Search results for "Chlorosome"

showing 5 items of 5 documents

Excitation Energy Transfer in Isolated Chlorosomes from Chlorobaculum tepidum and Prosthecochloris aestuarii

2012

Excitation energy transfer in chlorosomes from photosynthetic green sulfur bacteria, Chlorobaculum (Cba.) tepidum and Prosthecochloris (Pst.) aestuarii, have been studied at room temperature by time-resolved femtosecond transient absorption spectroscopy. Bleach rise times from 117 to 270 fs resolved for both chlorosomes reflect extremely efficient intrachlorosomal energy transfer. Bleach relaxation times, from 1 to 3 ps and 25 to 35 ps, probed at 758 nm were tentatively assigned to intrachlorosomal energy transfer based on amplitude changes of the global fits and model calculations. The anisotropy decay constant of about 1 ps resolved at 807 nm probe wavelength for the chlorosomes from Chlo…

biologyChemistryChloroflexus aurantiacusRelaxation (NMR)ChlorosomeGeneral Medicinebiology.organism_classificationPhotochemistryBiochemistryChemical physicsGreen sulfur bacteriaUltrafast laser spectroscopyFemtosecondPhysical and Theoretical ChemistrySpectroscopyExcitationPhotochemistry and Photobiology
researchProduct

Early Steps in the Assembly of Light-harvesting Chlorophyll a/b Complex

2004

The light-harvesting chlorophyll a/b complex (LHCIIb) spontaneously assembles from its pigment and protein components in detergent solution. The formation of functional LHCIIb can be detected in time-resolved experiments by monitoring the establishment of excitation energy transfer from protein-bound chlorophyll b to chlorophyll a. To detect the possible initial steps of chlorophyll binding that may not yet give rise to chlorophyll b-to-a energy transfer, we have monitored LHCIIb assembly by measuring excitation energy transfer from a fluorescent dye, covalently bound to the protein, to the chlorophylls. In order to exclude interference of the dye with protein folding or pigment binding, th…

Chlorophyll bChlorophyll aChemistryPigment bindingChlorosomeLight-harvesting complexes of green plantsCell BiologyPhotochemistryBiochemistrychemistry.chemical_compoundChlorophyllChlorophyll bindingMolecular BiologyChlorophyll fluorescenceJournal of Biological Chemistry
researchProduct

Excitation energy transfer in isolated chlorosomes from Chloroflexus aurantiacus

2009

Abstract Chlorosomes from green photosynthetic bacteria Chloroflexus aurantiacus have been studied by time-resolved femtosecond transient absorption spectroscopy. The fastest kinetics of 200–300 fs resolved, was interpreted to stem for intra-chlorosomal excitation energy transfer. Energy transfer from the antenna to the baseplate appeared as a major 9.2 ps rise component detected at the baseplate probe wavelength. Excitation energy transfer rates were evaluated for a model chlorosome. Calculated rod to rod, and rods to baseplate rate constants of 200–400 fs and 10–20 ps, respectively, are in accord with the experimental results.

biologyChemistryChloroflexus aurantiacusAnalytical chemistryGeneral Physics and AstronomyChlorosomebiology.organism_classificationMolecular physicsRodFemtosecondUltrafast laser spectroscopyPhotosynthetic bacteriaPhysical and Theoretical ChemistrySpectroscopyExcitationChemical Physics Letters
researchProduct

Exciton description of chlorosome to baseplate excitation energy transfer in filamentous anoxygenic phototrophs and green sulfur bacteria.

2013

A description of intra-chlorosome and from chlorosome to baseplate excitation energy transfer in green sulfur bacteria and in filamentous anoxygenic phototrophs is presented. Various shapes and sizes, single and multiwalled tubes, cylindrical spirals and lamellae of the antenna elements mimicking pigment organization in chlorosomes were generated by using molecular mechanics calculations, and the absorption, LD, and CD spectra of these were predicted by using exciton theory. Calculated absorption and LD spectra were similar for all modeled antenna structures; on the contrary, CD spectra turned out to be sensitive to the size and pigment orientations in the antenna. It was observed that, bri…

Physics::Biological PhysicsTime FactorsPhototrophbiologyChemistryExcitonChlorosomeModels Theoreticalbiology.organism_classificationMolecular physicsAnoxygenic photosynthesisSurfaces Coatings and FilmsChlorobiCrystallographyBacterial ProteinsEnergy TransferGreen sulfur bacteriaMaterials ChemistryPhysical and Theoretical ChemistryAntenna (radio)Organic ChemicalsAbsorption (electromagnetic radiation)ta116BacteriochlorophyllsExcitationThe journal of physical chemistry. B
researchProduct

A Theoretical Model for Excitation Energy Transfer in Chlorosomes: Lamellar and Rod-Shaped Antenna Structures

2008

A model based on exciton theory is presented for description of excitation energy transfer in chlorosomes. Three models to describe the internal organization of the pigments inside the chlorosome were considered, a stack of single-wall rods, a stack of double-wall rods and a stack of lamellae directed along the long axis of the chlorosome. Simulated absorption, circular dichroism and linear dichroism spectra of single-wall rod and the lamella structures turned out to be practically identical. It was shown that rod—rod interactions may localize the exciton states in the regions of a rod facing a neighboring rod. Such localized states provide a fast excitation energy transfer mechanism in per…

Physics::Biological PhysicsMaterials sciencegenetic structuresExcitonChlorosomeLinear dichroismMolecular physicsRodCondensed Matter::Soft Condensed MatterLamella (surface anatomy)Lamellar structuresense organsAbsorption (electromagnetic radiation)Excitation
researchProduct