Your search keyword '"van Amerongen H"' showing total 6 results

1. Publisher Correction: Superradiance of bacteriochlorophyll c aggregates in chlorosomes of green photosynthetic bacteria.

Author

Malina T, Koehorst R, Bína D, Pšenčík J, and van Amerongen H

Published

2021

2. Superradiance of bacteriochlorophyll c aggregates in chlorosomes of green photosynthetic bacteria.

Author

Malina T, Koehorst R, Bína D, Pšenčík J, and van Amerongen H

Subjects

Energy Transfer, Pigments, Biological metabolism, Bacteria metabolism, Bacterial Proteins metabolism, Bacteriochlorophylls metabolism, Photosynthesis, Protein Aggregates

Abstract

Chlorosomes are the main light-harvesting complexes of green photosynthetic bacteria that are adapted to a phototrophic life at low-light conditions. They contain a large number of bacteriochlorophyll c, d, or e molecules organized in self-assembling aggregates. Tight packing of the pigments results in strong excitonic interactions between the monomers, which leads to a redshift of the absorption spectra and excitation delocalization. Due to the large amount of disorder present in chlorosomes, the extent of delocalization is limited and further decreases in time after excitation. In this work we address the question whether the excitonic interactions between the bacteriochlorophyll c molecules are strong enough to maintain some extent of delocalization even after exciton relaxation. That would manifest itself by collective spontaneous emission, so-called superradiance. We show that despite a very low fluorescence quantum yield and short excited state lifetime, both caused by the aggregation, chlorosomes indeed exhibit superradiance. The emission occurs from states delocalized over at least two molecules. In other words, the dipole strength of the emissive states is larger than for a bacteriochlorophyll c monomer. This represents an important functional mechanism increasing the probability of excitation energy transfer that is vital at low-light conditions. Similar behaviour was observed also in one type of artificial aggregates, and this may be beneficial for their potential use in artificial photosynthesis.

Published

2021

3. Lipid polymorphism in chloroplast thylakoid membranes - as revealed by 31 P-NMR and time-resolved merocyanine fluorescence spectroscopy.

Author

Garab G, Ughy B, Waard P, Akhtar P, Javornik U, Kotakis C, Šket P, Karlický V, Materová Z, Špunda V, Plavec J, van Amerongen H, Vígh L, As HV, and Lambrev PH

Subjects

Catalysis, Hydrogen-Ion Concentration, Lipids chemistry, Magnetic Resonance Spectroscopy methods, Phosphorus Isotopes, Spectrometry, Fluorescence methods, Thylakoids chemistry, Thylakoids metabolism

Abstract

Chloroplast thylakoid membranes contain virtually all components of the energy-converting photosynthetic machinery. Their energized state, driving ATP synthesis, is enabled by the bilayer organization of the membrane. However, their most abundant lipid species is a non-bilayer-forming lipid, monogalactosyl-diacylglycerol; the role of lipid polymorphism in these membranes is poorly understood. Earlier 31 P-NMR experiments revealed the coexistence of a bilayer and a non-bilayer, isotropic lipid phase in spinach thylakoids. Packing of lipid molecules, tested by fluorescence spectroscopy of the lipophilic dye, merocyanine-540 (MC540), also displayed heterogeneity. Now, our 31 P-NMR experiments on spinach thylakoids uncover the presence of a bilayer and three non-bilayer lipid phases; time-resolved fluorescence spectroscopy of MC540 also reveals the presence of multiple lipidic environments. It is also shown by 31 P-NMR that: (i) some lipid phases are sensitive to the osmolarity and ionic strength of the medium, (ii) a lipid phase can be modulated by catalytic hydrogenation of fatty acids and (iii) a marked increase of one of the non-bilayer phases upon lowering the pH of the medium is observed. These data provide additional experimental evidence for the polymorphism of lipid phases in thylakoids and suggest that non-bilayer phases play an active role in the structural dynamics of thylakoid membranes.

Published

2017

4. Cyanobacterial Light-Harvesting Phycobilisomes Uncouple From Photosystem I During Dark-To-Light Transitions.

Author

Chukhutsina V, Bersanini L, Aro EM, and van Amerongen H

Subjects

Electron Transport, Energy Transfer physiology, Light, Spectrometry, Fluorescence, Photosynthesis physiology, Photosystem I Protein Complex metabolism, Photosystem II Protein Complex metabolism, Phycobilisomes metabolism, Synechocystis metabolism

Abstract

Photosynthetic organisms cope with changes in light quality by balancing the excitation energy flow between photosystems I (PSI) and II (PSII) through a process called state transitions. Energy redistribution has been suggested to be achieved by movement of the light-harvesting phycobilisome between PSI and PSII, or by nanometre scale rearrangements of the recently discovered PBS-PSII-PSI megacomplexes. The alternative 'spillover' model, on the other hand, states that energy redistribution is achieved by mutual association/dissociation of PSI and PSII. State transitions have always been studied by changing the redox state of the electron carriers using electron transfer inhibitors, or by applying illumination conditions with different colours. However, the molecular events during natural dark-to-light transitions in cyanobacteria have largely been overlooked and still remain elusive. Here we investigated changes in excitation energy transfer from phycobilisomes to the photosystems upon dark-light transitions, using picosecond fluorescence spectroscopy. It appears that megacomplexes are not involved in these changes, and neither does spillover play a role. Instead, the phycobilisomes partly energetically uncouple from PSI in the light but hardly couple to PSII.

Published

2015

5. Identification of a mechanism of photoprotective energy dissipation in higher plants.

Author

Ruban AV, Berera R, Ilioaia C, van Stokkum IH, Kennis JT, Pascal AA, van Amerongen H, Robert B, Horton P, and van Grondelle R

Subjects

Chloroplasts metabolism, Chloroplasts radiation effects, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes isolation & purification, Models, Molecular, Photosystem II Protein Complex isolation & purification, Photosystem II Protein Complex metabolism, Plant Leaves metabolism, Plant Leaves radiation effects, Spectrum Analysis, Raman, Time Factors, Xanthophylls chemistry, Xanthophylls metabolism, Arabidopsis cytology, Hot Temperature, Light, Light-Harvesting Protein Complexes metabolism, Spinacia oleracea metabolism

Abstract

Under conditions of excess sunlight the efficient light-harvesting antenna found in the chloroplast membranes of plants is rapidly and reversibly switched into a photoprotected quenched state in which potentially harmful absorbed energy is dissipated as heat, a process measured as the non-photochemical quenching of chlorophyll fluorescence or qE. Although the biological significance of qE is established, the molecular mechanisms involved are not. LHCII, the main light-harvesting complex, has an inbuilt capability to undergo transformation into a dissipative state by conformational change and it was suggested that this provides a molecular basis for qE, but it is not known if such events occur in vivo or how energy is dissipated in this state. The transition into the dissipative state is associated with a twist in the configuration of the LHCII-bound carotenoid neoxanthin, identified using resonance Raman spectroscopy. Applying this technique to study isolated chloroplasts and whole leaves, we show here that the same change in neoxanthin configuration occurs in vivo, to an extent consistent with the magnitude of energy dissipation. Femtosecond transient absorption spectroscopy, performed on purified LHCII in the dissipative state, shows that energy is transferred from chlorophyll a to a low-lying carotenoid excited state, identified as one of the two luteins (lutein 1) in LHCII. Hence, it is experimentally demonstrated that a change in conformation of LHCII occurs in vivo, which opens a channel for energy dissipation by transfer to a bound carotenoid. We suggest that this is the principal mechanism of photoprotection.

Published

2007

6. Molecular basis of photoprotection and control of photosynthetic light-harvesting.

Author

Pascal AA, Liu Z, Broess K, van Oort B, van Amerongen H, Wang C, Horton P, Robert B, Chang W, and Ruban A

Subjects

Chlorophyll metabolism, Crystallization, Crystallography, X-Ray, Fluorescence, Light-Harvesting Protein Complexes chemistry, Models, Molecular, Photosystem II Protein Complex chemistry, Photosystem II Protein Complex metabolism, Photosystem II Protein Complex radiation effects, Pigments, Biological chemistry, Pigments, Biological metabolism, Plants chemistry, Plants metabolism, Plants radiation effects, Protein Structure, Tertiary, Spectrum Analysis, Raman, Structure-Activity Relationship, Light, Light-Harvesting Protein Complexes metabolism, Light-Harvesting Protein Complexes radiation effects, Photosynthesis physiology, Photosynthesis radiation effects

Abstract

In order to maximize their use of light energy in photosynthesis, plants have molecules that act as light-harvesting antennae, which collect light quanta and deliver them to the reaction centres, where energy conversion into a chemical form takes place. The functioning of the antenna responds to the extreme changes in the intensity of sunlight encountered in nature. In shade, light is efficiently harvested in photosynthesis. However, in full sunlight, much of the energy absorbed is not needed and there are vitally important switches to specific antenna states, which safely dissipate the excess energy as heat. This is essential for plant survival, because it provides protection against the potential photo-damage of the photosynthetic membrane. But whereas the features that establish high photosynthetic efficiency have been highlighted, almost nothing is known about the molecular nature of the dissipative states. Recently, the atomic structure of the major plant light-harvesting antenna protein, LHCII, has been determined by X-ray crystallography. Here we demonstrate that this is the structure of a dissipative state of LHCII. We present a spectroscopic analysis of this crystal form, and identify the specific changes in configuration of its pigment population that give LHCII the intrinsic capability to regulate energy flow. This provides a molecular basis for understanding the control of photosynthetic light-harvesting.

Published

2005