Search results for "Reducing Agents"

showing 5 items of 5 documents

Determination of kinetic parameters of redox reactions using CE‐ICP‐MS: A case study for the reduction of Np(V) by hydroxylamine hydrochloride

2018

The rate constants k of the reduction of 5 × 10-5  M Np(V) to Np(IV) by hydroxylamine hydrochloride (HAHCl) in 1 M HCl have been determined by CE-ICP-MS in the temperature range of ϑ = 30-70°C and with varying concentrations of HAHCl from 1 to 7.2 M. The reaction was found to have (pseudo)first order kinetics with respect to HAHCl. The experimental results for k ranged from 0.0029(1) min-1 (ϑ = 40°C, c(HAHCl) = 3 M) to 0.039(7) min-1 (ϑ = 60°C, c(HAHCl) = 7.2 M). The activation energy of the reaction was determined as EA  = (72 ± 10) kJ/mol. These results and a comparison with literature data show that the coupling of CE to ICP-MS provides a powerful analytical tool for the investigation of…

Clinical BiochemistryInorganic chemistrychemistry.chemical_elementHydroxylamine02 engineering and technologyActivation energy01 natural sciencesBiochemistryRedoxMass SpectrometryAnalytical ChemistryNeptuniumReaction rate constantTransition metalChemistryNeptunium010401 analytical chemistryTemperatureElectrophoresis CapillaryActinideRate equationAtmospheric temperature range021001 nanoscience & nanotechnology0104 chemical sciencesKineticsReducing Agents0210 nano-technologyOxidation-ReductionELECTROPHORESIS
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Identification of Two Mannoproteins Released from Cell Walls of a Saccharomyces cerevisiae mnn1 mnn9 Double Mutant by Reducing Agents

1999

The cell wall of Saccharomyces cerevisiae represents some 30% of the total weight of the cell and is made up of β-glucans, mannose-containing glycoproteins (mannoproteins), and small amounts of chitin (9, 15). The mannoproteins can be divided into three groups according to the linkages that bind them to the structure of the cell wall: (i) noncovalently bound, (ii) covalently bound to the structural glucan, and (iii) disulfide bound to other proteins that are themselves covalently bound to the structural glucan of the cell wall (8). Our work has focused on the disulfide-bound mannoproteins, probably the least well known of the three groups mentioned above. Previous work (25) showed that trea…

GlycosylationSaccharomyces cerevisiae ProteinsGlycosylationBlotting WesternMolecular Sequence DataSaccharomyces cerevisiaeSaccharomyces cerevisiaeMicrobiologyGene Expression Regulation EnzymologicFungal ProteinsCell wallOpen Reading FramesSurface-Active Agentschemistry.chemical_compoundCell WallGene Expression Regulation FungalEndopeptidasesAspartic Acid EndopeptidasesAmino Acid SequenceSubtilisinsFluorescent Antibody Technique IndirectMolecular BiologyMercaptoethanolGlucanGel electrophoresischemistry.chemical_classificationFungal proteinMembrane GlycoproteinsbiologySodium Dodecyl SulfateBiological Transportbiology.organism_classificationRecombinant ProteinsYeastMolecular Weightcarbohydrates (lipids)Cytoskeletal ProteinsEukaryotic CellsPhenotypechemistryBiochemistryMutagenesisReducing AgentsElectrophoresis Polyacrylamide GelProprotein ConvertasesProtein Tyrosine PhosphatasesGlycoproteinGene DeletionJournal of Bacteriology
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Effect of reducing agents on the acidification capacity and the proton motive force of Lactococcus lactis ssp. cremoris resting cells.

2002

International audience; Reducing agents are potential inhibitors of the microbial growth. We have shown recently that dithiothreitol (DTT), NaBH(4) and H(2) can modify the proton motive force of resting cells of Escherichia coli by increasing the membrane protons permeability [Eur. J. Biochem. 262 (1999) 595]. In the present work, the effect of reducing agents on the resting cells of Lactococcus lactis ssp. cremoris, a species widely employed in dairy processes was investigated. DTT did not affect the acidification nor the DeltapH, in contrast to the effect previously reported on E. coli. The DeltaPsi was slightly increased (30 mV) at low pH (pH 4) in the presence of 31 mM DTT or 2.6 mM NaB…

MESH : Cell LineMESH: Hydrogen-Ion ConcentrationMESH : DithioniteBorohydridesMESH : DithiothreitolBacterial growthmedicine.disease_causeMESH: Proton-Motive ForceDithiothreitolSodium dithionitechemistry.chemical_compoundMESH : Proton-Motive ForceElectrochemistry[INFO.INFO-BT]Computer Science [cs]/Biotechnology0303 health sciencesMESH : Interphasebiologyfood and beveragesProton-Motive ForceGeneral MedicineHydrogen-Ion ConcentrationMESH: BorohydridesLactococcus lactisMembraneBiochemistryReducing AgentsMESH : Sensitivity and SpecificityMESH : Reducing Agents[ INFO.INFO-BT ] Computer Science [cs]/BiotechnologyReducing agentMESH: Reducing AgentsBiophysics[SDV.BC]Life Sciences [q-bio]/Cellular BiologySensitivity and SpecificityCell LineMESH: Interphase03 medical and health sciencesSpecies SpecificityMESH : Hydrogen-Ion ConcentrationMESH: DithionitemedicineMESH : Species SpecificityMESH: Species SpecificityLactic AcidPhysical and Theoretical ChemistryEscherichia coli[SDV.BC] Life Sciences [q-bio]/Cellular BiologyInterphase030304 developmental biology[ SDV.BC ] Life Sciences [q-bio]/Cellular Biology030306 microbiologyChemiosmosisLactococcus lactisDithionitebiology.organism_classificationMESH: Sensitivity and SpecificityMESH: Cell LineDithiothreitol[INFO.INFO-BT] Computer Science [cs]/BiotechnologychemistryMESH: Lactococcus lactisMESH : BorohydridesMESH : Lactic AcidBiophysicsMESH: Lactic AcidMESH : Lactococcus lactisMESH: Dithiothreitol
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Application of 3-Quinolinoyl Picket Porphyrins to the Electroreduction of Dioxygen to Water: Mimicking the Active Site of Cytochromec Oxidase

2001

International audience

PorphyrinsHemeproteinReducing agentIronchemistry.chemical_elementPhotochemistryElectrochemistry[ CHIM ] Chemical SciencesBiochemistryOxygenElectron Transport Complex IVO-O activationcytochrome c oxidase[CHIM]Chemical SciencesCytochrome c oxidaseBinding siteMolecular BiologyComputingMilieux_MISCELLANEOUSBinding SitesbiologyChemistryMolecular MimicryOrganic ChemistryActive siteElectron Transport Complex IVheme proteinsoxidoreductasesOxygenelectrochemistryReducing Agentsbiology.proteinMolecular MedicineIndicators and ReagentsSpectrophotometry UltravioletOxidation-ReductionCopperChemBioChem
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Bioprospective of Sorbus aucuparia leaf extract in development of silver and gold nanocolloids

2010

At the present time the bioprospective field is a dynamic area of research. The rapid biosynthesis of silver and gold nanoparticles without using toxic chemicals is reported here. Sorbus aucuparia is omnipresent in Europe. The aqueous leaves extract of the plant were used as reducing agent for the synthesis of silver and gold nanoparticles from their salt solutions. The synthesized nanoparticles were spherical, triangular and hexagonal in shape with an average size of 16 and 18nm for silver and gold, respectively. Different extract quantities, metal concentrations, temperatures and contact times were investigated to find their effect on nanoparticles synthesis. The resulting silver and gold…

SilverMaterials scienceMetal ions in aqueous solutionAnalytical chemistryMetal NanoparticlesNanoparticleSilver nanoparticleMetalAbsorbanceColloid and Surface ChemistryMicroscopy Electron TransmissionX-Ray DiffractionSpectroscopy Fourier Transform InfraredSorbusParticle SizePhysical and Theoretical ChemistryFourier transform infrared spectroscopyPlant ExtractsTemperatureSurfaces and InterfacesGeneral MedicineHydrogen-Ion ConcentrationPlant LeavesReducing AgentsColloidal goldvisual_artvisual_art.visual_art_mediumGoldInductively coupled plasmaCrystallizationOxidation-ReductionBiotechnologyColloids and Surfaces B: Biointerfaces
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