Complete mapping of energy transfer pathways in the plant light-harvesting complex Lhca4

Martijn Tros; Vladimir I Novoderezhkin; Roberta Croce; Rienk van Grondelle; Elisabet Romero

doi:10.1039/d0cp03351k

Complete mapping of energy transfer pathways in the plant light-harvesting complex Lhca4

Martijn Tros, Vladimir I Novoderezhkin, Roberta Croce, Rienk van Grondelle, Elisabet Romero

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Abstract

The Lhca4 antenna complex of plant Photosystem I (PSI) is characterized by extremely red-shifted and broadened absorption and emission bands from its low-energy chlorophylls (Chls). The mixing of a charge-transfer (CT) state with the excited state manifold causing these so-called red forms results in highly complicated multi-component excited energy transfer (EET) kinetics within the complex. The two-dimensional electronic spectroscopy experiments presented here reveal that EET towards the CT state occurs on three timescales: fast from the red Chls (within 1 ps), slower (5-7 ps) from the stromal side Chls, and very slow (100-200 ps) from a newly discovered 690 nm luminal trap. The excellent agreement between the experimental data with the previously presented Redfield-Förster exciton model of Lhca4 strongly supports the equilibration scheme of the bulk excitations with the dynamically localized CT on the stromal side. Thus, a complete picture of the energy transfer pathways leading to the population of the CT final trap within the whole Lhca4 complex is presented. In view of the environmental sensitivity of the CT contribution to the Lhca4 energy landscape, we speculate that one role of the CT states is to regulate the EET from the peripheral antenna to the PSI core.

Original language	English
Pages (from-to)	25720-25729
Number of pages	10
Journal	Physical chemistry chemical physics : PCCP
Volume	22
Issue number	44
DOIs	https://doi.org/10.1039/d0cp03351k
Publication status	Published - 18 Nov 2020

Funding

This work was supported by the Dutch Research Council (NWO) via a Vici grant to R. C. RvG acknowledges the financial support offered to him via the BioInspired Solar Energy Program of the Canadian Institute For Advanced Research (CIFAR). V. I. N. was supported by the Russian Foundation for Basic Research (Grant No. 18-04-00105). E. R. was supported by the European Research Council (Starting Grant number 805524, BioInspir-ed_H2), and by the CERCA Program/Generalitat de Catalunya.

Funders	Funder number
CERCA Program/Generalitat de Catalunya
Canadian Institute for Advanced Research
Horizon 2020 Framework Programme	805524
European Research Council	BioInspir-ed_H2
Russian Foundation for Basic Research	18-04-00105
Nederlandse Organisatie voor Wetenschappelijk Onderzoek

Keywords

Biochemical Phenomena
Energy Transfer
Light-Harvesting Protein Complexes/chemistry
Models, Molecular

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Complete mapping of energy transfer pathways in the plant lightharvesting complex Lhca4Final published version, 4.95 MBLicence: Article 25fa Dutch Copyright Act

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title = "Complete mapping of energy transfer pathways in the plant light-harvesting complex Lhca4",

abstract = "The Lhca4 antenna complex of plant Photosystem I (PSI) is characterized by extremely red-shifted and broadened absorption and emission bands from its low-energy chlorophylls (Chls). The mixing of a charge-transfer (CT) state with the excited state manifold causing these so-called red forms results in highly complicated multi-component excited energy transfer (EET) kinetics within the complex. The two-dimensional electronic spectroscopy experiments presented here reveal that EET towards the CT state occurs on three timescales: fast from the red Chls (within 1 ps), slower (5-7 ps) from the stromal side Chls, and very slow (100-200 ps) from a newly discovered 690 nm luminal trap. The excellent agreement between the experimental data with the previously presented Redfield-F{\"o}rster exciton model of Lhca4 strongly supports the equilibration scheme of the bulk excitations with the dynamically localized CT on the stromal side. Thus, a complete picture of the energy transfer pathways leading to the population of the CT final trap within the whole Lhca4 complex is presented. In view of the environmental sensitivity of the CT contribution to the Lhca4 energy landscape, we speculate that one role of the CT states is to regulate the EET from the peripheral antenna to the PSI core.",

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author = "Martijn Tros and Novoderezhkin, {Vladimir I} and Roberta Croce and {van Grondelle}, Rienk and Elisabet Romero",

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AU - Romero, Elisabet

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N2 - The Lhca4 antenna complex of plant Photosystem I (PSI) is characterized by extremely red-shifted and broadened absorption and emission bands from its low-energy chlorophylls (Chls). The mixing of a charge-transfer (CT) state with the excited state manifold causing these so-called red forms results in highly complicated multi-component excited energy transfer (EET) kinetics within the complex. The two-dimensional electronic spectroscopy experiments presented here reveal that EET towards the CT state occurs on three timescales: fast from the red Chls (within 1 ps), slower (5-7 ps) from the stromal side Chls, and very slow (100-200 ps) from a newly discovered 690 nm luminal trap. The excellent agreement between the experimental data with the previously presented Redfield-Förster exciton model of Lhca4 strongly supports the equilibration scheme of the bulk excitations with the dynamically localized CT on the stromal side. Thus, a complete picture of the energy transfer pathways leading to the population of the CT final trap within the whole Lhca4 complex is presented. In view of the environmental sensitivity of the CT contribution to the Lhca4 energy landscape, we speculate that one role of the CT states is to regulate the EET from the peripheral antenna to the PSI core.

AB - The Lhca4 antenna complex of plant Photosystem I (PSI) is characterized by extremely red-shifted and broadened absorption and emission bands from its low-energy chlorophylls (Chls). The mixing of a charge-transfer (CT) state with the excited state manifold causing these so-called red forms results in highly complicated multi-component excited energy transfer (EET) kinetics within the complex. The two-dimensional electronic spectroscopy experiments presented here reveal that EET towards the CT state occurs on three timescales: fast from the red Chls (within 1 ps), slower (5-7 ps) from the stromal side Chls, and very slow (100-200 ps) from a newly discovered 690 nm luminal trap. The excellent agreement between the experimental data with the previously presented Redfield-Förster exciton model of Lhca4 strongly supports the equilibration scheme of the bulk excitations with the dynamically localized CT on the stromal side. Thus, a complete picture of the energy transfer pathways leading to the population of the CT final trap within the whole Lhca4 complex is presented. In view of the environmental sensitivity of the CT contribution to the Lhca4 energy landscape, we speculate that one role of the CT states is to regulate the EET from the peripheral antenna to the PSI core.

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Complete mapping of energy transfer pathways in the plant light-harvesting complex Lhca4

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UN SDGs

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