Abstract
In photosynthetic water oxidation, two water molecules are converted into one oxygen molecule and four protons at the Mn4CaO5 cluster in photosystem II (PSII) via the S-state cycle. Efficient proton exit from the catalytic site to the lumen is essential for this process. However, the exit pathways of individual protons through the PSII proteins remain to be identified. In this study, we examined the involvement of a hydrogen-bond network near the redox-active tyrosine YZ in proton transfer during the S-state cycle. We focused on spectroscopic analyses of a site-directed variant of D1-Asn-298, a residue involved in a hydrogen-bond network near YZ We found that the D1-N298A mutant of Synechocystis sp. PCC 6803 exhibits an O2 evolution activity of ∼10% of the wild-type. D1-N298A and the wild-type D1 had very similar features of thermoluminescence glow curves and of an FTIR difference spectrum upon YZ oxidation, suggesting that the hydrogen-bonded structure of YZ and electron transfer from the Mn4CaO5 cluster to YZ were little affected by substitution. In the D1-N298A mutant, however, the flash-number dependence of delayed luminescence showed a monotonic increase without oscillation, and FTIR difference spectra of the S-state cycle indicated partial and significant inhibition of the S2 → S3 and S3 → S0 transitions, respectively. These results suggest that the D1-N298A substitution inhibits the proton transfer processes in the S2 → S3 and S3 → S0 transitions. This in turn indicates that the hydrogen-bond network near YZ can be functional as a proton transfer pathway during photosynthetic water oxidation.
Highlights
Plants and cyanobacteria utilize water as an ultimate electron donor to reduce carbon dioxide in the synthesis of sugars [1]
YZ1⁄7 oxidizes the water-oxidizing center (WOC), the catalytic site of water oxidation, which consists of a Mn4CaO5 cluster as an inorganic core, its amino acid (D1-Asp170, D1-Glu-189, D1-His-332, D1-Glu-333, D1-Asp-342, D1-Ala-344, and CP43-Glu-354) and water (W1–W4) ligands, two Cl ions (Cl-1 and Cl-2), a hydrogen-bonded network formed by nearby water molecules and amino acid residues (Fig. 1A) [17,18,19,20,21]
Fourier transform infrared (FTIR) difference spectroscopy is a powerful method for detecting the structural perturbations of amino acid residues, water molecules, and the hydrogen-bond network around the Mn4CaO5 cluster, as well as monitoring the inhibition of the S-state transitions [61,62,63,64,65,66,67,68,69,70]
Summary
In PSII, photochemical reactions start with light-induced charge separation between the primary donor chlorophyll (Chl), P680, and the pheophytin electron acceptor, Pheo [10, 11]. Detailed properties of the mutants of D1-Asn-298, such as specific inhibition of either electron or proton transfer in individual S-state transitions, have not yet been investigated, and no clear answer was obtained about the involvement of pathways near the YZ site in the water oxidation mechanism. FTIR difference spectroscopy is a powerful method for detecting the structural perturbations of amino acid residues, water molecules, and the hydrogen-bond network around the Mn4CaO5 cluster, as well as monitoring the inhibition of the S-state transitions [61,62,63,64,65,66,67,68,69,70].
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