Henriette Kühne scite author profile

When acetate-inhibited photosystem II (PSII) membranes are illuminated at temperatures above 250 K and quickly cooled to 77 K, a 240 G-wide electron paramagnetic resonance (EPR) signal is observed at 10 K. This EPR signal arises from a reciprocal interaction between the spin 1/2 ground state of the S2 state of the Mn4 cluster, for which a multiline EPR signal with shifted 55Mn hyperfine peaks is observed, and the oxidized tyrosine residue, YZ*, for which a broadened YZ* EPR spectrum is observed. The S2YZ* EPR signal in acetate-inhibited PSII is the first in which characteristic spectral features from both paramagnets can be observed. The observation of distinct EPR signals from each of the paramagnets together with the lack of a half-field EPR transition indicates that the exchange and dipolar couplings are weak. Below 20 K, the S2YZ* EPR signal in acetate-inhibited PSII is in the static limit. Above 20 K, the line width narrows dramatically as the broad low-temperature S2YZ* EPR signal is converted to a narrow YZ* EPR signal at room temperature. The line width narrowing is interpreted to be due to averaging of the exchange and dipolar interactions between YZ* and the S2 state of the Mn4 cluster by rapid spin-lattice relaxation of the Mn4 cluster as the temperature is increased. Decay of the S2YZ* intermediate at 200 K shows that the g = 4.1 form of the S2 state is formed and that a noninteracting S2-state multiline EPR signal is not observed as an intermediate in the decay. This result shows that a change in the redox state of YZ induces a spin-state change in the Mn4 cluster in acetate-inhibited PSII. The interconversion between spin states of the Mn4 cluster in acetate-inhibited PSII supports the idea that YZ oxidation or YZ* reduction is communicated to the Mn4 cluster through a direct hydrogen-bonding pathway, possibly involving a ligand bound to the Mn4 cluster.

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Competitive Binding of Acetate and Chloride in Photosystem II

Kühne

Szalai

Brudvig

1999

Biochemistry

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The binding of chloride and acetate to photosystem II (PSII) was examined to elucidate the mechanism of acetate inhibition. The mode of inhibition was studied, and individual binding sites were assigned by steady-state O2 evolution measurements in correlation with electron paramagnetic resonance (EPR) results. Two binding sites were found for acetate, one chloride-sensitive on the electron donor side and one chloride-insensitive on the electron acceptor side. The respective binding constants were as follows: KCl = 0.5 +/- 0.2 mM (chloride binding to the donor side), KI = 16 +/- 5 mM (acetate binding to the donor side), and KI' = 130 +/- 40 mM (acetate binding to the acceptor side). When acetate was bound to the acceptor side of PSII, 200 K illumination induced a narrowed form of the QA-FeII EPR signal, the yield of which was independent of the chloride concentration. When acetate was bound to the donor side, room-temperature illumination produced the S2YZ* state. EPR measurements showed that both the yield and formation rate of this state increased with acetate concentration. Increasing chloride concentrations slowed the rate of formation of the S2YZ* state, but did not affect the steady-state yield of the S2YZ* state. These findings indicate that the light-induced reactions in acetate-inhibited PSII are modulated by both donor side and acceptor side binding of acetate, while the steady-state yield of the S2YZ* state at the high PSII concentrations used for EPR measurements depends primarily on acceptor side turnover. Our data further support a close proximity of chloride to YZ*, indicating a possible role for chloride in the electron-transfer mechanism at the O2-evolving complex.

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Proton-Coupled Electron Transfer Involving Tyrosine Z in Photosystem II

Kühne

Brudvig

2002

J. Phys. Chem. B

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The O2-evolving complex (OEC) of photosystem II (PSII) catalyzes the oxidation of water to dioxygen. In addition to a tetramanganese-oxo (Mn4) cluster, calcium and chloride ions, the OEC also contains Tyrosine Z (YZ), a redox intermediate in the water oxidation reaction. The redox mechanism employed by YZ is under much debate. Using a novel method to study YZ oxidation based on the kinetic competition with secondary donors, we examine the electron-donation pathways of manganese-depleted PSII over a range of temperature and pH. H/D substitution causes a shift in the onset temperature for YZ oxidation, enabling measurements of lyonium isotope effects. In deuterated samples, the onset temperature for YZ oxidation is upshifted, suggesting that proton movement is a required step. Proton inventory experiments were performed to determine the number of protons that shift during the YZ oxidation reaction. Our findings indicate the movement of a single proton during the rate-limiting step of the oxidation process. The results presented herein demonstrate a need for proton movement in conjunction with YZ oxidation and support previous proposals that a proton-coupled electron transfer (PCET) step is necessary for oxidation of YZ. The possible involvement of PCET in the energetics of specific steps in the mechanism of water oxidation is discussed.

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Component B Binding to the Soluble Methane Monooxygenase Hydroxylase by Saturation-Recovery EPR Spectroscopy of Spin-Labeled MMOB

et al. 2002

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