Orientation of Chlorophyll Transition Moments in the Higher-Plant Light-Harvesting Complex CP29

Simonetto, Roberto; Crimi, Massimo; Sandonà, Dorianna; Croce, Roberta; Cinque, Gianfelice; Breton, Jacques; Bassi, Roberto

doi:10.1021/bi991140s

Cited by 51 publications

(70 citation statements)

References 46 publications

(95 reference statements)

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“…By selecting 53°and 138°respectively, deviation between measured and predicted values is kept to ∼20°in each case. For A 5 -B 5 , the angle is also close to the value of 116°obtained by linear dichroism on pigment deletion CP29 mutants (23). Thus, our findings indicate that the homology model captures the essential features of energy transfer in CP29 reasonably well, yet also indicate potential for improvement.…”

Section: Resultssupporting

confidence: 81%

Solving structure in the CP29 light harvesting complex with polarization-phased 2D electronic spectroscopy

Ginsberg

Davis

Ballottari

et al. 2011

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

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The CP29 light harvesting complex from green plants is a pigmentprotein complex believed to collect, conduct, and quench electronic excitation energy in photosynthesis. We have spectroscopically determined the relative angle between electronic transition dipole moments of its chlorophyll excitation energy transfer pairs in their local protein environments without relying on simulations or an X-ray crystal structure. To do so, we measure a basis set of polarized 2D electronic spectra and isolate their absorptive components on account of the tensor relation between the light polarization sequences used to obtain them. This broadly applicable advance further enhances the acuity of polarized 2D electronic spectroscopy and provides a general means to initiate or feed back on the structural modeling of electronically-coupled chromophores in condensed phase systems, tightening the inferred relations between the spatial and electronic landscapes of ultrafast energy flow. We also discuss the pigment composition of CP29 in the context of light harvesting, energy channeling, and photoprotection within photosystem II.photosynthetic light harvesting | polarized multidimensional spectroscopy | photosystem II supercomplex U nderstanding the underlying principles that give rise to the exceptional efficiency of light harvesting in photosynthesis is key to the development of artificial solar energy collection. It is equally compelling from a fundamental standpoint on account of nature's unique and elegant solution to solar energy funneling that employs ultrafast electronic excitation energy transfer (EET). Nevertheless, the very features that make photosynthetic light harvesting so effective commensurately ensure that it remains challenging to study. A complete understanding of the phenomenon is predicated on determining why a configuration of chlorophyll (Chl) pigments within a protein give rise to efficient EET. Measuring this dynamic process must be done with femtosecond time resolution and involves deciphering a spectrally congested electronically-coupled system of chromophores only angstroms apart in a protein solvent bath. Contributions to what is known have arisen from a confluence of ultrafast spectroscopic techniques, high-resolution spatial structure determination via X-ray crystallography, and active development of condensed phase modeling (1-3). That building structure-function relationships requires understanding energy flow with elusive subnanometer precision underscores the necessity for tracking energy spectrally and mapping the results back onto spatial structure, in spite of the challenges associated with assigning often congested spectral features to individual chlorophyll excitations.The CP29 light harvesting complex is purported to play multiple roles beyond solar energy collection in the photosystem II supercomplex (PSII) of plants. CP29 is one of three highly homologous pigment-protein complexes (PPCs) found adjacent to the reaction center core of PSII, where charge separation initiates energy transduction ...

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Section: Resultssupporting

confidence: 81%

Solving structure in the CP29 light harvesting complex with polarization-phased 2D electronic spectroscopy

Ginsberg

Davis

Ballottari

et al. 2011

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

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“…In CP29 the orientation of the Chls has been determined from the LD signal after normalization. We therefore analyzed the spectra previously presented in Simonetto et al (26), and we calculated the orientation of the Cars transition moments. The orientation of the xanthophyll located in the L1 site was calculated from the spectrum of the E166V mutant in which the only xanthophyll present is located in site L1.…”

Section: Resultsmentioning

confidence: 99%

“…Chlorophyll concentration was Ϸ10 g/ml for CD and absorption measurements and 0.01 g/ml for fluorescence measurements. LD spectra are the same reported in Simonetto et al (26). Photobleaching kinetic was measured as described in Formaggio et al (10).…”

Section: Dna Construction and Mutation Of Cp29 -Cp29-wt And Mutantsmentioning

confidence: 99%

Xanthophyll Binding Sites of the CP29 (Lhcb4) Subunit of Higher Plant Photosystem II Investigated by Domain Swapping and Mutation Analysis

Gastaldelli

Canino

Croce

et al. 2003

Journal of Biological Chemistry

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The binding sites for xanthophylls in the CP29 antenna protein of higher plant Photosystem II have been investigated using recombinant proteins refolded in vitro. Despite the presence of three xanthophyll species CP29 binds two carotenoids per polypeptide. The localization of neoxanthin was studied producing a chimeric protein constructed by swapping the C-helix domain from CP29 to LHCII. The resulting holoprotein did not bind neoxanthin, confirming that the N1 site is not present in CP29. Neoxanthin in CP29 was, instead, bound to the L2 site, which is thus shown to have a wider specificity with respect to the homologous site L2 in LHCII. Lutein was found in the L1 site of CP29. For each site the selectivity for individual xanthophyll species was studied as well as its role in protein stabilization, energy transfer, and photoprotection. Putative xanthophyll binding sequences, identified by primary structure analysis as a stretch of hydrophobic residues including an acidic term, were analyzed by site-directed mutagenesis or, in one case, by deleting the entire sequence. The mutant proteins were unaffected in their xanthophyll composition, thus suggesting that the target motifs had little influence in determining xanthophyll binding, whereas hydrophobic sequences in the membrane-spanning helices are important.

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“…This protein binds eight Chls and two xanthophylls, which have, if any, very weak excitonic interactions between each other (23). Each mutation led to the removal of a single Chl, and an individual spectral form was detected in the absorption difference spectrum (13,28). A somewhat more complex situation was found in the major antenna protein LHCII (Lhcb1) that binds 12 Chl/ polypeptide and shows excitonic interactions between a subset of its chromophores.…”

Section: Discussionmentioning

confidence: 99%

Mutation Analysis of Lhca1 Antenna Complex

Morosinotto¹,

Castelletti²,

Breton³

et al. 2002

Journal of Biological Chemistry

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The light harvesting complex Lhca1, one of the four gene products comprising the photosystem I antenna system, has been analyzed by site-directed mutagenesis with the aim of determining the chromophore(s) responsible for its long wavelength chlorophyll spectral form, a specific characteristic of the LHCI antenna complex. A family of mutant proteins, each carrying a mutation at a single chlorophyll-binding residue, was obtained and characterized by biochemical and spectroscopic methods. A map of the chromophores bound to each of the 10 chlorophyll-binding sites was drawn, and the energy levels of the Q y transition were determined in most cases. When compared with Lhcb proteins previously analyzed, Lhca1 is characterized by stronger interactions between individual chromophores as detected by both biochemical and spectroscopic methods; most mutations, although targeted to a single residue, lead to the loss of more than one chromophore and of conservative CD signals typical of chlorophyll-chlorophyll interactions. The lower energy absorption form (686 nm at 100K, 688 nm at room temperature), which is responsible for the red-shifted emission components at 690 and 701 nm, typical of Lhca1, is associated with a chlorophyll a/chlorophyll a excitonic interaction originating from a pigment cluster localized in the protein domain situated between helix C and the helix A/helix B cross. This cluster includes chlorophylls bound to sites A5-B5-B6 and a xanthophyll bound to site L2.

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Orientation of Chlorophyll Transition Moments in the Higher-Plant Light-Harvesting Complex CP29

Cited by 51 publications

References 46 publications

Solving structure in the CP29 light harvesting complex with polarization-phased 2D electronic spectroscopy

Solving structure in the CP29 light harvesting complex with polarization-phased 2D electronic spectroscopy

Xanthophyll Binding Sites of the CP29 (Lhcb4) Subunit of Higher Plant Photosystem II Investigated by Domain Swapping and Mutation Analysis

Mutation Analysis of Lhca1 Antenna Complex

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