On the simulation and interpretation of substrate-water exchange experiments in photosynthetic water oxidation

Water oxidation by photosystem II (PSII) sustains most life on Earth, but the molecular mechanism of this unique process remains controversial. The ongoing identification of the binding sites and modes of the two water-derived substrate oxygens (‘substrate waters’) in the various intermediates (S i...

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Bibliographic Details
Published in:Photosynthesis research 2024-12, Vol.162 (2), p.413-426
Main Authors: Chernev, Petko, Aydin, A. Orkun, Messinger, Johannes
Format: Article
Language:English
Subjects:
Biochemistry
Biomedical and Life Sciences
calcium
data collection
Intermediates
Kinetics
Life Sciences
Manganese
Manganese - metabolism
mass spectrometry
Molecular modelling
molecular models
Oxidation
Oxidation-Reduction
oxygen
Oxygen - metabolism
Photosynthesis - physiology
Photosystem II
Photosystem II Protein Complex - metabolism
Plant Genetics and Genomics
Plant Physiology
Plant Sciences
species
Water - metabolism
Water exchange
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Summary:Water oxidation by photosystem II (PSII) sustains most life on Earth, but the molecular mechanism of this unique process remains controversial. The ongoing identification of the binding sites and modes of the two water-derived substrate oxygens (‘substrate waters’) in the various intermediates (S i states, i  = 0, 1, 2, 3, 4) that the water-splitting tetra-manganese calcium penta-oxygen (Mn 4 CaO 5 ) cluster attains during the reaction cycle provides central information towards resolving the unique chemistry of biological water oxidation. Mass spectrometric measurements of single- and double-labeled dioxygen species after various incubation times of PSII with H 2 18 O provide insight into the substrate binding modes and sites via determination of exchange rates. Such experiments have revealed that the two substrate waters exchange with different rates that vary independently with the S i state and are hence referred to as the fast (W f ) and the slow (W S ) substrate waters. New insight for the molecular interpretation of these rates arises from our recent finding that in the S 2 state, under special experimental conditions, two different rates of W S exchange are observed that appear to correlate with the high spin and low spin conformations of the Mn 4 CaO 5 cluster. Here, we reexamine and unite various proposed methods for extracting and assigning rate constants from this recent data set. The analysis results in a molecular model for substrate-water binding and exchange that reconciles the expected non-exchangeability of the central oxo bridge O5 when located between two Mn(IV) ions with the experimental and theoretical assignment of O5 as W S in all S states. The analysis also excludes other published proposals for explaining the water exchange kinetics.
ISSN:0166-8595
1573-5079
1573-5079
DOI:10.1007/s11120-024-01084-8