Oxygenic photosynthesis begins in the reaction center (RC) of the protein complex photosystem II (PSII). PSII has an intriguing, nearly symmetrical arrangement of cofactors within its RC. Despite this symmetry, evolution has favored only one of the two branches of PSII for efficient electron transfer. Current spectroscopic experiments explore the electronic dynamics during the picoseconds after energy has entered the RC and until the electron transfers to the pheophytin of the first branch. We present state-of-the-art multiconfigurational multireference calculations of the excitation energies or site energies of the four chlorophyll pigments of the RC without protein environment considerations. We see a significant variation that breaks the apparent symmetry of the RC. The inner chlorophyll of the productive RC branch possessed the lowest excitation energy of the four central chlorophylls. Our computational method used here is expensive; thus, geometry optimization of the crystal structure is currently not possible. In future work, charge and energy dynamics within the RC will be included as well as a dynamic description of the protein environment and its coupling to the RC. Other state-of-the-art studies of the RC, at lower levels of electronic structure, include a static treatment of the protein environment. These almost unanimously report that the outer chlorophyll of the active branch had the lowest excitation energy. Future work is needed to reconcile this discrepancy.
Sørensen, L.N., De Vico, L., Hansen, T. (2024). A multireference view of photosynthesis: uncovering significant site energy variations among isolated Photosystem II reaction center chlorophylls. ACS OMEGA, 9(5), 5246-5254 [10.1021/acsomega.3c05331].
A multireference view of photosynthesis: uncovering significant site energy variations among isolated Photosystem II reaction center chlorophylls
De Vico, Luca;
2024-01-01
Abstract
Oxygenic photosynthesis begins in the reaction center (RC) of the protein complex photosystem II (PSII). PSII has an intriguing, nearly symmetrical arrangement of cofactors within its RC. Despite this symmetry, evolution has favored only one of the two branches of PSII for efficient electron transfer. Current spectroscopic experiments explore the electronic dynamics during the picoseconds after energy has entered the RC and until the electron transfers to the pheophytin of the first branch. We present state-of-the-art multiconfigurational multireference calculations of the excitation energies or site energies of the four chlorophyll pigments of the RC without protein environment considerations. We see a significant variation that breaks the apparent symmetry of the RC. The inner chlorophyll of the productive RC branch possessed the lowest excitation energy of the four central chlorophylls. Our computational method used here is expensive; thus, geometry optimization of the crystal structure is currently not possible. In future work, charge and energy dynamics within the RC will be included as well as a dynamic description of the protein environment and its coupling to the RC. Other state-of-the-art studies of the RC, at lower levels of electronic structure, include a static treatment of the protein environment. These almost unanimously report that the outer chlorophyll of the active branch had the lowest excitation energy. Future work is needed to reconcile this discrepancy.File | Dimensione | Formato | |
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https://hdl.handle.net/11365/1255814