From HB experiments performed in this way, we were able to obtain excitation energy-transfer times from BChl a molecules in the B800 ring to those in the B850 ring at low temperature. In addition, experiments on the red wing of the B850 band yielded a T 1.3±0.1 temperature dependence of Γhom (optical dephasing), similar to organic disordered systems, and an extrapolation value of Γhom for T → 0
that is consistent with a fluorescence lifetime of the excited state of a few nanoseconds. These results proved that no scattering processes, but only decay from the excited state takes place in the red wing of B850 at T → 0. By measuring hole widths as a function of delay selleck screening library time between burning and probing, we are able to obtain an insight into spectral diffusion processes in photosynthetic complexes, i.e. into irreversible low-frequency fluctuations of the protein. We found that a decrease of the amount of spectral diffusion is correlated with an increase of the size of the complex for the systems studied: the B777 monomer subunit of bacterial LH1, and the CP47, the RC and the CP47–RC complexes of PSII of higher plants. Furthermore, we have demonstrated that not only the hole widths but also the hole depths
reveal quantitative information that is otherwise hidden within a broad absorption band. On the one hand, ‘traps’ for energy transfer in the isolated PSII RC, CP47 and CP47-RC complexes of higher plants could be disentangled. On the other hand, the lowest k = 0 exciton distributions Crenigacestat solubility dmso buried within the B850 band of Mocetinostat purple bacteria were made visible. Finally, it is worth mentioning that spectral hole burning is not only a powerful technique
for studying photosynthetic complexes but its value has been demonstrated for other biological systems, such as green, yellow and red fluorescent proteins (GFPs and DsRed), also studied in our group (Bonsma et al. 2005; Creemers et al. 1999b, 2000). In these autofluorescent proteins, HB spectroscopy was used to obtain a ‘fingerprint’ of the species under study. For example, photo-convertible forms and their 0–0 transitions were identified and pathways of photo-conversion and energy transfer were determined. Owing to the G protein-coupled receptor kinase wavelength selectivity of HB, when using very narrow-band lasers, questions on the intricate electronic structure of proteins can be answered that cannot be solved with ultrafast (femtosecond) techniques, because of the inherently large optical bandwidths of short laser pulses. These two techniques are thus complementary for the study of complex biological systems. Acknowledgements There are a number of students and postdocs from our laboratory who were involved in the experiments mentioned here (results not yet published) that we would like to thank: Jürgen Gallus, Flurin Könz, Sybrand Bonsma, Sebastian Jezowski, Rifka Vlijm, Laura van den Aarssen, Vinzenz Koning and Nico Verhart.
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