Your search keyword '"Broess, K."' showing total 6 results

1. Determination of the herbicide amitrole in water with pre-column derivatization, liquid chromatography and tandem mass spectrometry

Author

Bobeldijk, I, Broess, K, Speksnijder, P, and van Leerdam, T

Published

2001

2. Excitation energy transfer and trapping in higher plant Photosystem II complexes with different antenna sizes.

Author

Caffarri S, Broess K, Croce R, and van Amerongen H

Subjects

Arabidopsis radiation effects, Chlorophyll chemistry, Chlorophyll A, Fluorescence, Kinetics, Molecular Dynamics Simulation, Protein Multimerization radiation effects, Time Factors, Arabidopsis metabolism, Energy Transfer radiation effects, Light-Harvesting Protein Complexes chemistry, Photosystem II Protein Complex chemistry

Abstract

We performed picosecond fluorescence measurements on well-defined Photosystem II (PSII) supercomplexes from Arabidopsis with largely varying antenna sizes. The average excited-state lifetime ranged from 109 ps for PSII core to 158 ps for the largest C(2)S(2)M(2) complex in 0.01% α-DM. Excitation energy transfer and trapping were investigated by coarse-grained modeling of the fluorescence kinetics. The results reveal a large drop in free energy upon charge separation (>700 cm(-1)) and a slow relaxation of the radical pair to an irreversible state (∼150 ps). Somewhat unexpectedly, we had to reduce the energy-transfer and charge-separation rates in complexes with decreasing size to obtain optimal fits. This strongly suggests that the antenna system is important for plant PSII integrity and functionality, which is supported by biochemical results. Furthermore, we used the coarse-grained model to investigate several aspects of PSII functioning. The excitation trapping time appears to be independent of the presence/absence of most of the individual contacts between light-harvesting complexes in PSII supercomplexes, demonstrating the robustness of the light-harvesting process. We conclude that the efficiency of the nonphotochemical quenching process is hardly dependent on the exact location of a quencher within the supercomplexes., (Copyright © 2011 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2011

3. Applying two-photon excitation fluorescence lifetime imaging microscopy to study photosynthesis in plant leaves.

Author

Broess K, Borst JW, and van Amerongen H

Subjects

Alocasia physiology, Arabidopsis physiology, Temperature, Time Factors, Microscopy, Fluorescence methods, Photons, Photosynthesis physiology, Plant Leaves physiology

Abstract

This study investigates to which extent two-photon excitation (TPE) fluorescence lifetime imaging microscopy can be applied to study picosecond fluorescence kinetics of individual chloroplasts in leaves. Using femtosecond 860 nm excitation pulses, fluorescence lifetimes can be measured in leaves of Arabidopsis thaliana and Alocasia wentii under excitation-annihilation free conditions, both for the F (0)- and the F (m)-state. The corresponding average lifetimes are approximately 250 ps and approximately 1.5 ns, respectively, similar to those of isolated chloroplasts. These values appear to be the same for chloroplasts in the top, middle, and bottom layer of the leaves. With the spatial resolution of approximately 500 nm in the focal (xy) plane and 2 microm in the z direction, it appears to be impossible to fully resolve the grana stacks and stroma lamellae, but variations in the fluorescence lifetimes, and thus of the composition on a pixel-to-pixel base can be observed.

Published

2009

4. Determination of the excitation migration time in Photosystem II consequences for the membrane organization and charge separation parameters.

Author

Broess K, Trinkunas G, van Hoek A, Croce R, and van Amerongen H

Subjects

Energy Transfer, Fluorescence, Kinetics, Membrane Proteins chemistry, Photosystem II Protein Complex chemistry, Plant Leaves metabolism, Spectrometry, Fluorescence, Spinacia oleracea metabolism, Thylakoids metabolism, Membrane Proteins metabolism, Models, Biological, Photosystem II Protein Complex metabolism

Abstract

The fluorescence decay kinetics of Photosystem II (PSII) membranes from spinach with open reaction centers (RCs), were compared after exciting at 420 and 484 nm. These wavelengths lead to preferential excitation of chlorophyll (Chl) a and Chl b, respectively, which causes different initial excited-state populations in the inner and outer antenna system. The non-exponential fluorescence decay appears to be 4.3+/-1.8 ps slower upon 484 nm excitation for preparations that contain on average 2.45 LHCII (light-harvesting complex II) trimers per reaction center. Using a recently introduced coarse-grained model it can be concluded that the average migration time of an electronic excitation towards the RC contributes approximately 23% to the overall average trapping time. The migration time appears to be approximately two times faster than expected based on previous ultrafast transient absorption and fluorescence measurements. It is concluded that excitation energy transfer in PSII follows specific energy transfer pathways that require an optimized organization of the antenna complexes with respect to each other. Within the context of the coarse-grained model it can be calculated that the rate of primary charge separation of the RC is (5.5+/-0.4 ps)(-1), the rate of secondary charge separation is (137+/-5 ps)(-1) and the drop in free energy upon primary charge separation is 826+/-30 cm(-1). These parameters are in rather good agreement with recently published results on isolated core complexes [Y. Miloslavina, M. Szczepaniak, M.G. Muller, J. Sander, M. Nowaczyk, M. Rögner, A.R. Holzwarth, Charge separation kinetics in intact Photosystem II core particles is trap-limited. A picosecond fluorescence study, Biochemistry 45 (2006) 2436-2442].

Published

2008

5. Excitation energy transfer and charge separation in photosystem II membranes revisited.

Author

Broess K, Trinkunas G, van der Weij-de Wit CD, Dekker JP, van Hoek A, and van Amerongen H

Subjects

Cell Membrane radiation effects, Computer Simulation, Energy Transfer drug effects, Light, Models, Molecular, Photosystem II Protein Complex radiation effects, Spinacia oleracea chemistry, Spinacia oleracea physiology, Spinacia oleracea radiation effects, Static Electricity, Cell Membrane chemistry, Cell Membrane physiology, Energy Transfer physiology, Models, Biological, Models, Chemical, Photosystem II Protein Complex chemistry, Photosystem II Protein Complex physiology

Abstract

We have performed time-resolved fluorescence measurements on photosystem II (PSII) containing membranes (BBY particles) from spinach with open reaction centers. The decay kinetics can be fitted with two main decay components with an average decay time of 150 ps. Comparison with recent kinetic exciton annihilation data on the major light-harvesting complex of PSII (LHCII) suggests that excitation diffusion within the antenna contributes significantly to the overall charge separation time in PSII, which disagrees with previously proposed trap-limited models. To establish to which extent excitation diffusion contributes to the overall charge separation time, we propose a simple coarse-grained method, based on the supramolecular organization of PSII and LHCII in grana membranes, to model the energy migration and charge separation processes in PSII simultaneously in a transparent way. All simulations have in common that the charge separation is fast and nearly irreversible, corresponding to a significant drop in free energy upon primary charge separation, and that in PSII membranes energy migration imposes a larger kinetic barrier for the overall process than primary charge separation.

Published

2006

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