the interplay of Hsc70 and Hsp70 with the ubiquitin-proteasome system (UPS) and the autophagosome-lysosome pathway emerged as key regulators of this process. The chaperone-associated ubiquitin ligase CHIP and the ubiquitin-domain protein BAG-1 are essential for DALIS formation in mou…

Macromolecular AssembliesImmune CellsCellular differentiationImmunologyAntigen presentationAntigen-Presenting Cellslcsh:MedicineAntigen Processing and RecognitionMajor histocompatibility complexBiochemistryMiceMolecular Cell BiologyMHC class IAutophagyAnimalsHSP70 Heat-Shock ProteinsAntigensProtein Interactionslcsh:ScienceAntigen-presenting cellBiologyImmune ResponseCellular Stress ResponsesAntigen PresentationMultidisciplinarybiologylcsh:RHSC70 Heat-Shock ProteinsImmunityProteinsCell DifferentiationDendritic cellChaperone ProteinsUbiquitin ligaseCell biologyProteostasisbiology.proteinlcsh:QProtein MultimerizationResearch ArticlePLoS ONE
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Decoding the Folding of Burkholderia glumae Lipase: Folding Intermediates En Route to Kinetic Stability

2012

The lipase produced by Burkholderia glumae folds spontaneously into an inactive near-native state and requires a periplasmic chaperone to reach its final active and secretion-competent fold. The B. glumae lipase-specific foldase (Lif) is classified as a member of the steric-chaperone family of which the propeptides of alpha-lytic protease and subtilisin are the best known representatives. Steric chaperones play a key role in conferring kinetic stability to proteins. However, until present there was no solid experimental evidence that Lif-dependent lipases are kinetically trapped enzymes. By combining thermal denaturation studies with proteolytic resistance experiments and the description of…

Macromolecular AssembliesProtein StructureProtein FoldingBurkholderiaProtein ConformationStereochemistryBiophysicslcsh:MedicineBiochemistryProtein Chemistrybacterial lipasemolten globuleBacterial ProteinsNative stateBurkholderia glumaeLipaseProtein Interactionslcsh:ScienceBiologyMultidisciplinarybiologylipase-specific foldasePhysicslcsh:RSubtilisinProteinsLipasebiology.organism_classificationMolten globuleEnzymesChaperone ProteinsKineticsBiochemistryChaperone (protein)Enzyme StructureProteolysisFoldasebiology.proteinlcsh:Qsteric chaperoneProtein foldingnear-native folding intermediateResearch ArticleMolecular Chaperones
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Sesquiterpenoids in subtribe Centaureinae (Cass.) Dumort (tribe Cardueae, Asteraceae): distribution, (13)C NMR spectral data and biological propertie…

2012

Asteraceae Bercht. & J. Presl is one of the biggest and most economically important plant families. The taxonomy and phylogeny of Asteraceae is rather complex and according to the latest and most reliable taxonomic classification of Panero & Funk, based on the analysis of nine chloroplast regions, the family is divided into 12 subfamilies and 35 tribes. One of the largest tribes of Asteraceae is Cardueae Cass. with four subtribes (Carlininae, Echinopinae, Carduinae and Centaureinae) and more than 2500 species. Susanna & Garcia-Jacas have organized the genera of Centaureinae (about 800 species) into seven informal groups, which recent molecular studies have confirmed: 1. Basal genera; 2. Vol…

Magnetic Resonance Spectroscopy13C NMR spectral dataPlant ScienceHorticultureRhaponticumAsteraceaeBiochemistryElemaneSerratulaPhylogeneticsBotanySettore BIO/15 - Biologia FarmaceuticaAntiviralSpectral dataMolecular BiologyPhylogenyEffects on insectGermacranebiologyMolecular StructurePlant ExtractsCentaureinaeGeneral MedicineSettore CHIM/06 - Chimica OrganicaAsteraceaebiology.organism_classificationCentaureinaeCentaureaGuiaianesAntiprotozoalTaxonomy (biology)AntimicrobialAnti-inflammatoryEffects on plantEudesmaneAntitumor and cytotoxicSesquiterpenesPhytochemistry
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