Localized Electronic Structure of Nitrogenase FeMoco Revealed by Selenium K-Edge High Resolution X-ray Absorption Spectroscopy

Henthorn, Justin T.; Arias, Renee J.; Koroidov, Sergey; Kröll, Thomas; Sokaras, Dimosthenis; Bergmann, Uwe; Rees, Douglas C; DeBeer, Serena

doi:10.1021/jacs.9b06988

Cited by 59 publications

(119 citation statements)

References 73 publications

(113 reference statements)

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“… 35 A Mo(III) oxidation state was discovered in FeMoco via Mo X-ray absorption spectroscopy (XAS) and X-ray magnetic circular dichroism experiments and theoretical calculations. 36 − 38 A 3Fe(II)4Fe(III) oxidation state is suggested by SpReAD 33 and Se XAS 39 experiments, while theoretical calculations suggest more delocalization of electrons. 32 , 34 …”

Section: Introductionmentioning

confidence: 98%

Quantum Mechanics/Molecular Mechanics Study of Resting-State Vanadium Nitrogenase: Molecular and Electronic Structure of the Iron–Vanadium Cofactor

Benediktsson

Björnsson

2020

Inorg. Chem.

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The nitrogenase enzymes are responsible for all biological nitrogen reduction. How this is accomplished at the atomic level, however, has still not been established. The molybdenum-dependent nitrogenase has been extensively studied and is the most active catalyst for dinitrogen reduction of the nitrogenase enzymes. The vanadium-dependent form, on the other hand, displays different reactivity, being capable of CO and CO 2 reduction to hydrocarbons. Only recently did a crystal structure of the VFe protein of vanadium nitrogenase become available, paving the way for detailed theoretical studies of the iron–vanadium cofactor (FeVco) within the protein matrix. The crystal structure revealed a bridging 4-atom ligand between two Fe atoms, proposed to be either a CO 3 2– or NO 3 – ligand. Using a quantum mechanics/molecular mechanics model of the VFe protein, starting from the 1.35 Å crystal structure, we have systematically explored multiple computational models for FeVco, considering either a CO 3 2– or NO 3 – ligand, three different redox states, and multiple broken-symmetry states. We find that only a [VFe 7 S 8 C(CO 3 )] 2– model for FeVco reproduces the crystal structure of FeVco well, as seen in a comparison of the Fe–Fe and V–Fe distances in the computed models. Furthermore, a broken-symmetry solution with Fe2, Fe3, and Fe5 spin-down (BS7-235) is energetically preferred. The electronic structure of the [VFe 7 S 8 C(CO 3 )] 2– BS7-235 model is compared to our [MoFe 7 S 9 C] − BS7-235 model of FeMoco via localized orbital analysis and is discussed in terms of local oxidation states and different degrees of delocalization. As previously found from Fe X-ray absorption spectroscopy studies, the Fe part of FeVco is reduced compared to FeMoco, and the calculations reveal Fe5 as locally ferrous. This suggests resting-state FeVco to be analogous to an unprotonated E 1 state of FeMoco. Furthermore, V–Fe interactions in FeVco are not as strong compared to Mo–Fe interactions in FeMoco. These clear differences in the electronic structures of otherwise similar cofactors suggest an explanation for distinct differences in reactivity.

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Section: Introductionmentioning

confidence: 98%

Quantum Mechanics/Molecular Mechanics Study of Resting-State Vanadium Nitrogenase: Molecular and Electronic Structure of the Iron–Vanadium Cofactor

Benediktsson

Björnsson

2020

Inorg. Chem.

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“…The data from the “edge” analysis was used to visualize selenium within the nitrogenase cofactor. This technique confirmed that the selenium was exchanged for a sulfur in FeMoco [ 146 ].…”

Section: Selenium In Physics Surfaces and Nanoscience With Regarmentioning

confidence: 60%

Discussions of Fluorescence in Selenium Chemistry: Recently Reported Probes, Particles, and a Clearer Biological Knowledge

et al. 2021

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In this review from literature appearing over about the past 5 years, we focus on selected selenide reports and related chemistry; we aimed for a digestible, relevant, review intended to be usefully interconnected within the realm of fluorescence and selenium chemistry. Tellurium is mentioned where relevant. Topics include selenium in physics and surfaces, nanoscience, sensing and fluorescence, quantum dots and nanoparticles, Au and oxide nanoparticles quantum dot based, coatings and catalyst poisons, thin film, and aspects of solar energy conversion. Chemosensing is covered, whether small molecule or nanoparticle based, relating to metal ion analytes, H2S, as well as analyte sulfane (biothiols—including glutathione). We cover recent reports of probing and fluorescence when they deal with redox biology aspects. Selenium in therapeutics, medicinal chemistry and skeleton cores is covered. Selenium serves as a constituent for some small molecule sensors and probes. Typically, the selenium is part of the reactive, or active site of the probe; in other cases, it is featured as the analyte, either as a reduced or oxidized form of selenium. Free radicals and ROS are also mentioned; aggregation strategies are treated in some places. Also, the relationship between reduced selenium and oxidized selenium is developed.

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“…[28] Thea dditional contribution of our system is the correlation between structure and chemical reactivity with the relevant substrate,N 2 O. Asimilar correlation between substrate activation and localization of frontier MO density has recently emerged to describe the octanuclear FeMo-cofactor of nitrogenase. [29] In our system, no visual changes are observed unless all three reaction components (1,C oCp 2 ,a nd N 2 O) are present. Because complex 1 is in the 4Cu I :1S 2À redox state,i ti su nlikely that reactivity initiates with reduction of 1 by CoCp 2 .Instead, we favor asequence where the p-accepting molecule N 2 Ob inds to 1,likely along the Cu1 À Cu2 edge,thus raising the reduction potential such that CoCp 2 can donate to the newly introduced electron holes of 1·N 2 O.…”

Section: Zuschriftenmentioning

confidence: 62%

“…The additional contribution of our system is the correlation between structure and chemical reactivity with the relevant substrate, N 2 O. A similar correlation between substrate activation and localization of frontier MO density has recently emerged to describe the octanuclear FeMo‐cofactor of nitrogenase . In our system, no visual changes are observed unless all three reaction components ( 1 , CoCp 2 , and N 2 O) are present.…”

Section: Figurementioning

confidence: 99%

N₂O Reductase Activity of a [Cu₄S] Cluster in the 4Cu^I Redox State Modulated by Hydrogen Bond Donors and Proton Relays in the Secondary Coordination Sphere

et al. 2019

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The model complex [Cu4(μ4‐S)(dppa)4]2+ (1, dppa=μ2‐(Ph2P)2NH) has N2O reductase activity in methanol solvent, mediating 2 H+/2 e− reduction of N2O to N2+H2O in the presence of an exogenous electron donor (CoCp2). A stoichiometric product with two deprotonated dppa ligands was characterized, indicating a key role of second‐sphere N−H residues as proton donors during N2O reduction. The activity of 1 towards N2O was suppressed in solvents that are unable to provide hydrogen bonding to the second‐sphere N−H groups. Structural and computational data indicate that second‐sphere hydrogen bonding induces structural distortion of the [Cu4S] active site, accessing a strained geometry with enhanced reactivity due to localization of electron density along a dicopper edge site. The behavior of 1 mimics aspects of the CuZ catalytic site of nitrous oxide reductase: activity in the 4CuI:1S redox state, use of a second‐sphere proton donor, and reactivity dependence on both primary and secondary sphere effects.

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Localized Electronic Structure of Nitrogenase FeMoco Revealed by Selenium K-Edge High Resolution X-ray Absorption Spectroscopy

Cited by 59 publications

References 73 publications

Quantum Mechanics/Molecular Mechanics Study of Resting-State Vanadium Nitrogenase: Molecular and Electronic Structure of the Iron–Vanadium Cofactor

Quantum Mechanics/Molecular Mechanics Study of Resting-State Vanadium Nitrogenase: Molecular and Electronic Structure of the Iron–Vanadium Cofactor

Discussions of Fluorescence in Selenium Chemistry: Recently Reported Probes, Particles, and a Clearer Biological Knowledge

N₂O Reductase Activity of a [Cu₄S] Cluster in the 4Cu^I Redox State Modulated by Hydrogen Bond Donors and Proton Relays in the Secondary Coordination Sphere

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Localized Electronic Structure of Nitrogenase FeMoco Revealed by Selenium K-Edge High Resolution X-ray Absorption Spectroscopy

Cited by 59 publications

References 73 publications

Quantum Mechanics/Molecular Mechanics Study of Resting-State Vanadium Nitrogenase: Molecular and Electronic Structure of the Iron–Vanadium Cofactor

Quantum Mechanics/Molecular Mechanics Study of Resting-State Vanadium Nitrogenase: Molecular and Electronic Structure of the Iron–Vanadium Cofactor

Discussions of Fluorescence in Selenium Chemistry: Recently Reported Probes, Particles, and a Clearer Biological Knowledge

N2O Reductase Activity of a [Cu4S] Cluster in the 4CuI Redox State Modulated by Hydrogen Bond Donors and Proton Relays in the Secondary Coordination Sphere

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N₂O Reductase Activity of a [Cu₄S] Cluster in the 4Cu^I Redox State Modulated by Hydrogen Bond Donors and Proton Relays in the Secondary Coordination Sphere