Spectral hole burning study of intact cells of green bacterium Chlorobium limicola

AbstractSpectral hole burning studies of intact cells of the green bacterium, Chlorobium limicola, have proven that the Qy-absorption system of antenna bacteriochlorophyll c (BChl c) should be interpreted in terms of the delocalized exciton level structure of an oligomer. For the first time the 0-0 band of the lowest exciton state of BChl c oligomers has been directly detected as the lowest energy inhomogeneously broadened band (FWHM −100 cm−1; position of maximum, at ~774 nm) of the near-infrared BChl c band of 1.8K excitation spectrum (FWHM = 830 cm−1; position of maximum, at 751 nm)

Experimental evidence of oligomeric organization of antenna bacteriochlorophyll c in green bacterium Chloroflexus aurantiacus by spectral hole burning

AbstractSpectral hole burning has been used to prove experimentally the existence in natural antenna of one of the predicted structural optimizing factors — antenna pigment oligomerization [J. Theor. Biol. 140 (1989) 167]—ensuring high efficiency of excitation energy transfer from antenna to reaction center, This point has been examined for the chlorosomal antenna of green bacterium Chloroflexus auranticus by hole burning in fluorescence excitation and emission spectra of intact cells at 1.8 K. The persistent hole spectra have been found to be consistent with a strongly exciton-coupled bacteriochloraphyll c (BChl c) chromophore system. The lowest exciton state of BChl c oligomers has been direclly detected and separated as the lowest energy inhomogeneously broadened band (FWHM ∼90 cm−1, position of maximum, at ∼752 nm) from the near-infrared BChl c band (FWHM ∼350 cm−1, position or maximum, at ∼74 nm) of 1.8 K excitation spectrum