Tracking Reactive Water and Hydrogen-Bonding Networks
in Photosynthetic Oxygen Evolution
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Abstract
ConspectusIn oxygenic photosynthesis, photosystem II (PSII)
converts water
to molecular oxygen through four photodriven oxidation events at a
Mn<sub>4</sub>CaO<sub>5</sub> cluster. A tyrosine, YZ (Y161 in the
D1 polypeptide), transfers oxidizing equivalents from an oxidized,
primary chlorophyll donor to the metal center. Calcium or its analogue,
strontium, is required for activity. The Mn<sub>4</sub>CaO<sub>5</sub> cluster and YZ are predicted to be hydrogen bonded in a water-containing
network, which involves amide carbonyl groups, amino acid side chains,
and water. This hydrogen-bonded network includes amino acid residues
in intrinsic and extrinsic subunits. One of the extrinsic subunits,
PsbO, is intrinsically disordered. This extensive (35 Å) network
may be essential in facilitating proton release from substrate water.
While it is known that some proteins employ internal water molecules
to catalyze reactions, there are relatively few methods that can be
used to study the role of water. In this Account, we review spectroscopic
evidence from our group supporting the conclusion that the PSII hydrogen-bonding
network is dynamic and that water in the network plays a direct role
in catalysis. Two approaches, transient electron paramagnetic resonance
(EPR) and reaction-induced FT-IR (RIFT-IR) spectroscopies, were used.
The EPR experiments focused on the decay kinetics of YZ• via
recombination at 190 K and the solvent isotope, pH, and calcium dependence
of these kinetics. The RIFT-IR experiments focused on shifts in amide
carbonyl frequencies, induced by photo-oxidation of the metal cluster,
and on the isotope-based assignment of bands to internal, small protonated
water clusters at 190, 263, and 283 K. To conduct these experiments,
PSII was prepared in selected steps along the catalytic pathway, the
S<sub><i>n</i></sub> state cycle (<i>n</i> = 0–4).
This cycle ultimately generates oxygen. In the EPR studies, S-state
dependent changes were observed in the YZ• lifetime and in its
solvent isotope effect. The YZ• lifetime depended on the presence
of calcium at pH 7.5, but not at pH 6.0, suggesting a two-donor model
for PCET. At pH 6.0 or 7.5, barium and ammonia both slowed the rate
of YZ• recombination, consistent with disruption of the hydrogen-bonding
network. In the RIFT-IR studies of the S state transitions, infrared
bands associated with the transient protonation and deprotonation
of internal waters were identified by D<sub>2</sub>O and H<sub>2</sub><sup>18</sup>O labeling. The infrared bands of these protonated water
clusters, W<sub><i>n</i></sub><sup>+</sup> (or <i>n</i>H<sub>2</sub>O(H<sub>3</sub>O)<sup>+</sup>, <i>n</i> =
5–6), exhibited flash dependence and were produced during the
S<sub>1</sub> to S<sub>2</sub> and S<sub>3</sub> to S<sub>0</sub> transitions.
Calcium dependence was observed at pH 7.5, but not at pH 6.0. S-state
induced shifts were observed in amide CO frequencies during
the S<sub>1</sub> to S<sub>2</sub> transition and attributed to alterations
in hydrogen bonding, based on ammonia sensitivity. In addition, isotope
editing of the extrinsic subunit, PsbO, established that amide vibrational
bands of this lumenal subunit respond to the S state transitions and
that PsbO is a structural template for the reaction center. Taken
together, these spectroscopic results support the hypothesis that
proton transfer networks, extending from YZ to PsbO, play a functional
and dynamic role in photosynthetic oxygen evolution