Search results for "Thermoplasma"

showing 6 items of 6 documents

Influence of the Main Phospholipid (MPL) fromThermoplasma Acidophilumand of Liposomes from MPL on Living Cells: Cytotoxicity and Mutagenicity

1993

AbstractLiposomes of the main phospholipid (MPL) from the archaebacterium Thermplasma acidophilum were investigated for their interference with living cells. Growth of mouse lymphoma cells L5178Y, permanent hamster fibroblasts V79, Ehrlich-mouse-ascites tumor (EMAT) cells and a variety of other celltypes was not influenced by these liposomes. Mutagenicity and antimutagenic efficacy were tested with Salmonella typhimurium TA100 in the “Ames plate-incorporation test”. No cytotoxicity and mutagenicity of liposomes from MPL was detected. The influence of MPL liposomes on ion transport, intracellular pH, electrolytes, membrane potential, energy metabolism, and the biosynthesis of proteins and nu…

LiposomebiologyIntracellular pHPhospholipidPharmaceutical ScienceThermoplasma acidophilumHamsterbiology.organism_classificationMolecular biologychemistry.chemical_compoundchemistryBiosynthesisBiochemistryNucleic acidCytotoxicityJournal of Liposome Research
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Letter to the Editor: Solution structure of hypothetical protein TA1414 from Thermoplasma acidophilum

2004

biologyChemistryHypothetical proteinStructural proteomicsThermoplasma acidophilumComputational biologybiology.organism_classificationBiochemistrySolution structureSpectroscopyStructural genomicsJournal of Biomolecular NMR
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Community composition and seasonal changes of archaea in coarse and fine air particulate matter

2018

Archaea are ubiquitous in terrestrial and marine environments and play an important role in biogeochemical cycles. Although air acts as the primary medium for their dispersal among different habitats, their diversity and abundance is not well characterized. The main reason for this lack of insight is that archaea are difficult to culture, seem to be low in number in the atmosphere, and have so far been difficult to detect even with molecular genetic approaches. However, to better understand the transport, residence time, and living conditions of microorganisms in the atmosphere as well as their effects on the atmosphere and vice versa, it is essential to study all groups of bioaerosols. Her…

0301 basic medicinebiologyEcology030106 microbiologylcsh:QE1-996.5Cenarchaealeslcsh:LifeThermoplasmataParticulatesbiology.organism_classificationlcsh:Geology03 medical and health scienceslcsh:QH501-531030104 developmental biologyAbundance (ecology)Crenarchaeotalcsh:QH540-549.5Environmental sciencelcsh:EcologyEuryarchaeotaPhyllosphereEcology Evolution Behavior and SystematicsEarth-Surface ProcessesArchaea
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NMR structure of hypothetical protein TA0938 from Thermoplasma acidophilum.

2007

Models MolecularbiologySequence Homology Amino AcidChemistryThermoplasmaArchaeal ProteinsArchaeal ProteinsHypothetical proteinThermoplasmaMolecular Sequence DataThermoplasma acidophilumSequence alignmentComputational biologybiology.organism_classificationBiochemistryStructural genomicsProtein Structure TertiaryStructural BiologyAmino Acid SequenceMolecular BiologyPeptide sequenceNuclear Magnetic Resonance BiomolecularSequence AlignmentProteins
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Primary Structure of Selected Archaeal Mesophilic and Extremely Thermophilic Outer Surface Layer Proteins

2002

The archaea are recognized as a separate third domain of life together with the bacteria and eucarya. The archaea include the methanogens, extreme halophiles, thermoplasmas, Sulfate reducers and Sulfur metabolizing thermophiles, which thrive in different habitats such as anaerobic niches, salt lakes, and marine hydrothermals systems and continental solfataras. Many of these habitats represent extreme environments in respect to temperature, osmotic pressure and pH-values and remind on the conditions of the early earth. The cell envelope structures were one of the first biochemical characteristics of archaea studied in detail. The most common archaeal cell envelope is composed of a single cry…

Hot TemperaturebiologyArchaeal ProteinsThermophileThermoplasmaMembrane ProteinsProtein Sorting Signalsbiology.organism_classificationArchaeaApplied Microbiology and BiotechnologyMicrobiologyProtein Structure SecondaryHalophileBiochemistryExtreme environmentAmino Acid SequenceAmino AcidsCell envelopeProtein stabilizationSequence AlignmentS-layerEcosystemEcology Evolution Behavior and SystematicsArchaeaSystematic and Applied Microbiology
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Reconstitution of bacteriorhodopsin and ATP synthase from Micrococcus luteus into liposomes of the purified main tetraether lipid from Thermoplasma a…

1995

The archaebacterium Thermoplasma acidophilum is cultivated at 59 degrees C in a medium containing sulfuric acid of pH 2. The purified bipolar membrane spanning main phospholipid (MPL) of this organism can be used to produce stable liposomes of 100-500 nm in diameter either using a French pressure cell detergent dialysis or sonication. Despite a potassium diffusion potential of 186 mV very low ionic permeability of sonicated MPL liposomes was measured using the potassium binding fluorescent indicator benzofuran isophthalate PBF1, which measures net K+ uptake. The latter also remained very low, in the presence of the K(+) ionophore valinomycin and palmitic acid. Addition of valinomycin and th…

Carbonyl Cyanide p-TrifluoromethoxyphenylhydrazoneLightOctoxynolThermoplasmaBiochemistryPermeabilityPyranineValinomycinchemistry.chemical_compoundAdenosine TriphosphateProton transportParticle SizeMolecular BiologyPhospholipidsLiposomeChromatographyValinomycinbiologyIonophoresVesicleOrganic ChemistryFatty AcidsTemperatureThermoplasma acidophilumMembrane ProteinsPhospholipid EthersBacteriorhodopsinCell BiologyHydrogen-Ion Concentrationbiology.organism_classificationMicrococcus luteusProton-Translocating ATPaseschemistryBacteriorhodopsinsLiposomesbiology.proteinGramicidinPotassiumProtonsChemistry and physics of lipids
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