Search results for "Spheroplast"

showing 10 items of 10 documents

Biological response of multicellular emt6 spheroids to exogenous lactate

1991

The influence of elevated lactate concentrations, as found in tumor microregions, on cellular growth, viability, and metabolic state was studied employing the multicellular spheroid model. Spheroids of EMT6/Ro cells were cultured at 37 degrees C in 5% or 20% (v/v) oxygen, using stirred media with various concentrations of exogenous lactate ranging from 0.0 mM (standard conditions) to 20.0 mM. Elevated concentrations of exogenous lactate led to a considerable decrease of the maximum spheroid diameter at growth saturation, e.g., for 20% O2 from around 1700 microns to 700 microns in 0.0 and 20.0 mM lactate respectively. Histological investigations showed that the thickness of the viable cell r…

Cancer ResearchCell Survivalchemistry.chemical_elementMammary Neoplasms AnimalSpheroplastsIn Vitro TechniquesBiologyOxygenColony-Forming Units AssayMiceOxygen ConsumptionRespirationAnimalsLactic AcidDose-Response Relationship DrugCell growthSpheroidOxygen tensionGlucoseOncologychemistryBiochemistryCell cultureLactatesBiophysicsFemaleLimiting oxygen concentrationSaturation (chemistry)Cell DivisionInternational Journal of Cancer
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d-Alanyl-d-Alanine Carboxypeptidase in the Bacterial Form and L-Form of Proteus mirabilis

1975

Membranes of the bacterial form and the stable and unstable L-forms of Proteus mirabilis contain LD and DD-carboxypeptidase. The DD-carboxypeptidase is inhibited non-competitively by penicillin G. The enzyme of the bacterial form is highly penicillin-sensitive (Ki - 4 X 10(-9) M penicillin G). Inhibition is only partly reversible by treatment with penicillinase or by dialysis against buffer. In contrast, the DD-carboxypeptidase of the unstable L-form, grown in the presence of penicillin, is 175-fold less penicillin-sensitive (Ki = 7 X 10(7) M penicillin G). Inhibition is completely reversed by penicillinase or dialysis. After inhibition by penicillin and subsequent reactivation the penicill…

D-Amino-Acid OxidaseDetergentsPenicillin sensitivityL FormsCarboxypeptidasesSpheroplastsBiochemistryDD PeptidaseCell wallpolycyclic compoundsmedicineProteus mirabilischemistry.chemical_classificationAlaninebiologyProtoplastsCell MembranePenicillin GHydrogen-Ion Concentrationbiology.organism_classificationProteus mirabilisPenicillinKineticsMembraneEnzymechemistryBiochemistryPenicillin VPenicillin bindingmedicine.drugEuropean Journal of Biochemistry
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A rapid and simple method for the preparation of yeast mitochondrial DNA

1990

Gel electrophoresisMitochondrial DNAbiologySaccharomyces cerevisiaeSaccharomyces cerevisiaeSpheroplastsMitochondrionSpheroplastbiology.organism_classificationDNA MitochondrialMolecular biologyYeastMitochondriachemistry.chemical_compoundBiochemistrychemistryCentrifugation Density GradientGeneticsCentrifugationDNA FungalDNA
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Yeast dsRNA viruses: replication and killer phenotypes

1991

The cytoplasmic L-A dsRNA virus of Saccharomyces cerevisiae consists of a 4.5 kb dsRNA and the two gene products it encodes; the capsid (cap) and at least one copy of the capsid-polymerase (cap-pol) fusion protein. Virion cap-pol catalyses transcription of the plus (sense)-strand; this is extruded from the virus and serves as messenger for synthesis of cap and cap-pol. Nascent cap-pol binds to a specific domain in the plus strand to initiate encapsidation and then catalyses minus-strand synthesis to complete the replication cycle. Products of at least three host genes are required for replication, and virus copy number is kept at tolerable levels by the SKI antivirus system. S. cerevisiae k…

Genes ViralbiologyDNA synthesisvirusesSaccharomyces cerevisiaeRNA virusSaccharomyces cerevisiaeSpheroplastsVirus Replicationbiology.organism_classificationModels BiologicalMicrobiologyVirologyVirusPhenotypeDNA Topoisomerases Type ICapsidViral replicationTranscription (biology)VirusesRNA ViralMolecular BiologyGeneRNA Double-StrandedVirus Physiological PhenomenaMolecular Microbiology
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Relationship between ethanol tolerance, lipid composition and plasma membrane fluidity inSaccharomyces cerevisiaeandKloeckera apiculata

1994

The lipid composition of a strain of each of two yeasts, Saccharomyces csrevisiae and Kloeckera apiculata, with different ethanol tolerances, was determined for cells grown with or without added ethanol. An increase in the proportion of ergosterol, unsaturated fatty acid levels and the maintenance of phospholipid biosynthesis seemed to be responsible for ethanol tolerance. The association of ethanol tolerance of yeast cells with plasma membrane fluidity, measured by fluorescence anisotropy, is discussed. We propose that an increase in plasma membrane fluidity may be correlated with a decrease in the sterol: phospholipid and sterol: protein ratios and an increase in unsaturation index.

Membrane FluidityPhospholipidFluorescence PolarizationSaccharomyces cerevisiaeSpheroplastsMicrobiologySaccharomyceschemistry.chemical_compoundBacterial ProteinsGeneticsMembrane fluidityMolecular BiologyPhospholipidsUnsaturated fatty acidErgosterolEthanolEthanolbiologyDrug Tolerancebiology.organism_classificationLipidsYeastSterolSterolsBiochemistrychemistrylipids (amino acids peptides and proteins)Mitosporic FungiFEMS Microbiology Letters
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Development of a modified DNA extraction method for pulsed-field gel electrophoresis analysis of Staphylococcus aureus and enterococci without using …

2010

A modified pulsed-field gel electrophoresis (PFGE) protocol was developed and applied to clinical isolates of Staphylococcus aureus and enterococci to reduce the cost of using lysostaphin. This protocol reduces the expenses of PFGE typing of S. aureus and enterococci as it removes the use of lysostaphin during the spheroplast formation from these bacteria.

Microbiology (medical)DNA BacterialStaphylococcus aureusSettore MED/07 - Microbiologia E Microbiologia ClinicaMicrococcaceaemedicine.disease_causeMicrobiologyMicrobiologyPulsed-field gel electrophoresismedicineHumansMolecular BiologyGel electrophoresisBacteriological TechniquesbiologyLysostaphinbiochemical phenomena metabolism and nutritionSpheroplastStreptococcaceaebiology.organism_classificationBacterial Typing TechniquesElectrophoresis Gel Pulsed-FieldEnterococcusStaphylococcus aureusLysostaphinEnterococcusPulse-field gel electrophoresis(PFGE) MRSA VRE Nosocomial infections
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Killer-toxin-resistant kre12 mutants of Saccharomyces cerevisiae: genetic and biochemical evidence for a secondary K1 membrane receptor.

1995

The Saccharomyces cerevisiae killer toxin K1 is a secreted alpha/beta-heterodimeric protein toxin that kills sensitive yeast cells in a receptor-mediated two-stage process. The first step involves toxin binding to beta-1,6-D-glucan-components of the outer yeast cell surface; this step is blocked in yeast mutants bearing nuclear mutations in any of the KRE genes whose products are involved in synthesis and/or assembly of cell wall beta-D-glucans. After binding to the yeast cell wall, the killer toxin is transferred to the cytoplasmic membrane, subsequently leading to cell death by forming lethal ion channels. In an attempt to identify a secondary K1 toxin receptor at the plasma membrane leve…

MutantSaccharomyces cerevisiaeGenes FungalReceptors Cell SurfaceSaccharomyces cerevisiaeSpheroplastsBiologymedicine.disease_causeBiochemistryMicrobiologyModels BiologicalIon ChannelsFungal ProteinsCell surface receptorCell WallGeneticsmedicineMolecular BiologyDiphtheria toxinToxinMembrane ProteinsDrug Resistance MicrobialGeneral MedicineSpheroplastMycotoxinsbiology.organism_classificationYeastKiller Factors YeastBiochemistryMembrane proteinMutationArchives of microbiology
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Molecular structure of the cell wall receptor for killer toxin KT28 in Saccharomyces cerevisiae

1988

The adsorption of the yeast killer toxin KT28 to susceptible cells of Saccharomyces cerevisiae was prevented by concanavalin A, which blocks the mannoprotein receptor. Certain mannoprotein mutants of S. cerevisiae that lack definite structures in the mannan of their cell walls were found to be resistant to KT28, whereas the wild-type yeast from which the mutants were derived was susceptible. Isolated mannoprotein from a resistant mutant was unable to adsorb killer toxin. By comparing the resistances of different mannoprotein mutants, information about the molecular structure of the receptor was obtained. At least two mannose residues have to be present in the side chains of the outer chain …

Saccharomyces cerevisiae ProteinsMutantSaccharomyces cerevisiaeMannoseReceptors Cell Surfacechemical and pharmacologic phenomenaSaccharomyces cerevisiaeSpheroplastsMicrobiologyFungal Proteinschemistry.chemical_compoundCell WallConcanavalin AReceptorMolecular BiologyGlycoproteinsMannanMembrane GlycoproteinsbiologyMycotoxinsSpheroplastbiology.organism_classificationKiller Factors YeastYeastcarbohydrates (lipids)BiochemistrychemistryConcanavalin AMutationbiology.proteinAdsorptionResearch ArticleJournal of Bacteriology
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Killer toxin producing strains of the yeasts Hanseniaspora uvarum and Pichia kluyveri

1988

By heat treatment killer strains of the type K1 of Saccharomyces cerevisiae that are known to harbour dsRNA plasmids were completely cured, whereas only a small fraction of the clones of the killer type K2 had lost the dsRNA dependent killer character. The K2 killers but not the strains of killer type K1 were easily cured by cycloheximide. Killer strains of Hanseniaspora uvarum were not curable by heat treatment. Curing was successfull with cycloheximide or 5-fluorouracil. Two double-stranded RNA plasmids were detected in the killer strains of H. uvarum. The smaller dsRNA plasmid was absent in the strains that were cured of their killer character by 5-fluorouracil. The killer character of H…

ToxinfungiSaccharomyces cerevisiaeRNAchemical and pharmacologic phenomenaGeneral MedicineCycloheximideSpheroplastBiologybiology.organism_classificationmedicine.disease_causeBiochemistryMicrobiologyMicrobiologychemistry.chemical_compoundRNA silencingPlasmidchemistryGeneticsmedicineMolecular BiologyGeneArchives of Microbiology
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Chromatin structure of transposon Tn903 cloned into a yeast plasmid

1989

Transposon Tn903 contains the APH gene for kanamycin resistance, which is active in yeast [A. Jiménez and J. Davies (1980) Nature (London) 287, 869-871] and is flanked by two inverted repeats (IR) 1057 bp long. When plasmid pAJ50, carrying Tn903 and the 2-microns circle origin of replication, is cloned into Saccharomyces cerevisiae, nucleosomes are assembled in vivo on the prokaryotic DNA of the transposon. Indirect end labeling revealed that three nucleosomes are preferentially positioned on symmetrical sequences from both IRs. DNase I digestion also confirmed that the chromatin structure is symmetrical in both IRs. This suggests that sequence determinants are decisive for chromatin struct…

Transposable elementGeneticsInverted repeatGenes FungalRestriction MappingSaccharomyces cerevisiaeSpheroplastsBiologyOrigin of replicationChromatinNucleosomesChromatinchemistry.chemical_compoundTransformation GeneticPlasmidchemistryDNA Transposable ElementsDeoxyribonuclease INucleosomeCloning MolecularDNA FungalDeoxyribonuclease IMolecular BiologyDNAPlasmidsPlasmid
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