Critical computational analysis illuminates the reductive-elimination mechanism that activates nitrogenase for N
            <sub>2</sub>
            reduction

Raugei, Simone; Seefeldt, Lance C.; Hoffman, Brian M.

doi:10.1073/pnas.1810211115

Cited by 112 publications

(251 citation statements)

References 68 publications

(132 reference statements)

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“…This energetic analysis suggests that models j-o are the most viable models for the E 4 state (at the TPSSh-QM/MM level). Open sulde-bridge models like j-o were not considered in the study by Cao et al 27 but some open-sulde bridge models were discussed by Raugei et al 24 and were found to be similar in energy as model e, which, however, is not in agreement with our results. We attribute this disagreement to different modelling aspects, i.e.…”

Section: A Computational Modelling Of the E 4 Statecontrasting

confidence: 97%

“…All models that we consider in this study were structurally optimized at the same QM/MM level of theory that we have previously used to describe the resting state E 0 and we considered multiple broken-symmetry states for each model. As recently discussed by Raugei et al, 24 the protein environment and the quality of the computational model can make a surprisingly large difference regarding the relative stability of an E 4 isomer. Raugei et al demonstrated e.g.…”

Section: A Computational Modelling Of the E 4 Statementioning

confidence: 95%

“…Mutation studies have previously implicated the Fe 2 -Fe 3 -Fe 6 -Fe 7 face as a likely binding site for dinitrogen as no dinitrogen reduction is observed when the residue a-70 Val is mutated into the bulkier a-70 Ile . 22 Recent joint experimentalcomputational studies have proposed E 4 models featuring bridging hydrides [23][24][25] (the favoured model features bridging hydrides between Fe 3 -Fe 7 and Fe 2 -Fe 6 ) while other computational studies have suggested mixed bridging/terminal hydride models 26,27 or even, surprisingly, structures featuring a protonated carbide with/without bridging hydrides. [28][29][30][31] Additionally, recent crystal structures of a CO-bound form 32 of MoFe protein (CO being an inhibitor) and an XH-ligand-bound (X ¼ N or O) form 33 of VFe protein have emerged, that show CO/XH replacing the Fe 2 -Fe 6 bridging sulde in a bridging binding mode (we recently showed via QM/MM calculations that the XH ligand in the FeVco structure is more consistent with an OH).…”

Section: + H 2 + 16mgadpmentioning

confidence: 99%

“…As some of the models in this study feature structural changes at these Fe ions, it seems possible that such a solution could become more favourable than other BS solutions. To aid in the computational problem involving many models and many BS states at an expensive level of theory, we have restricted ourselves to performing geometry optimizations with the BS-235, BS-247, BS-346, BS-147 solutions to explore the energetics of all models in Fig Models n, m and o were previously discussed as models close in energy to the favoured model e in work by Raugei et al In this study we introduce models l and model o (though a model like o has been discussed by Raugei et al 24 ) as plausible candidates for E 4 as well as models j and k, being similar to models m and n, and model b featuring two terminal sulydryl groups and two bridging hydrides. Model i also has a terminal sulydryl group like l but has a different sulde protonation state.…”

Section: A Computational Modelling Of the E 4 Statementioning

confidence: 99%

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A model for dinitrogen binding in the E₄state of nitrogenase

2019

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Molybdenum nitrogenase is one of the most intriguing metalloenzymes in nature, featuring an exotic ironmolybdenum-sulfur cofactor, FeMoco, whose mode of action remains elusive. In particular, the molecular and electronic structure of the N 2 -binding E 4 state is not known. In this study we present theoretical QM/ MM calculations of new structural models of the E 4 state of molybdenum-dependent nitrogenase and compare to previously suggested models for this enigmatic redox state. We propose two models as possible candidates for the E 4 state. Both models feature two hydrides on the FeMo cofactor, bridging atoms Fe 2 and Fe 6 with a terminal sulfhydryl group on either Fe 2 or Fe 6 (derived from the S2B bridge) and the change in coordination results in local lower-spin electronic structure at Fe 2 and Fe 6 . These structures appear consistent with the bridging hydride proposal put forward from ENDOR studies and are calculated to be lower in energy than other proposed models for E 4 at the TPSSh-QM/MM level of theory. We critically analyze the DFT method dependency in calculations of FeMoco that has resulted in strikingly different proposals for this state. Importantly, dinitrogen binds exothermically to either Fe 2 or Fe 6 in our models, contrary to others, an effect rationalized via the unique ligand field (from the hydrides) at the Fe with an empty coordination site. A low-spin Fe site is proposed as being important to N 2 binding. Furthermore, the geometries of these states suggest a feasible reductive elimination step that could follow, as experiments indicate. Via this step, two electrons are released, reducing the cofactor to yield a distorted 4-coordinate Fe 2 or Fe 6 that partially activates N 2 . We speculate that stabilization of an N 2 -bound Fe(I) at Fe 6 (not found for Fe 2 model) via reductive elimination is a crucial part of N 2 activation in nitrogenases, possibly aided by the apical heterometal ion (Mo or V). By using protons from the sulfhydryl group (to regenerate the sulfide bridge between Fe 2 and Fe 6 ) and the nearby homocitrate hydroxy group, we calculate a plausible route to yield a diazene intermediate. This is found to be more favorable with the Fe 6 -bound model than the Fe 2 -bound model; however, this protonation is uphill in energy, suggesting protonation of N 2 might occur later in the catalytic cycle or via another mechanism. Electronic supplementary information (ESI) available: Further information on all broken-symmetry solutions calculated for all models. Details of the QM/MM model preparation. Spin populations of all models. Localized orbital analysis of selected models. Geometry analysis of E 0 state calculated with different functionals and electronic structure analysis. Cartesian coordinates for the QM regions of all optimized structures available as XYZ les. See

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Section: A Computational Modelling Of the E 4 Statecontrasting

confidence: 97%

Section: A Computational Modelling Of the E 4 Statementioning

confidence: 95%

Section: + H 2 + 16mgadpmentioning

confidence: 99%

Section: A Computational Modelling Of the E 4 Statementioning

confidence: 99%

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A model for dinitrogen binding in the E₄state of nitrogenase

2019

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“…in clusters of Mn atoms in Photosystem II (PSII) or Fe and Mo atoms in nitrogenases. [4][5][6][7] Furthermore, the coordination of small molecules to single metal ions is an important motif in drug design, 8 and the correlations exhibited in the copper oxide layers of cuprate materials play a central role in the phenomenon of high-temperature superconductivity. 9,10 Ab initio modeling has the potential to yield essential insights into these transition metal systems.…”

Section: Introductionmentioning

confidence: 99%

Predicting Ligand-Dissociation Energies of 3d Coordination Complexes with Auxiliary-Field Quantum Monte Carlo

Rudshteyn

Coskun

Weber

et al. 2020

J. Chem. Theory Comput.

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Transition metal complexes are ubiquitous in biology and chemical catalysis, yet they remain difficult to accurately describe with ab initio methods due to the presence of a large degree of dynamic electron correlation, and, in some cases, strong static correlation which results from a manifold of low-lying states. Progress has been hindered by a scarcity of high quality gas-phase experimental data, while exact ab initio predictions are usually computationally unaffordable due to the large size of the relevant complexes.In this work, we present a data set of 34 tetrahedral, square planar, and octahedral 3d metal-containing complexes with gas-phase ligand-dissociation energies that have reported uncertainties of ≤ 2 kcal/mol. We perform all-electron phaseless auxiliaryfield quantum Monte Carlo (ph-AFQMC) calculations utilizing multi-determinant trial wavefunctions selected by a blackbox procedure. We compare the results with those from density functional theory (DFT) with the B3LYP, B97, M06, PBE0, ωB97X-V, and DSD-PBEP86/2013 functionals, and a localized orbital variant of coupled cluster theory with single, double, and perturbative triple excitations (DLPNO-CCSD(T)). We find mean averaged errors of 1.09 ± 0.28 kcal/mol for our best ph-AFQMC method, vs 2.89 kcal/mol for DLPNO-CCSD(T) and 1.57 -3.87 kcal/mol for DFT. We find maximum errors of 2.96 ± 1.71 kcal/mol for our best ph-AFQMC method, vs 9.15 kcal/mol for DLPNO-CCSD(T) and 5.98 -13.69 kcal/mol for DFT. The reasonable performance of a number of DFT functionals is in stark contrast to the much poorer accuracy previously demonstrated for diatomic species, suggesting a moderation in electron correlation due to ligand coordination. However, the unpredictably large errors for a small subset of cases with both DFT and DLPNO-CCSD(T) methods leave cause for concern, especially in light of the unreliability of common multi-reference indicators. In contrast, the robust and, in principle, systematically improvable results of ph-AFQMC for these realistic complexes establish the method as a useful tool for elucidating the electronic structure of transition metal-containing complexes and predicting their gas-phase properties.

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Computational Investigations of the Chemical Mechanism of the Enzyme Nitrogenase

Dance

2020

ChemBioChem

101

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Critical computational analysis illuminates the reductive-elimination mechanism that activates nitrogenase for N ₂ reduction

Cited by 112 publications

References 68 publications

A model for dinitrogen binding in the E₄state of nitrogenase

A model for dinitrogen binding in the E₄state of nitrogenase

Predicting Ligand-Dissociation Energies of 3d Coordination Complexes with Auxiliary-Field Quantum Monte Carlo

Computational Investigations of the Chemical Mechanism of the Enzyme Nitrogenase

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Critical computational analysis illuminates the reductive-elimination mechanism that activates nitrogenase for N 2 reduction

Cited by 112 publications

References 68 publications

A model for dinitrogen binding in the E4state of nitrogenase

A model for dinitrogen binding in the E4state of nitrogenase

Predicting Ligand-Dissociation Energies of 3d Coordination Complexes with Auxiliary-Field Quantum Monte Carlo

Computational Investigations of the Chemical Mechanism of the Enzyme Nitrogenase

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Product

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Critical computational analysis illuminates the reductive-elimination mechanism that activates nitrogenase for N ₂ reduction

A model for dinitrogen binding in the E₄state of nitrogenase

A model for dinitrogen binding in the E₄state of nitrogenase