Mechanism of Proton-Coupled
Electron Transfer in the
S0‑to‑S1 Transition of Photosynthetic
Water Oxidation As Revealed by Time-Resolved Infrared Spectroscopy
posted on 2018-09-25, 00:00authored byTatsuki Shimizu, Miwa Sugiura, Takumi Noguchi
Photosynthetic
water oxidation takes place at the Mn4CaO5 cluster
in photosystem II through a light-driven
cycle of intermediates called S states (S0–S4). To unravel the mechanism of water oxidation, it is essential
to understand the coupling of electron- and proton-transfer reactions
during the S-state transitions. Here, we monitored the reaction process
in the S0 → S1 transition using time-resolved
infrared (TRIR) spectroscopy. The TRIR signals of the pure contribution
of the S0 → S1 transition was obtained
by measurement upon a flash after dark adaptation following three
flashes. The S0 → S1 traces at the vibrational
frequencies of carboxylate groups and hydrogen bond networks around
the Mn4CaO5 cluster showed a single phase with
a time constant of ∼45 μs. A relatively small H/D kinetic
isotope effect of ∼1.2 together with the absence of a slower
phase suggests that proton release is coupled with electron transfer,
which is a rate-limiting step. The high rate of proton-coupled electron
transfer, which is even higher than pure electron transfer in the
S1 → S2 transition, is consistent with
the previous theoretical prediction that a hydroxo bridge of the Mn4CaO5 cluster gives rise to barrierless deprotonation
upon S1 formation through a strongly hydrogen-bonded water
molecule.