Search results for "Photosystem"

showing 10 items of 103 documents

Calcium signatures and signaling in cytosol and organelles of tobacco cells induced by plant defense elicitors

2011

Calcium signatures induced by two elicitors of plant defense reactions, namely cryptogein and oligogalacturonides, were monitored at the subcellular level, using apoaequorin-transformed Nicotiana tabacum var Xanthi cells, in which the apoaequorin calcium sensor was targeted either to cytosol, mitochondria or chloroplasts. Our study showed that both elicitors induced specific Ca2+ signatures in each compartment, with the most striking difference relying on duration. Common properties also emerged from the analysis of Ca2+ signatures: both elicitors induced a biphasic cytosolic [Ca2+] elevation together with a single mitochondrial [Ca2+] elevation concomitant with the first cytosolic [Ca2+] p…

ChlorophyllChloroplastsTime FactorsPhysiology[SDV]Life Sciences [q-bio]Nicotiana tabacumAequorinMitochondrionMITOCHONDRIALAntiportersCA2+CytosolPlant defenseINTACT CHLOROPLASTSCation Transport ProteinsCalcium signalingRECOMBINANT AEQUORINDEATHfood and beveragesARABIDOPSISOligogalacturonidesMitochondriaChloroplastBiochemistry[SDE]Environmental SciencesCryptogeinPhytophthorachemistry.chemical_elementCalciumBiologyChloroplastFluorescenceFungal ProteinsPHOTOSYSTEM-IIPlant CellsTobaccoOrganelle[SDV.BV]Life Sciences [q-bio]/Vegetal BiologyCalcium SignalingMolecular BiologyHYPERSENSITIVE RESPONSENITRIC-OXIDECell MembraneCell Biologybiology.organism_classificationSALICYLIC-ACIDOxygenCytosolchemistryBiophysicsbiology.proteinCalciumCell Calcium
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The negatively charged amino acids in the lumenal loop influence the pigment binding and conformation of the major light-harvesting chlorophyll a/b c…

2008

AbstractThe major chlorophyll (Chl) a/b complexes of photosystem II (LHCIIb), in addition to their primary light-harvesting function, play key roles in the organization of the granal ultrastructure of the thylakoid membranes and in various regulatory processes. These functions depend on the structural stability and flexibility of the complexes. The lumenal side of LHCIIb is exposed to broadly variable pH environments, due to the build-up and decay of the pH gradient during photosynthesis. Therefore, the negatively charged amino acids in the lumenal loop might be of paramount importance for adjusting the structure and functions of LHCIIb. In order to clarify the structural roles of these res…

ChlorophyllCircular dichroismPhotosystem IIPigment bindingMolecular ConformationBiophysicsPhotosynthesisBiochemistryMajor light-harvesting a/b complex of photosystem IILow pHAmino AcidsSpectroscopyPhotosystemchemistry.chemical_classificationChemistryCircular DichroismPhotosystem II Protein ComplexPigments BiologicalCell BiologyHydrogen-Ion ConcentrationAmino acidCrystallographyB vitaminsMutagenesisThylakoidBiophysicsElectrophoresis Polyacrylamide GelProtein BindingBiochimica et Biophysica Acta (BBA) - Bioenergetics
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Cadmium accumulation and buffering of cadmium-induced stress by arbuscular mycorrhiza in three Pisum sativum L. genotypes

2002

The role of arbuscular mycorrhiza in reducing Cd stress was investigated in three genotypes of Pisum sativum L. (cv. Frisson, VIR4788, VIR7128), grown in soil/sand pot cultures in the presence and absence of 2-3 mg kg(-1) bioavailable Cd, and inoculated or not with the arbuscular mycorrhizal fungus Glomus intraradices. Shoot, root and pod biomass were decreased by Cd in non-mycorrhizal plants. The presence of mycorrhiza attenuated the negative effect of Cd so that shoot biomass and activity of photosystem II, based on chlorophyll a fluorescence, were not significantly different between mycorrhizal plants growing in the presence or absence of the heavy metal (HM). Total P concentrations were…

ChlorophyllGenotypePhysiologyPhotosynthetic Reaction Center Complex ProteinsLight-Harvesting Protein Complexeschemistry.chemical_elementPlant SciencePhosphorus metabolismPisum[SDV.BV.BOT] Life Sciences [q-bio]/Vegetal Biology/BotanicsSativumSymbiosisBotanyPhotosynthesisMycorrhizaSymbiosisComputingMilieux_MISCELLANEOUSAnalysis of VarianceCadmiumbiologyChlorophyll AfungiFungiPeasPhotosystem II Protein Complexfood and beveragesPhosphorus[SDV.BV.BOT]Life Sciences [q-bio]/Vegetal Biology/Botanicsbiology.organism_classificationArbuscular mycorrhizachemistryShootPlant StructuresCadmium
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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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De-epoxidation of Violaxanthin in Light-harvesting Complex I Proteins

2004

The conversion of violaxanthin (Vx) to zeaxanthin (Zx) in the de-epoxidation reaction of the xanthophyll cycle plays an important role in the protection of chloroplasts against photooxidative damage. Vx is bound to the antenna proteins of both photosystems. In photosystem II, the formation of Zx is essential for the pH-dependent dissipation of excess light energy as heat. The function of Zx in photosystem I is still unclear. In this work we investigated the de-epoxidation characteristics of light-harvesting complex proteins of photosystem I (LHCI) under in vivo and in vitro conditions. Recombinant LHCI (Lhcal-4) proteins were reconstituted with Vx and lutein, and the convertibility of Vx wa…

ChlorophyllLuteinPhotosystem IIPhotosynthetic Reaction Center Complex ProteinsLight-Harvesting Protein ComplexesXanthophyllsPhotosystem IThylakoidsBiochemistrychemistry.chemical_compoundSolanum lycopersicumSpinacia oleraceaEscherichia coliMolecular BiologyPhotosystemchemistry.chemical_classificationBinding SitesPhotosystem I Protein ComplexChemistryfood and beveragesPigments BiologicalCell Biologybeta CaroteneRecombinant ProteinsChloroplastKineticsBiochemistryXanthophyllThylakoidEpoxy CompoundsApoproteinsViolaxanthinJournal of Biological Chemistry
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Early folding events during light harvesting complex II assembly in vitro monitored by pulsed electron paramagnetic resonance

2016

Efficient energy transfer in the major light harvesting complex II (LHCII) of green plants is facilitated by the precise alignment of pigments due to the protein matrix they are bound to. Much is known about the import of the LHCII apoprotein into the chloroplast via the TOC/TIC system and its targeting to the thylakoid membrane but information is sparse about when and where the pigments are bound and how this is coordinated with protein folding. In vitro, the LHCII apoprotein spontaneously folds and binds its pigments if the detergent-solubilized protein is combined with a mixture of chlorophylls a and b and carotenoids. In the present work, we employed this approach to study apoprotein fo…

ChlorophyllModels Molecular0301 basic medicineProtein FoldingPigment bindingLight-Harvesting Protein ComplexesBiophysicsBiochemistrylaw.invention03 medical and health scienceslawElectron paramagnetic resonancePlant ProteinsPulsed EPRChemistryElectron Spin Resonance SpectroscopyPeasPhotosystem II Protein ComplexCell BiologyProtein tertiary structureProtein Structure TertiaryChloroplastFolding (chemistry)KineticsCrystallography030104 developmental biologyEnergy TransferThylakoidProtein foldingApoproteinsProtein BindingBiochimica et Biophysica Acta (BBA) - Bioenergetics
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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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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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