X-ray spectroscopy-based structure of the Mn cluster and mechanism of photosynthetic oxygen evolution

Robblee, John H.; Cinco, Roehl M.; Yachandra, Vittal K.

doi:10.1016/s0005-2728(00)00217-6

Cited by 191 publications

(280 citation statements)

References 101 publications

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“…50), it seems reasonable that the main influence of Sr 2ϩ will be on its nearest neighbors, the Tyr Z and particularly the Mn 4 . A slowdown in the forward steps of the enzyme cycle (the advancement of the S-states) and the associated lowering of oxygen-evolving activity, as reported here and earlier, fit with the existing ideas on the location and role of the Ca 2ϩ .…”

Section: Discussionmentioning

confidence: 99%

“…Absorption of a photon results in a charge separation between a chlorophyll molecule (P 680 ), and a pheophytin molecule. The pheophytin anion transfers the electron to a quinone, Q A , and P 680 ϩ is reduced by a tyrosine residue, Tyr Z , that in turn is reduced by the Mn 4 cluster. During the enzyme cycle, the oxidizing side of PSII goes through five different redox states that are denoted S n , n varying from 0 to 4.…”

mentioning

confidence: 99%

“…Oxygen is released during the S 3 to S 0 transition in which S 4 is a transient state (reviewed in Refs. [1][2][3][4]. Ca 2ϩ ions are known to be required for enzyme activity (1,(5)(6)(7)(8).…”

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confidence: 99%

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Biosynthetic Ca2+/Sr2+ Exchange in the Photosystem II Oxygen-evolving Enzyme of Thermosynechococcus elongatus

Boussac

Rappaport

Carrier

et al. 2004

Journal of Biological Chemistry

151

175

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The thermophilic cyanobacterium, Thermosynechococcus elongatus, has been grown in the presence of Sr 2؉ instead of Ca 2؉ with the aim of biosynthetically replacing the Ca 2؉ of the oxygen-evolving enzyme with Sr 2؉. Not only were the cells able to grow normally with Sr 2؉ , they actively accumulated the ion to levels higher than those of Ca 2؉ in the normal cultures. A protocol was developed to purify a fully active Sr The evolution of oxygen as a result of light-driven water oxidation is catalyzed by photosystem II (PSII) 1 in which a cluster of 4 manganese ions acts both as a device for accumulating oxidizing equivalents and as the active site. The reaction center of PSII is made up of two membrane-spanning polypeptides (D1 and D2) that bear the redox cofactors involved in the main electron transfer route. Absorption of a photon results in a charge separation between a chlorophyll molecule (P 680 ), and a pheophytin molecule. The pheophytin anion transfers the electron to a quinone, Q A , and P 680 ϩ is reduced by a tyrosine residue, Tyr Z , that in turn is reduced by the Mn 4 cluster. During the enzyme cycle, the oxidizing side of PSII goes through five different redox states that are denoted S n , n varying from 0 to 4. Oxygen is released during the S 3 to S 0 transition in which S 4 is a transient state (reviewed in Refs.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Biosynthetic Ca2+/Sr2+ Exchange in the Photosystem II Oxygen-evolving Enzyme of Thermosynechococcus elongatus

Boussac

Rappaport

Carrier

et al. 2004

Journal of Biological Chemistry

151

175

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“…Decades of biophysical study have provided a solid groundwork for this project. Crystal structures of photosystem II [1,2] (PSII) have revealed the location of many important components such as chlorophylls and the oxygen-evolving center (OEC) while spectroscopy such as EXAFS [3][4][5][6][7], EPR [8][9][10][11][12], and IR [13,14] have allowed the study of reactive intermediates, the composition of the OEC and the protein ligation of the metal centers. Unfortunately, while we now have a much better structural and mechanistic basis for PSII, we still are some way from the goal of a molecular mechanistic understanding of water oxidation.…”

Section: Introductionmentioning

confidence: 99%

Functional models for the oxygen-evolving complex of photosystem II

Cady

Crabtree

Brudvig

2008

Coordination Chemistry Reviews

388

255

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In the last ten years, a number of advances have been made in the study of the oxygen-evolving complex (OEC) of photosystem II (PSII). Along with this new understanding of the natural system has come rapid advance in chemical models of this system. The advance of PSII model chemistry is seen most strikingly in the area of functional models where the few known systems available when this topic was last reviewed has grown into two families of model systems. In concert with this work, numerous mechanistic proposals for photosynthetic water oxidation have been proposed. Here, we review the recent efforts in functional model chemistry of the oxygen-evolving complex of photosystem II.

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“…The conflicting results in the literature concerning the S 2 → S 3 transition, some of which support and some of which disagree with Mn oxidation occurring during this transition, have led to two different types of proposed O 2 evolution mechanisms, with one type 8,[10][11][12]15,16 incorporating the oxidation of ligand or substrate in the S 3 state, and the other type 9,13,54 invoking Mn oxidation during the S 2 → S 3 transition. As expected, fundamental differences in the chemistry of O-O bond formation and O 2 evolution exist between the two types of mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Absence of Mn-Centered Oxidation in the S₂→ S₃Transition: Implications for the Mechanism of Photosynthetic Water Oxidation

et al. 2001

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A key question for the understanding of photosynthetic water oxidation is whether the four oxidizing equivalents necessary to oxidize water to dioxygen are accumulated on the four Mn ions of the oxygen-evolving complex (OEC), or whether some ligand-centered oxidations take place before the formation and release of dioxygen during the S 3 → [S 4 ] → S 0 transition. Progress in instrumentation and flash sample preparation allowed us to apply Mn Kβ X-ray emission spectroscopy (Kβ XES) to this problem for the first time. The Kβ XES results, in combination with Mn X-ray absorption near-edge structure (XANES) and electron paramagnetic resonance (EPR) data obtained from the same set of samples, show that the S 2 → S 3 transition, in contrast to the S 0 → S 1 and S 1 → S 2 transitions, does not involve a Mn-centered oxidation. On the basis of new structural data from the S 3 -state, manganese μ-oxo bridge radical formation is proposed for the S 2 → S 3 transition, and three possible mechanisms for the O-O bond formation are presented.

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X-ray spectroscopy-based structure of the Mn cluster and mechanism of photosynthetic oxygen evolution

Cited by 191 publications

References 101 publications

Biosynthetic Ca2+/Sr2+ Exchange in the Photosystem II Oxygen-evolving Enzyme of Thermosynechococcus elongatus

Biosynthetic Ca2+/Sr2+ Exchange in the Photosystem II Oxygen-evolving Enzyme of Thermosynechococcus elongatus

Functional models for the oxygen-evolving complex of photosystem II

Absence of Mn-Centered Oxidation in the S₂→ S₃Transition: Implications for the Mechanism of Photosynthetic Water Oxidation

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X-ray spectroscopy-based structure of the Mn cluster and mechanism of photosynthetic oxygen evolution

Cited by 191 publications

References 101 publications

Biosynthetic Ca2+/Sr2+ Exchange in the Photosystem II Oxygen-evolving Enzyme of Thermosynechococcus elongatus

Biosynthetic Ca2+/Sr2+ Exchange in the Photosystem II Oxygen-evolving Enzyme of Thermosynechococcus elongatus

Functional models for the oxygen-evolving complex of photosystem II

Absence of Mn-Centered Oxidation in the S2→ S3Transition: Implications for the Mechanism of Photosynthetic Water Oxidation

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Absence of Mn-Centered Oxidation in the S₂→ S₃Transition: Implications for the Mechanism of Photosynthetic Water Oxidation