0000000000384449

AUTHOR

Alexander Bender

showing 4 related works from this author

Localization of the N-terminal Domain in Light-harvesting Chlorophyll a/b Protein by EPR Measurements

2005

The conformational distribution of the N-terminal domain of the major light-harvesting chlorophyll a/b protein (LHCIIb) has been characterized by electron-electron double resonance yielding distances between spin labels placed in various domains of the protein. Distance distributions involving residue 3 near the N terminus turned out to be bimodal, revealing that this domain, which is involved in regulatory functions such as balancing the energy flow through photosystems (PS) I and II, exists in at least two conformational states. Models of the conformational sub-ensembles were generated on the basis of experimental distance restraints from measurements on LHCIIb monomers and then checked f…

ChlorophyllModels MolecularThreonineConformational changeTime FactorsLightMacromolecular SubstancesProtein ConformationPhotosynthetic Reaction Center Complex ProteinsLight-Harvesting Protein ComplexesElectronsTrimerCrystallography X-RayThylakoidsBiochemistryProtein Structure Secondarylaw.inventionResidue (chemistry)chemistry.chemical_compoundlawEscherichia coliAnimalsPhosphorylationAnnexin A4Electron paramagnetic resonanceMolecular BiologyPhotosystemPhotosystem I Protein ComplexChemistryChlorophyll AElectron Spin Resonance SpectroscopyPeasPhotosystem II Protein ComplexCell BiologyRecombinant ProteinsProtein Structure TertiaryOxygenN-terminusCrystallographyMonomerThylakoidMutationCattleSpin LabelsDimerizationJournal of Biological Chemistry
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Carotenoid binding sites in LHCIIb

2000

The major light-harvesting complex of photosystem II can be reconstituted in vitro from its bacterially expressed apoprotein with chlorophylls a and b and neoxanthin, violaxanthin, lutein, or zeaxanthin as the only xanthophyll. Reconstitution of these one-carotenoid complexes requires low-stringency conditions during complex formation and isolation. Neoxanthin complexes (containing 30–50% of the all-trans isomer) disintegrate during electrophoresis, exhibit a largely reduced resistance against proteolytic attack; in addition, energy transfer from Chl b to Chl a is easily disrupted at elevated temperature. Complexes reconstituted in the presence of either zeaxanthin or lutein contain nearly …

ChlorophyllLuteinPhotosynthetic Reaction Center Complex ProteinsPigment bindingLight-Harvesting Protein ComplexesXanthophyllsBiologyBinding CompetitiveBiochemistrySubstrate SpecificityLight-harvesting complexchemistry.chemical_compoundNeoxanthinZeaxanthinsTrypsinProtein PrecursorsCarotenoidPlant Proteinschemistry.chemical_classificationBinding SitesChlorophyll ALuteinPhotosystem II Protein Complexfood and beveragesPigments BiologicalPlantsbeta CaroteneCarotenoidseye diseasesZeaxanthinEnergy TransferchemistryBiochemistryXanthophyllElectrophoresis Polyacrylamide GelApoproteinsViolaxanthinEuropean Journal of Biochemistry
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Data analysis procedures for pulse ELDOR measurements of broad distance distributions

2004

The reliability of procedures for extracting the distance distribution between spins from the dipolar evolution function is studied with particular emphasis on broad distributions. A new numerically stable procedure for fitting distance distributions with polynomial interpolation between sampling points is introduced and compared to Tikhonov regularization in the dipolar frequency and distance domains and to approximate Pake transformation. Distance distributions with only narrow peaks are most reliably extracted by distance-domain Tikhonov regularization, while frequency-domain Tikhonov regularization is favorable for distributions with only broad peaks. For the quantification of distribut…

PhysicsTikhonov regularizationTransformation (function)Distribution (mathematics)Hermite polynomialsSpinsStatistical physicsFunction (mathematics)Atomic and Molecular Physics and OpticsPolynomial interpolationInterpolation
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Sensitivity enhancement in pulse EPR distance measurements

2004

Established pulse EPR approaches to the measurement of small dipole-dipole couplings between electron spins rely on constant-time echo experiments to separate relaxational contributions from dipolar time evolution. This requires a compromise between sensitivity and resolution to be made prior to the measurement, so that optimum data are only obtained if the magnitude of the dipole-dipole coupling is known beforehand to a good approximation. Moreover, the whole dipolar evolution function is measured with relatively low sensitivity. These problems are overcome by a variable-time experiment that achieves suppression of the relaxation contribution by reference deconvolution. Theoretical and exp…

Nuclear and High Energy PhysicsProtein ConformationBiophysicsAnalytical chemistryBiochemistrySensitivity and Specificitylaw.inventionlawspin labelingSensitivity (control systems)protein structurepair correlation functionElectron paramagnetic resonanceCouplingSpinsChemistryPulsed EPRRelaxation (NMR)Time evolutionElectron Spin Resonance SpectroscopyPhotosystem II Protein ComplexReproducibility of ResultsSignal Processing Computer-AssistedELDORCondensed Matter PhysicsComputational physicsDeconvolutionEPRAlgorithms
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