Search results for "MESH : Membrane Fluidity"

showing 3 items of 3 documents

Mechanisms underlying the toxicity of lactone aroma compounds towards the producing yeast cells

2003

M. A G U E D O , L. B E N E Y , Y. W A C H EA N D J. - M. B E L I N. 2003. Aims: To study the fundamental mechanisms of toxicity of the fruity aroma compound c-decalactone, that lead to alterations in cell viability during its biotechnological production by yeast cells; Yarrowia lipolytica that is able to produce high amounts of this metabolite was used here as a model. Methods and Results: Lactone concentrations above 150 mg l )1 inhibited cell growth, depolarized the living cells and increased membrane fluidity. Infrared spectroscopic measurements revealed that the introduction of the lactone into model phospholipid bilayers, decreased the phase transition temperature. Moreover, the H + -…

MESH : YarrowiaMembrane FluidityMESH : Cell MembraneIntracellular pHMESH : Membrane FluidityYarrowiaFluorescence PolarizationApplied Microbiology and BiotechnologyMESH : PhospholipidsMembrane PotentialsCell membraneMESH : Spectroscopy Fourier Transform InfraredLactonesMESH : Hydrogen-Ion ConcentrationSpectroscopy Fourier Transform InfraredmedicineMembrane fluidityMESH : Membrane PotentialsViability assay[SDV.BC] Life Sciences [q-bio]/Cellular BiologySpectroscopyPhospholipidsAdenosine TriphosphatasesMESH : Adenosine Triphosphatasesbiology[ SDV.BC ] Life Sciences [q-bio]/Cellular BiologyCell growthCell MembraneYarrowiaGeneral MedicineHydrogen-Ion Concentrationbiology.organism_classificationBioproductionYeastMESH : Lactones[INFO.INFO-BT] Computer Science [cs]/Biotechnologymedicine.anatomical_structureBiochemistryFourier Transform InfraredMESH : Fluorescence Polarization[ INFO.INFO-BT ] Computer Science [cs]/BiotechnologyBiotechnologyJournal of Applied Microbiology
researchProduct

Fluorescent probes to evaluate the physiological state and activity of microbial biocatalysts: A guide for prokaryotic and eukaryotic investigation

2008

International audience; Many fluorescent techniques are employed to evaluate the viability and activity of microbial cells used in biotechnology. These techniques are sometimes complex and the interpretation of results opened to misunderstanding. Moreover, new developments are constantly proposed especially concerning a more accurate evaluation of the state of the cells including eukaryotic microorganisms. This paper aims at presenting to biotechnologists unfamiliar with fluorescence the principles of these methods and the related possible pitfalls. It focuses on probes of the physical (integrity and fluidity) and energetical (intracellular pH and membrane potential) state of the cell membr…

Cell Membrane PermeabilityMembrane FluidityMESH : Microscopy FluorescenceMESH : Cell MembraneIntracellular pHMESH : Membrane FluidityBiologyApplied Microbiology and BiotechnologyMembrane PotentialsCell membraneIndustrial MicrobiologyMESH : Hydrogen-Ion ConcentrationYeastsGram-Negative BacteriamedicineMESH : Membrane PotentialsMESH : Fluorescent DyesFluorescent DyesMESH : YeastsMESH : Spectrometry FluorescenceCell Membrane[ SDV.BIO ] Life Sciences [q-bio]/BiotechnologyGeneral MedicineHydrogen-Ion ConcentrationMESH : Gram-Negative BacteriaMESH : Industrial MicrobiologyFluorescenceYeastSpectrometry Fluorescencemedicine.anatomical_structureMicroscopy FluorescenceBiochemistryMESH : Cell Membrane PermeabilityNucleic acidMolecular MedicineBiotechnology Journal
researchProduct

Effects of oxidoreduction potential combined with acetic acid, NaCl and temperature on the growth, acidification, and membrane properties of Lactobac…

2002

International audience; The effects of oxidoreduction potential (Eh) combined with acetic acid, NaCl and temperature on the growth, acidification, and membrane properties of Lactobacillus plantarum were studied. The culture medium was set at pH 5, and two different Eh values were adjusted using nitrogen (Eh = +350 mV) or hydrogen (Eh = -300 mV) gas. In reducing condition, the growth was slowed and the acidification delayed at 37 degrees C, but not at 10 degrees C. A synergistic inhibitory effect of reducing Eh, acetic acid and NaCl was observed, mainly for delaying the lag phase before acidification. These results may be explained by changes in ATPase activity, membrane fluidity and surface…

MESH: Oxidation-ReductionMESH : Acetic AcidMESH: Sodium ChlorideHydrogenMembrane FluiditySodiumInorganic chemistrychemistry.chemical_elementMESH : Membrane Fluidity[SDV.BC]Life Sciences [q-bio]/Cellular BiologySodium ChlorideMicrobiologyAcetic acidchemistry.chemical_compoundLactobacillusGeneticsMembrane fluidity[INFO.INFO-BT]Computer Science [cs]/BiotechnologyMolecular BiologyMESH : Temperature[SDV.BC] Life Sciences [q-bio]/Cellular BiologyAcetic AcidMESH : Oxidation-Reductionbiology[ SDV.BC ] Life Sciences [q-bio]/Cellular BiologyTemperaturebiology.organism_classificationNitrogenMESH: TemperatureCulture MediaMESH : Sodium ChlorideLactobacillusMembrane[INFO.INFO-BT] Computer Science [cs]/BiotechnologychemistryMESH: Acetic AcidMESH: Culture MediaMESH : Culture MediaMESH : LactobacillusOxidation-ReductionMESH: LactobacillusLactobacillus plantarum[ INFO.INFO-BT ] Computer Science [cs]/BiotechnologyMESH: Membrane FluidityNuclear chemistry
researchProduct