Search results for " Lipid"

showing 10 items of 481 documents

Untargeted Metabolomics Investigation on Selenite Reduction to Elemental Selenium by Bacillus mycoides SeITE01

2021

Bacillus mycoides SeITE01 is an environmental isolate that transforms the oxyanion selenite (SeO32−) into the less bioavailable elemental selenium (Se0) forming biogenic selenium nanoparticles (Bio-SeNPs). In the present study, the reduction of sodium selenite (Na2SeO3) by SeITE01 strain and the effect of SeO32− exposure on the bacterial cells was examined through untargeted metabolomics. A time-course approach was used to monitor both cell pellet and cell free spent medium (referred as intracellular and extracellular, respectively) metabolites in SeITE01 cells treated or not with SeO32−. The results show substantial biochemical changes in SeITE01 cells when exposed to SeO32−. The initial u…

Microbiology (medical)Cell signalingMembrane lipidsBacillus mycoides SeITE01 selenite selenium nanoparticles signaling molecules time course untargeted metabolomicschemistry.chemical_elementSettore BIO/19 - Microbiologia GeneraleMicrobiologychemistry.chemical_compoundselenium nanoparticlesExtracellularBacillus mycoides SeITE01time courseSettore CHIM/02 - Chimica Fisicachemistry.chemical_classificationbiologyGlutathioneBacillus mycoidesbiology.organism_classificationQR1-502Amino aciduntargeted metabolomicschemistryBiochemistrysignaling moleculesseleniteSeleniumIntracellular
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EMPLOYMENT OF CATIONIC SOLID-LIPID NANOPARTICLES AS RNA CARRIERS

2007

Gene transfer represents an important advance in the treatment of both genetic and acquired diseases. In this article, the suitability of cationically modified solid-lipid nanoparticles (SLN) as a nonviral vector for gene delivery was investigated, in order to obtain stable materials able to condense RNA. Cationic SLN were produced by microemulsion using Compritol ATO 888 as matrix lipid, Pluronic F68 as tenside, and dimethyldioctadecylammonium bromide (DDAB) as cationic lipid. The resulting particles were approximately 100 nm in size and showed a highly positive surface charge (+41 mV) in water. Size and shape were further characterized by scanning electron microscopy (SEM) measurements. M…

MicroinjectionsCell SurvivalBiomedical EngineeringPharmaceutical ScienceNanoparticleBioengineeringNanotechnologyElectrophoretic Mobility Shift AssayPoloxamerGene deliveryTransfectionParacentrotus lividusCationsSolid lipid nanoparticleAnimalsNanotechnologyeducationcationic solid lipid nanoparticles gene deliveryOvumPharmacologyeducation.field_of_studyDrug CarriersbiologyChemistryOrganic ChemistryFatty AcidsCationic polymerizationRNAMembrane ProteinsTransfectionbiology.organism_classificationLipidsQuaternary Ammonium CompoundsSea UrchinsBiophysicsMicroscopy Electron ScanningNanoparticlesRNAEmulsionsDimethyldioctadecylammonium bromideBiotechnology
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Sistemi Microparticellari Lipidici con proprietà mucoadesive per il trattamento della Broncopneumopatia Cronica Ostruttiva

Microparticelle Solide Lipidiche Broncopneumopatia Cronica Ostruttiva diametro aerodinamicop-ERK survivina cAMP 16-HBE stress ossidativo.
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Effects of a high-fat diet on energy metabolism and ROS production in rat liver.

2011

International audience; BACKGROUND & AIMS: A high-fat diet affects liver metabolism, leading to steatosis, a complex disorder related to insulin resistance and mitochondrial alterations. Steatosis is still poorly understood since diverse effects have been reported, depending on the different experimental models used. METHODS: We hereby report the effects of an 8 week high-fat diet on liver energy metabolism in a rat model, investigated in both isolated mitochondria and hepatocytes. RESULTS: Liver mass was unchanged but lipid content and composition were markedly affected. State-3 mitochondrial oxidative phosphorylation was inhibited, contrasting with unaffected cytochrome content. Oxidative…

Mitochondrial ROSMaleTranscription GeneticMESH : Reactive Oxygen SpeciesMitochondria LiverMESH : HepatocytesMitochondrionOxidative PhosphorylationMESH: Hepatocytes0302 clinical medicineMESH: Membrane Potential MitochondrialCitrate synthaseMESH: AnimalsBeta oxidationMESH : Electron Transport2. Zero hungerMembrane Potential Mitochondrial0303 health sciencesMESH : RatsAdenine nucleotide translocatorMESH: Energy MetabolismMESH: Reactive Oxygen SpeciesLipidsBiochemistryLiverMESH: Dietary FatsMitochondrial matrix030220 oncology & carcinogenesisBody CompositionMESH : Oxidative PhosphorylationATP–ADP translocaseMESH: Mitochondria LiverMESH: RatsMESH : Body CompositionMESH : MaleOxidative phosphorylationBiologyMESH : Rats WistarElectron Transport03 medical and health sciencesMESH: Oxidative Phosphorylation[SDV.BBM] Life Sciences [q-bio]/Biochemistry Molecular BiologyAnimals[SDV.BBM]Life Sciences [q-bio]/Biochemistry Molecular BiologyRats WistarMESH: Electron Transport[ SDV.BBM ] Life Sciences [q-bio]/Biochemistry Molecular Biology030304 developmental biologyHepatologyMESH: Transcription GeneticMESH : Transcription GeneticMESH : LiverMESH : LipidsMESH: Body CompositionMESH: Rats WistarMESH: LipidsDietary FatsMESH: MaleRatsMESH : Energy MetabolismMESH : Membrane Potential MitochondrialMESH : Mitochondria Liverbiology.proteinHepatocytesMESH : AnimalsEnergy MetabolismReactive Oxygen SpeciesMESH : Dietary FatsMESH: Liver
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Revisiting Plant Plasma Membrane Lipids in Tobacco: A Focus on Sphingolipids

2016

International audience; The lipid composition of plasma membrane (PM) and the corresponding detergent-insoluble membrane (DIM) fraction were analyzed with a specific focus on highly polar sphingolipids, so-called glycosyl inositol phosphorylceramides (GIPCs). Using tobacco (Nicotiana tabacum) 'Bright Yellow 2' cell suspension and leaves, evidence is provided that GIPCs represent up to 40 mol % of the PM lipids. Comparative analysis of DIMs with the PM showed an enrichment of 2-hydroxylated very-long-chain fatty acid-containing GIPCs and polyglycosylated GIPCs in the DIMs. Purified antibodies raised against these GIPCs were further used for immunogold-electron microscopy strategy, revealing …

Models Molecular0106 biological sciences0301 basic medicinePhysiology[SDV]Life Sciences [q-bio]Membrane lipidsNicotiana tabacumCell Culture TechniquesMembrane biologymacromolecular substancesPlant ScienceBiology01 natural sciencesGlycosphingolipidsCell membraneMembrane Lipids03 medical and health scienceschemistry.chemical_compoundMembrane MicrodomainsTobaccoGeneticsmedicine[SDV.BV]Life Sciences [q-bio]/Vegetal BiologyInositolGlycosylcardiovascular diseasesSphingolipidsMicroscopy ConfocalCell MembraneFatty Acidstechnology industry and agriculturePhytosterolsArticlesRaftbiology.organism_classificationSphingolipidPlant Leaves030104 developmental biologymedicine.anatomical_structureBiochemistrychemistry[SDE]Environmental Sciencescardiovascular systemlipids (amino acids peptides and proteins)010606 plant biology & botanyPlant Physiology
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Specific adduction of plant lipid transfer protein by an allene oxide generated by 9-lipoxygenase and allene oxide synthase

2006

International audience; Lipid transfer proteins (LTPs) are ubiquitous plant lipid-binding proteins that have been associated with multiple developmental and stress responses. Although LTPs typically bind fatty acids and fatty acid derivatives in a non-covalent way, studies on the LTPs of barley seeds have identified an abundantly occurring covalently modified form, LTP1b, the lipid ligand of which has resisted clarification. In the present study, this adduct was identified as the {alpha}-ketol 9-hydroxy-10-oxo-12(Z)-octadecenoic acid. Further studies on the formation of LTP1b demonstrated that the ligand was introduced by nucleophilic attack of the free carboxylate group of the Asp-7 residu…

Models Molecular0106 biological sciencesMagnetic Resonance SpectroscopyTime FactorsLIPID TRANSFER PROTEINAlleneLipoxygenaseLigands01 natural sciencesBiochemistrySubstrate SpecificityMiceLipoxygenasechemistry.chemical_compoundJasmonate2. Zero hungerchemistry.chemical_classificationALLENE OXIDE SYNTHASEMice Inbred BALB C0303 health sciencesbiologyfood and beveragesLIPID TRANSFER PROTEIN;LTP;ALLENE OXIDE SYNTHASE;PROTEINE DE TRANSFERT DE LIPIDE;REPONSE DE LA PLANTEIntramolecular OxidoreductasessynthaseBiochemistryprotéineLTPPlant lipid transfer proteinsLinoleic acidGas Chromatography-Mass Spectrometry03 medical and health sciencesprotéine végétaleréaction de défenseBiosynthesisAnimals[SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry Molecular Biology/Biochemistry [q-bio.BM]Molecular Biologymécanisme de défense030304 developmental biologyHybridomasFatty acidHordeumCell BiologyOxylipinenzymeoxylipineModels Chemicalchemistrybiology.proteinREPONSE DE LA PLANTEPROTEINE DE TRANSFERT DE LIPIDECarrier Proteins010606 plant biology & botany
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A lipid transfer protein binds to a receptor involved in the control of plant defence responses

2001

AbstractLipid transfer proteins (LTPs) and elicitins are both able to load and transfer lipidic molecules and share some structural and functional properties. While elicitins are known as elicitors of plant defence mechanisms, the biological function of LTP is still an enigma. We show that a wheat LTP1 binds with high affinity sites. Binding and in vivo competition experiments point out that these binding sites are common to LTP1 and elicitins and confirm that they are the biological receptors of elicitins. A mathematical analysis suggests that these receptors could be represented by an allosteric model corresponding to an oligomeric structure with four identical subunits.

Models Molecular0106 biological sciencesTime FactorsProtein ConformationPlasma protein bindingLigands01 natural sciencesBiochemistryProtein structureStructural BiologyReceptorAllosteryTriticumComputingMilieux_MISCELLANEOUSPlant Proteins0303 health sciencesFungal proteinfood and beveragesCell biologyBiochemistryPlant lipid transfer proteinsAllosteric SiteProtein BindingReceptorPhytophthoraLipid transfer proteinAllosteric regulationBiophysics[SDV.BC]Life Sciences [q-bio]/Cellular BiologyBiologyBinding CompetitiveFungal Proteins03 medical and health sciencesTobaccoGeneticsBinding site[SDV.BC] Life Sciences [q-bio]/Cellular BiologyMolecular Biology030304 developmental biologyBinding SitesDose-Response Relationship DrugAlgal ProteinsCell MembraneElicitinCell BiologyAntigens PlantModels TheoreticalLipid MetabolismElicitinCarrier Proteins010606 plant biology & botanyFEBS Letters
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Multiple IgE recognition on the major allergen of the Parietaria pollen Par j 2

2015

The interaction between IgE antibodies and allergens is a key event in triggering an allergic reaction. The characterization of this region provides information of paramount importance for diagnosis and therapy. Par j 2 Lipid Transfer Protein is one of the most important allergens in southern Europe and a well-established marker of sensitization in Parietaria pollen allergy. The main aim of this study was to map the IgE binding regions of this allergen and to study the pattern of reactivity of individual Parietaria-allergic patients. By means of gene fragmentation, six overlapping peptides were expressed in Escherichia coli, and their IgE binding activity was evaluated by immunoblotting in …

Models MolecularParietariaAdolescentBlotting WesternImmunoblottingMolecular Sequence DataEpitope mappingImmunologyProtein domainImmunoglobulin Emedicine.disease_causeEpitopelaw.inventionEpitopesAllergenlawmedicineHumansComputer SimulationAmino Acid SequenceCloning MolecularChildParietaria IgE Epitope mapping Molecular biology.Molecular BiologybiologyRhinitis Allergic SeasonalAllergensImmunoglobulin Ebiology.organism_classificationRecombinant ProteinsParietariaEpitope mappingImmunologybiology.proteinRecombinant DNAPollenElectrophoresis Polyacrylamide GelIgEPlant lipid transfer proteinsMolecular Immunology
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Functional competition within a membrane: Lipid recognition vs. transmembrane helix oligomerization

2015

Abstract Binding of specific lipids to large, polytopic membrane proteins is well described, and it is clear that such lipids are crucial for protein stability and activity. In contrast, binding of defined lipid species to individual transmembrane helices and regulation of transmembrane helix monomer–oligomer equilibria by binding of distinct lipids is a concept, which has emerged only lately. Lipids bind to single-span membrane proteins, both in the juxta-membrane region as well as in the hydrophobic membrane core. While some interactions counteract transmembrane helix oligomerization, in other cases lipid binding appears to enhance oligomerization. As reversible oligomerization is involve…

Models MolecularSyntaxin 1AMembrane lipidsLipid BilayersBiophysicsBiologyBinding CompetitiveBiochemistryProtein Structure SecondaryMembrane LipidsLipid bindingOligomerizationIntegral membrane proteinC99Transmembrane channelsMolecular StructureMembrane transport proteinCell MembranePeripheral membrane proteinMembrane ProteinsCell Biologyp24Transmembrane proteinProtein Structure TertiaryCell biologyTransmembrane domainMembrane proteinMembrane proteinbiology.proteinlipids (amino acids peptides and proteins)Protein BindingBiochimica et Biophysica Acta (BBA) - Biomembranes
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Formation of irreversibly bound annexin A1 protein domains on POPC/POPS solid supported membranes

2008

AbstractThe specific interaction of annexin A1 with phospholipid bilayers is scrutinized by means of scanning force and fluorescence microscopy, quartz crystal microbalance, ellipsometry, and modeled by dynamic Monte Carlo simulations. It was found that POPC/POPS bilayers exhibit phase separation in POPC- and POPS-enriched domains as a function of Ca2+ concentration. Annexin A1 interacts with POPC/POPS bilayers by forming irreversibly bound protein domains with monolayer thickness on POPS-enriched nanodomains, while the attachment of proteins to the POPC-enriched regions is fully reversible. A thorough kinetic analysis of the process reveals that both, the binding constant of annexin A1 at …

Models Moleculargenetic structuresLipid BilayersBiophysicsPhospholipidAnalytical chemistryPhosphatidylserines02 engineering and technologyMicroscopy Atomic ForceBiochemistryBiophysical PhenomenaMembrane Lipids03 medical and health scienceschemistry.chemical_compoundProtein structureSFMMonolayerMicropatterned membranesAnimalsHumansPOPCMonte Carlo simulationAnnexin A1030304 developmental biologyFluorescence microscopy0303 health sciencesEllipsometrytechnology industry and agricultureCell BiologyQuartz crystal microbalanceSurface Plasmon Resonance021001 nanoscience & nanotechnologyBinding constantProtein Structure TertiaryMembraneMicroscopy FluorescencechemistryQCMPhosphatidylcholinesBiophysicsCalciumlipids (amino acids peptides and proteins)Adsorption0210 nano-technologyMonte Carlo MethodProtein BindingAnnexin A1Biochimica et Biophysica Acta (BBA) - Biomembranes
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