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Substrate water exchange in the S2 state of photosystem II is dependent on the conformation of the Mn4Ca cluster
Umeå universitet, Teknisk-naturvetenskapliga fakulteten, Kemiska institutionen.ORCID-id: 0000-0003-2975-8395
Umeå universitet, Teknisk-naturvetenskapliga fakulteten, Kemiska institutionen. Molecular Biomimetics, Department of Chemistry – Ångström, Uppsala University, Uppsala, Sweden.ORCID-id: 0000-0003-2790-7721
2020 (Engelska)Ingår i: Physical Chemistry, Chemical Physics - PCCP, ISSN 1463-9076, E-ISSN 1463-9084, Vol. 22, nr 23, s. 12894-12908Artikel i tidskrift (Refereegranskat) Published
Abstract [en]

In photosynthesis, dioxygen formation from water is catalyzed by the oxygen evolving complex (OEC) in Photosystem II (PSII) that harbours the Mn4Ca cluster. During catalysis, the OEC cycles through five redox states, S0 to S4. In the Sstate, the Mn4Ca cluster can exist in two conformations, which are signified by the low-spin (LS) g = 2 EPR multiline signal and the high-spin (HS) g = 4.1 EPR signal. Here, we employed time-resolved membrane inlet mass spectrometry to measure the kinetics of H218O/H216O exchange between bulk water and the two substrate waters bound at the Mn4Ca cluster in the SLS2, SHS2, and the S3 states in both Ca-PSII and Sr-PSII core complexes from T. elongatus. We found that the slowly exchanging substrate water exchanges 10 times faster in the SHS2 than in the SLS2 state, and that the SLS2 → SHS2 conversion has at physiological temperature an activation barrier of 17 ± 1 kcal mol−1. Of the presently suggested SHS2 models, our findings are best in agreement with a water exchange pathway involving a SHS2state that has an open cubane structure with a hydroxide bound between Ca and Mn1. We also show that water exchange in the S3 state is governed by a different equilibrium than in S2, and that the exchange of the fast substrate water in the Sstate is unaffected by Ca/Sr substitution. These findings support that (i) O5 is the slowly exchanging substrate water, with W2 being the only other option, and (ii) either W2 or W3 is the fast exchanging substrate. The three remaining possibilities for O–O bond formation in PSII are discussed.
Ort, förlag, år, upplaga, sidor
Royal Society of Chemistry, 2020. Vol. 22, nr 23, s. 12894-12908
Nationell ämneskategori
Fysikalisk kemi
Identifikatorer
URN: urn:nbn:se:umu:diva-173575DOI: 10.1039/d0cp01380cISI: 000543038500047PubMedID: 32373850Scopus ID: 2-s2.0-85086748140OAI: oai:DiVA.org:umu-173575DiVA, id: diva2:1455425
Tillgänglig från: 2020-07-24 Skapad: 2020-07-24 Senast uppdaterad: 2023-03-23Bibliografiskt granskad
Ingår i avhandling
1. Time-resolved Structural and Mechanistic Studies of Water Oxidation in Photosystem II: water here, water there, water everywhere
Öppna denna publikation i ny flik eller fönster >>Time-resolved Structural and Mechanistic Studies of Water Oxidation in Photosystem II: water here, water there, water everywhere
2020 (Engelska)Doktorsavhandling, sammanläggning (Övrigt vetenskapligt)
Abstract [en]

Oxygenic photosynthesis is undisputedly one of the most important chemical processes for human life on earth as it not only fills the atmosphere with the oxygen that we need to breathe, but also sustains the accumulation of biomass, which is not only used as nourishment but is also present in almost every aspect of our lives as building material, textiles in clothes and furniture, or even as living decorations to name a few.

The photosynthetic water-splitting mechanism is catalyzed by a water:plastoquinone oxido-reductase by the name of photosystem II (PSII), which is embedded in the thylakoid membranes of plants, algae and cyanobacteria. As it is excited by light, charge separation occurs in the reaction center of the protein and an electron is extracted by oxidation of Mn4Ca-cluster, that constitutes the active site for the water splitting reaction in PSII. When the Mn4Ca-cluster has been oxidized 4 times, it forms an oxygen-oxygen bond between two water derived ligands bound to the Mn4Ca-cluster and returns to the lowest oxidation state of the catalytic cycle. Understanding what ligands of the cluster that are used in the water splitting reaction is the key to unlocking the underlying chemical mechanism.

In this thesis I describe investigations, with room temperature X-ray diffraction (XRD) and X-ray emission spectroscopy (XES) on PSII microcrystals, of how the active site looks in all the stable intermediate oxidation states. Furthermore I describe how we uncovered the sequence of events that lead to insertion of an additional water ligand in the S2-S3 state transition of the catalytic cycle.

Furthermore, through time-resolved membrane-inlet mass spectrometry (TR-MIMS) measurements of the isotopic equilibration of the substrate waters with the bulk in conditions that induce different electron magnetic resonance (EPR) spectroscopic signatures, I present evidence that the exchange of the slowly exchanging substrate water Ws is controlled by a dynamic equilibrium between conformations in the S2-state that give rise to either the low-spin multiline (LS-ML) signal or the high-spin (HS) signal. Based on the crystal structures and litterature suggestions for the conformation of the HS state different scenarios were presented for the assignment of Ws and how it exchanges. This analysis is discussed in the context of all semi-stable intermediate oxidation states in the Kok cycle.

To further the understanding of this equilibrium, I also studied a selection of mutants positioned at strategic places in the vicinity of the different proposed substrates and at points that were suggested to be critical for substrate entry. With the combination of TR-MIMS and EPR, I reached the conclusion that by mutating valine 185 to asparagine, the water bound A-type conformation was stabilized, meanwhile in the mutant where aspartate 61 was mutated to alanine I observed that the barrier of the equilibrium between the exchanging conformations was so high that the interchange between them was arrested at room temperature. Additionally the retardation of the substrate exchange rates in the S3-states fit best with D61 being in the vicinity of the fast exchanging water. With this information we found the data best explained in a scenario where the water insertion of the S2-S3 transition was determining the if O-O bond formation occurred between the waters that were W2 and W3 or W2 and O5 in the S2 state. In addition, by mutation of glutamate 189 to glutamine that this residue is not important for the exchange of substrate waters in the S2 or the S3 states.

Finally I use a combination of substrate labelling with TR-MIMS and time resolved labelling of the waters that ligate the Mn4Ca-cluster to show that the briding oxygen O5  is exchanging with a near identical rate to Ws, further supporting the assignment that Ws=O5.

In conclusion, O-O bond formation most likely occurs between W2 (Wf) and O5 (Ws) via an oxo-oxyl radical coupling mechanism. The newly inserted water thus represents the slow exchanging water of the following S-state cycle.
Ort, förlag, år, upplaga, sidor
Umeå: Umeå Universitet, 2020. s. 104
Nyckelord
Oxygenic Photosynthesis, Photosystem II, TR-MIMS, isotope exchange, EPR, EDNMR, water splitting, water oxidation
Nationell ämneskategori
Fysikalisk kemi Biofysik Biokemi Molekylärbiologi
Identifikatorer
urn:nbn:se:umu:diva-174116 (URN)978-91-7855-343-3 (ISBN)978-91-7855-344-0 (ISBN)
Disputation
2020-09-11, Glasburen, KBC Huset, Linnaeus väg 6, Umeå, 13:00 (Engelska)
Opponent
Handledare
Anmärkning

ISBN för den tryckta versionen saknas i fulltext och spikblad: 978-91-7855-343-3.

Tillgänglig från: 2020-08-21 Skapad: 2020-08-18 Senast uppdaterad: 2025-02-20Bibliografiskt granskad

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