Search results for "Protein Complex"

showing 10 items of 154 documents

Derivation of coarse-grained simulation models of chlorophyll molecules in lipid bilayers for applications in light harvesting systems

2015

The correct interplay of interactions between protein, pigment and lipid molecules is highly relevant for our understanding of the association behavior of the light harvesting complex (LHCII) of green plants. To cover the relevant time and length scales in this multicomponent system, a multi-scale simulation ansatz is employed that subsequently uses a classical all atomistic (AA) model to derive a suitable coarse grained (CG) model which can be backmapped into the AA resolution, aiming for a seamless conversion between two scales. Such an approach requires a faithful description of not only the protein and lipid components, but also the interaction functions for the indispensable pigment mo…

ChlorophyllModels MolecularChlorophyll bChlorophyll aChlorophyll ABilayerLipid BilayersLight-Harvesting Protein ComplexesGeneral Physics and AstronomyLight-harvesting complexchemistry.chemical_compoundCrystallographychemistryChemical physicsChlorophyllddc:540MoleculeProtein MultimerizationPhysical and Theoretical ChemistryProtein Structure QuaternaryLipid bilayerAnsatz
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Structural and Functional Analysis of the Antiparallel Strands in the Lumenal Loop of the Major Light-harvesting Chlorophyll a/b Complex of Photosyst…

2007

The light-harvesting chlorophyll a/b-binding protein of photosystem II (LHCIIb) fulfills multiple functions, such as light harvesting and energy dissipation under different illuminations. The crystal structure of LHCIIb at the near atomic resolution reveals an antiparallel strands structure in the lumenal loop between the transmembrane helices B/C. To study the structural and functional significances of this structure, three amino acids (Val-119, His-120, and Ser-123) in this region have been exchanged to Phe, Leu, and Gly, respectively, and the influence of the mutagenesis on the structure and function of LHCIIb has been investigated. The results are as follows. 1) Circular dichroism spect…

ChlorophyllModels MolecularCircular dichroismPhotosystem IIRecombinant Fusion ProteinsLight-Harvesting Protein ComplexesAntiparallel (biochemistry)BiochemistryFluorescencechemistry.chemical_compoundNeoxanthinSite-directed mutagenesisMolecular BiologyPlant ProteinsPhotobleachingChemistryChlorophyll ACircular DichroismPeasPhotosystem II Protein ComplexCell BiologyFluorescenceTransmembrane domainB vitaminsCrystallographyMutationMutagenesis Site-DirectedProtein BindingJournal of Biological Chemistry
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How the Protein Environment Can Tune the Energy, the Coupling, and the Ultrafast Dynamics of Interacting Chlorophylls: The Example of the Water-Solub…

2020

The interplay between active molecules and the protein environment in light-harvesting complexes tunes the photophysics and the dynamical properties of pigment–protein complexes in a subtle way, which is not fully understood. Here we characterized the photophysics and the ultrafast dynamics of four variants of the water-soluble chlorophyll protein (WSCP) as an ideal model system to study the behavior of strongly interacting chlorophylls. We found that when coordinated by the WSCP protein, the presence of the formyl group in chlorophyll b replacing the methyl group in chlorophyll a strongly affects the exciton energy and the dynamics of the system, opening up the possibility of tuning the ph…

ChlorophyllModels MolecularLetterChemistryChlorophyll ALight-Harvesting Protein ComplexesTemperatureWater02 engineering and technology010402 general chemistry021001 nanoscience & nanotechnology01 natural sciences0104 chemical sciencesCoupling (physics)chemistry.chemical_compoundProtein environmentWater solubleChemical physicsChlorophyllThermodynamicsMoleculeGeneral Materials SciencePhysical and Theoretical Chemistry0210 nano-technologyUltrashort pulse
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Amino acids in the second transmembrane helix of the Lhca4 subunit are important for formation of stable heterodimeric light-harvesting complex LHCI-…

2007

Photosynthetic light-harvesting complexes (LHCs) are assembled from apoproteins (Lhc proteins) and non-covalently attached pigments. Despite a considerable amino acid sequence identity, these proteins differ in their oligomerization behavior. To identify the amino acid residues determining the heterodimerization of Lhca1 and Lhca4 to form LHCI-730, we mutated the poorly conserved second transmembrane helix of the two subunits. Mutated genes were expressed in Escherichia coli and the resultant proteins were refolded in vitro and subsequently analyzed by gel electrophoresis. Replacement of the entire second helix in Lhca4 by the one of Lhca3 abolished heterodimerization, whereas it had no eff…

ChlorophyllModels MolecularMolecular Sequence DataLight-Harvesting Protein ComplexesBiologyProtein Structure SecondarySerineSolanum lycopersicumStructural BiologyChlorophyll bindingConsensus sequenceHistidineHomology modelingAmino Acid SequenceAmino AcidsProtein Structure QuaternaryMolecular BiologyPeptide sequenceHistidinePlant Proteinschemistry.chemical_classificationPhotosystem I Protein ComplexAmino acidTransmembrane domainProtein SubunitschemistryBiochemistryMutagenesisChlorophyll Binding ProteinsDimerizationSequence AlignmentJournal of molecular biology
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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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Evidence for two spectroscopically different dimers of light-harvesting complex I from green plants

2000

A preparation consisting of isolated dimeric peripheral antenna complexes from green plant photosystem I (light-harvesting complex I or LHCI) has been characterized by means of (polarized) steady-state absorption and fluorescence spectroscopy at low temperatures. We show that this preparation can be described reasonably well by a mixture of two types of dimers. In the first dimer about 10% of all Q(y)() absorption of the chlorophylls arises from two chlorophylls with absorption and emission maxima at about 711 and 733 nm, respectively, whereas in the second about 10% of the absorption arises from two chlorophylls with absorption and emission maxima at about 693 and 702 nm, respectively. The…

ChlorophyllP700Photosystem IIPhotosystem I Protein ComplexChemistryDimerCircular DichroismPhotosynthetic Reaction Center Complex ProteinsLight-Harvesting Protein ComplexesPhotosystem II Protein ComplexPhotochemistryPhotosystem IBiochemistryZea maysFluorescence spectroscopychemistry.chemical_compoundSpectrometry FluorescenceLight harvesting complex ISpectrophotometryAbsorption (chemistry)Protein Structure QuaternaryDimerization
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Light-harvesting chlorophyll protein (LHCII) drives electron transfer in semiconductor nanocrystals

2017

Type-II quantum dots (QDs) are capable of light-driven charge separation between their core and the shell structures; however, their light absorption is limited in the longer-wavelength range. Biological light-harvesting complex II (LHCII) efficiently absorbs in the blue and red spectral domains. Therefore, hybrid complexes of these two structures may be promising candidates for photovoltaic applications. Previous measurements had shown that LHCII bound to QD can transfer its excitation energy to the latter, as indicated by the fluorescence emissions of LHCII and QD being quenched and sensitized, respectively. In the presence of methyl viologen (MV), both fluorescence emissions are quenched…

ChlorophyllParaquatPhotosynthetic reaction centreMaterials scienceAbsorption spectroscopyLight-Harvesting Protein ComplexesBiophysics02 engineering and technology010402 general chemistryPhotochemistry01 natural sciencesBiochemistryElectron TransportLight-harvesting complexElectron transferQuantum DotsUltrafast laser spectroscopyFluorescence Resonance Energy TransferAction spectrumPeasPhotosystem II Protein ComplexCell Biology021001 nanoscience & nanotechnologyFluorescence0104 chemical sciencesSemiconductorsQuantum dotNanoparticles0210 nano-technologyBiochimica et Biophysica Acta (BBA) - Bioenergetics
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Expression of a higher plant light-harvesting chlorophyll a/b-binding protein in Synechocystis sp. PCC 6803

1999

A chimeric lhcb gene, coding for Lhcb, a higher plant chlorophyll a/b-binding light-harvesting complex of photosystem II (LHCII), was constructed using the Synechocystis sp. PCC 6803 psbA3 promoter and a modified lhcb gene from pea. This construct drives synthesis of full-length, mature Lhcb under the control of the strong psbA3 promoter that usually drives expression of the D1 protein of photosystem II. This chimeric gene was transformed into a photosystem I-less/chlL(-) Synechocystis sp. PCC 6803 strain that is unable to synthesize chlorophyll in darkness. In the resulting strain, a high level of lhcb transcript was detected and transcript accumulation was enhanced by addition of exogenou…

ChlorophyllPhotosystem IIRecombinant Fusion ProteinsPhotosynthetic Reaction Center Complex ProteinsPigment bindingMutantLight-Harvesting Protein ComplexesGene ExpressionChimeric geneBiologyCyanobacteriaBiochemistrychemistry.chemical_compoundTransformation GeneticIntegral membrane proteinChromatography High Pressure LiquidPlant ProteinsPhotosystemModels GeneticPhotosystem I Protein ComplexPhotosystem II Protein ComplexPigments BiologicalSpectrometry FluorescenceBiochemistrychemistryThylakoidChlorophyllRNAEuropean Journal of Biochemistry
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Water soluble chlorophyll binding protein of higher plants: A most suitable model system for basic analyses of pigment–pigment and pigment–protein in…

2011

Abstract This short review paper describes spectroscopic studies on pigment–pigment and pigment–protein interactions of chlorophyll (Chl) a and b bound to the recombinant protein of class IIa water soluble chlorophyll protein (WSCP) from cauliflower. Two Chls form a strongly excitonically coupled open sandwich dimer within the tetrameric protein matrix. In marked contrast to the mode of excitonic coupling of Chl and bacterio-Chl molecules in light harvesting complexes and reaction centers of all photosynthetic organisms, the unique structural pigment array in the Chl dimer of WSCP gives rise to an upper excitonic state with a large oscillator strength. This property opens the way for thorou…

ChlorophyllPhysiologyTetrameric proteinDimerLight-Harvesting Protein ComplexesTemperatureWatermacromolecular substancesPlant SciencePlantsPhotochemistryPhotosynthesisModels BiologicalLight-harvesting complexchemistry.chemical_compoundPigmentchemistryChlorophyllvisual_artvisual_art.visual_art_mediumChlorophyll bindingMoleculeAgronomy and Crop ScienceJournal of Plant Physiology
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The Folding State of the Lumenal Loop Determines the Thermal Stability of Light-Harvesting Chlorophyll a/b Protein

2004

The major light-harvesting protein of photosystem II (LHCIIb) is the most abundant chlorophyll-binding protein in the thylakoid membrane. It contains three membrane-spanning alpha helices; the first and third one closely interact with each other to form a super helix, and all three helices bind most of the pigment cofactors. The protein loop domains connecting the alpha helices also play an important role in stabilizing the LHCIIb structure. Single amino acid exchanges in either loop were found to be sufficient to significantly destabilize the complex assembled in vitro [Heinemann, B., and Paulsen, H. (1999) Biochemistry 38, 14088-14093. Mick, V., Eggert, K., Heinemann, B., Geister, S., and…

ChlorophyllProtein DenaturationProtein FoldingPhotosystem IILight-Harvesting Protein ComplexesBiochemistryProtein structureTrypsinPlant Proteinschemistry.chemical_classificationChemistryChlorophyll AHydrolysisPeasTemperaturePhotosystem II Protein ComplexSodium Dodecyl SulfateProtein Structure TertiaryAmino acidKineticsCrystallographyAmino Acid SubstitutionMembrane proteinThylakoidHelixBiophysicsElectrophoresis Polyacrylamide GelProtein foldingAlpha helixBiochemistry
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