Peggy L. Bustamante scite author profile

Methodology has been developed to reconstitute carotenoids and bacteriochlorophyll alpha with isolated light-harvesting complex I (LHI) polypeptides of both Rhodobacter sphaeroides and Rhodospirillum rubrum. Reconstitution techniques first developed in this laboratory using the LHI polypeptides of R. rubrum, R. sphaeroides, and Rhodobacter capsulatus reproduced bacteriochlorophyll alpha spectral properties characteristic of LHI complexes lacking carotenoids. In this study, carotenoids are supplied either as organic-solvent extracts of chromatophores or as thin-layer chromatography or high performance liquid chromatography-purified species. The resulting LHI complexes exhibit carotenoid and bacteriochlorophyll a spectral properties characteristic of native LHI complexes of carotenoid-containing bacteria. Absorption and circular dichroism spectra support the attainment of a native-like carotenoid environment in the reconstituted LHI complexes. For both R. sphaeroides- and R. rubrum-reconstituted systems, fluorescence excitation spectra reveal appropriate carotenoid to bacteriochlorophyll alpha energy-transfer efficiencies based on comparisons with the in vivo systems. In the case of R. rubrum reconstitutions, carotenoids afford protection from photodynamic degradation. Thus, carotenoids reconstituted into LHI exhibit spectral and functional characteristics associated with native pigments. Heterologous reconstitutions demonstrate the applicability of the developed assay in dissecting the molecular environment of carotenoids in light-harvesting complexes.

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Evaluation of Structure−Function Relationships in the Core Light-Harvesting Complex of Photosynthetic Bacteria by Reconstitution with Mutant Polypeptides

Davis

Bustamante

Todd

et al. 1997

Biochemistry

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Seven mutant LH1 polypeptides of Rhodobactor sphaeroides have been isolated, and their behaviors in in vitro reconstitution of LH1 and its subunit complex have been characterized. Two mutants were selected to address the increased stability of the subunit complex of Rb. sphaeroides compared with that of Rhodobacter capsulatus. We found that this difference can be largely ascribed to the existence of Tyr at position +4 in the beta-polypeptide (the numbering system used assigns position 0 to the His which provides the coordinating ligand to bacteriochlorophyll) of the former bacterium compared to Met in that position in the latter. The amount of energy involved in the increased interaction was 1.6 kcal/mol, which would be consistent with a hydrogen bond involving Tyr. Mutation of the His at position 0 to Asn allows an estimate of the binding energy for subunit formation contributed by coordination of the imidazole group of His to the Mg atom of bacteriochlorophyll of >4.5 kcal/mol per BChl. Finally, an evaluation of the role of amino acids in the C-terminal region of the alpha-polypeptide was begun. Reconstitution of a mutant alpha-polypeptide in which Trp at position +11 was changed to Phe resulted in optimal formation of an LH1-type complex whose lambda(max) was blue-shifted to 853 nm, the same as observed in the intact bacterium harboring this mutation. These results provide further confirmation that the environment of BChl in reconstituted LH1 complexes is the same as in vivo and support the assignment of this residue to a role in hydrogen bonding with the C3(1) carbonyl group of BChl. Two other mutants of the alpha-polypeptide in which 5 and 14 amino acids in the C-terminus were deleted were also examined. These were of interest because the latter mutant, unlike the former, resulted in a low level of expression of LH1 in intact cells. However, with both of these mutant polypeptides, reconstitution appeared identical to that of the native system. In the case of the mutant shortened by 14 amino acids, a small blue-shift in lambda(max) to 861 nm was observed, again reproducing the blue-shift exhibited by the intact cells. Thus, these results suggest that the lowered levels of in vivo expression observed in these two mutants are due to reduced incorporation of the alpha-polypeptide into the membrane or its increased degradation, rather than to decreased stabilization of the LH1 complex.

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Comparison of Structural Subunits of the Core Light-Harvesting Complexes of Photosynthetic Bacteria

Loach¹,

Parkes-Loach²,

Chang³

et al. 1990

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Reconstitution of a Functional Photosynthetic Receptor Complex with Isolated Subunits of Core Light-Harvesting Complex and Reaction Centers

Bustamante

Loach

1994

Biochemistry

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The B820 subunit form of the core light-harvesting complex LHI, isolated from the photosynthetic bacterium Rhodospirillum rubrum, was combined in a reassociation assay with the reaction center (RC) isolated from the same or related bacteria. This reassociation produced a photoreceptor complex (PRC) which appeared, by absorption spectroscopy, circular dichroism measurements, and kinetic absorption spectroscopy measuring transient photochanges, as analogous to the PRC in the intact bacteria. Energy transfer between the LHI and reaction center progressed with almost 100% efficiency and indicated a cooperative pattern of transfer. Treatment of the RC with proteinase K resulted in peptide cleavages of all three polypeptides of the RC but did not alter the light-induced charge separation in the RC or prevent the reassociation of the LHI and modified RC. Energy transfer efficiency from LHI to RC still approached 100% but the cooperative behavior seen in reconstitutions with the intact RC was not observed. Initial experiments using interspecies reassociations (LHI from Rhodobacter sphaeroides and RC from Rs. rubrum) showed a low efficiency of energy transfer from LHI to RC. Possible association domains for the LHI-RC interaction based on considerations of the comparative amino acid sequences of the RC of each bacteria and the most feasible remaining residues in the proteinase K treated RC are considered.

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