Gregory J.S. Fowler scite author profile

Light energy for photosynthesis is collected by the antenna system, creating an excited state which migrates energetically 'downhill'. To achieve efficient migration of energy the antenna is populated with a series of pigments absorbing at progressively redshifted wavelengths. This variety in absorbing species in vivo has been created in a biosynthetically economical fashion by modulating the absorbance behaviour of one kind of (bacterio)chlorophyll molecule. This modulation is poorly understood but has been ascribed to pigment-pigment and pigment-protein interactions. We have examined the relationship between aromatic residues in antenna polypeptides and pigment absorption, by studying the effects of site-directed mutagenesis on a bacterial antenna complex. A clear correlation was observed between the absorbance of bacteriochlorophyll a and the presence of two tyrosine residues, alpha Tyr44 and alpha Tyr45, in the alpha subunit of the peripheral light-harvesting complex of Rhodobacter sphaeroides, a purple photosynthetic bacterium that provides a well characterized system for site-specific mutagenesis. By constructing single (alpha Tyr44, alpha Tyr45----PheTyr) and then double (alpha Tyr44, alpha Tyr45----PheLeu) site-specific mutants, the absorbance of bacteriochlorophyll was blueshifted by 11 and 24 nm at 77 K, respectively. The results suggest that there is a close approach of tyrosine residues to bacteriochlorophyll, and that this proximity may promote redshifts in vivo.

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Identification of the Upper Exciton Component of the B850 Bacteriochlorophylls of the LH2 Antenna Complex, Using a B800-Free Mutant of Rhodobacter sphaeroides

Koolhaas

et al. 1998

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In this paper, we report the circular dichroism (CD) spectra of two types of LH2-only mutants of Rhodobacter sphaeroides. In the first, only the wild type LH2 is present, while i the second, the B800 binding site of LH2 has been either destabilized or removed. For the first time, we have identified a band in the CD spectrum of LH2, located at approximately 780 nm, that can be ascribed to the high exciton component of the B850 band. The experimental spectra have been modeled by theoretical calculations. On this basis, the average interaction strength between the monomers in the B850 ring can be estimated to be approximately 300 cm-1. In addition, we suggest that in LH2 of Rb. sphaeroides the angles made by the Qy transitions of the B850 BChls with respect to the plane of the ring are slightly different from those calculated from the crystal structure of the Rhodopseudomonas acidophila LH2 complex.

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Blue shifts in bacteriochlorophyll absorbance correlate with changed hydrogen bonding patterns in light-harvesting 2 mutants of Rhodobacter sphaeroides with alterations at α-Tyr-44 and α-Tyr-45

et al. 1994

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A combination of Fourier-Transform (FT) resonance Raman spectroscopy and site-directed mutagenesis has been used to examine the function of two highly conserved aromatic residues, alpha-Tyr-44 and alpha-Tyr-45, in the light-harvesting 2 (LH2) complex of the photosynthetic bacterium Rhodobacter sphaeroides. In LH2 complexes, aromatic residues located at positions alpha-44 and alpha-45 are thought to be located near the putative binding site for bacteriochlorophyll, and alterations at these positions are known to produce blue shifts in bacteriochlorophyll absorbance. In the present work, mutant LH2 complexes carrying the alterations alpha-Tyr-44-->Phe, alpha-Tyr-45-->Phe and alpha-Tyr-44,-45-->Phe,Leu were examined. FT resonance Raman spectroscopy of the resulting complexes shows the breakage of a hydrogen bond to the 2-acetyl carbonyl group of one of the B850 bacteriochlorophylls in the LH2 complex; in the double mutant, breakage of a second bond is probable. These results suggest that one of these hydrogen bonds is to alpha-Tyr-44, placing this residue in close proximity to ring I of one of the B850 bacteriochlorophyll a pigments. The breakage of one, then two, 2-acetyl carbonyl hydrogen bonds correlates well with the shift in the absorbance of the B850 pigments of 11 nm then 26 nm at 77 K. Thus a consistency between literature theoretical calculations and the observations from both absorption and FT resonance Raman spectroscopy is demonstrated.

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Temporally and spectrally resolved subpicosecond energy transfer within the peripheral antenna complex (LH2) and from LH2 to the core antenna complex in photosynthetic purple bacteria.

Hess

Chachisvilis

Timpmann

et al. 1995

Proc. Natl. Acad. Sci. U.S.A.

123

110

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We report studies ofenergy transfer from the 800-nm absorbing pigment (B800) to the 850-nm absorbing pigment (B850) of the LH2 peripheral antenna complex and from LH2 to the core antenna complex (LH1) in Rhodobacter (Rb.) sphaeroides. The B800 to B850 process was studied in membranes from a LH2-reaction center (no LH1) mutant of Rb. sphaeroides and the LH2 to LH1 transfer was studied in both the wild-type species and in LH2 mutants with blueshifted B850. The measurements were performed by using '100-fs pulses to probe the formation of acceptor excitations in a two-color pump-probe measurement. Our experiments reveal a B800 to B850 transfer time of -0.7 ps at 296 K and energy transfer from LH2 to LH1 is characterized by a time constant of -3 ps at 296 K and -5 ps at 77 K. In the blue-shifted B850 mutants, the transfer time from B850 to LH1 becomes gradually longer with increasing blue-shift of the B850 band as a result of the decreasing spectral overlap between the antennae. The results have been used to produce a model for the association between the ring-like structures that are characteristic of both the LH2 and LH1 antennae.Organization and function of the core antenna complex (LH1) and the peripheral antenna complex (LH2) of purple bacteria have been extensively studied in the past (1, 2, 29). A major step forward in this work was taken very recently when the threedimensional structure of a complex of the peripheral antenna absorbing at 800 nm (B800) and at 850 nm (B850) from Rhodopseudomonas (Rps.) acidophila was solved to high resolution showing a ninefold circular symmetry of a13 pairs (3). From this structure of LH2 and the similar circular structure of LH1 (4), it has become clear that the pigment density in these light harvesting pigments is very high, leading to short intermolecular distances and strong dipole-dipole interactions. Presently, two modes of energy transfer are considered, incoherent F6rster transfer or exciton state relaxation (5-8), and it is a challenge for future research to establish the levels of organization at which the two modes of energy transfer are operative. Until experiments and theory have produced a unified description of the energy transfer dynamics, we have chosen to describe the energy transfer steps within LH2 and LH1 and between the complexes as incoherent Forster hopping. Early work on energy transfer dynamics in photosynthetic purple bacteria (9-16) yielded information about the overall exciton lifetime in the antenna and provided a time scale for energy equilibration within individual complexes (9, 10) and over the whole antenna (11,16). In particular, the LH2 antenna is probably the most extensively studied complex. Picosecond absorption and fluorescence studies performed at room and low temperature on the LH2 pigmentprotein complex of Rhodobacter (Rb.) sphaeroides revealed that B800 -> B850 energy transfer is a very fast and temperature-The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereb...

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Characterization of the Light-Harvesting Antennas of Photosynthetic Purple Bacteria by Stark Spectroscopy. 2. LH2 Complexes: Influence of the Protein Environment

et al. 1997

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We have performed low-temperature Stark spectroscopy on a variety of different LH2 complexes from four photosynthetic bacteria, with the aim of characterizing the electric field response of the B800 and B850 absorption properties as a function of the protein environment. The following LH2 complexes were investigated: B800-850 and B800-820 of Rhodopseudomonas (Rps) acidophila; B800-850, B800-840 (RTyr +13 fPhe), and B800-826 (RTyr +13 fPhe, RTyr +14 fLeu) of Rhodobacter (Rb.) sphaeroides; B800-850 and B800-830 (obtained at high LDAO) of Ectothiorhodospira sp.; and B800-850 of Rhodospirillum (Rsp.) molischianum. For all these cases the spectral blue shift of B850 has been assigned to the loss hydrogenbonding interaction with the acetyl carbonyl of bacteriochlorophyll a. |∆µ| values for the 850 nm bands as well as for the blue-shifted bands are all on the order of 3-4.5 D/f. The loss of hydrogen-bonding interactions has only small effects on |∆µ| in these complexes. The values of the difference polarizability, Tr(∆r), are large (600-1400 Å 3 /f 2 ). The results are discussed in terms of crystal-structure-based models for LH2, in which pigment-pigment and pigment-protein interactions are considered; strong pigment-pigment interactions were found to be especially important. The values of |∆µ| for the 800 nm band are small, 1.0-1.5 D/f for LH2 complexes from Rb. sphaeroides and Rps. acidophila. However, in Rsp. molischianum and Ectothiorhodospira sp. |∆µ| values are much larger, of the order of 3 D/f. The difference in the B800 band is assigned to the difference in orientation of the B800 pigments in Rsp. molischianum and Ectothiorhodospira sp., as compared to the Rps. acidophila and Rb. sphaeroides. Due to the difference in orientation, the interactions of the Bchl a with the surrounding protein and neighboring carotenoid pigments are also not identical.

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