Understanding the Electronic Structure Basis for N<sub>2</sub> Binding to FeMoco: A Systematic Quantum Mechanics/Molecular Mechanics Investigation

Pang, Yunjie; Björnsson, Ragnar

doi:10.1021/acs.inorgchem.2c03967

Cited by 12 publications

(26 citation statements)

References 129 publications

(347 reference statements)

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“…This seems to be the definition used by Bjornsson and coworkers in their first study 52 and called single-step N 2 binding energy in their second study. 53 In all three cases, a negative binding energy indicates a favourable binding.…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

N₂binding to the E₀–E₄states of nitrogenase

Jiang

Ryde

2023

Dalton Trans.

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Section: Methodsmentioning

confidence: 99%

“…This seems to be the definition used by Siegbahn 60,61 and by Bjornsson and coworkers in their latest study. 53…”

Section: Methodsmentioning

confidence: 99%

N₂binding to the E₀–E₄states of nitrogenase

Jiang

Ryde

2023

Dalton Trans.

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“…Both all-electron and ECP calculations (using the Stuttgart–Dresden ECP , ) were performed for each functional. The impact of a relativistic ECP on the predicted metal–nucleic acid geometries was investigated for a subset of 10 complexes containing a heavy metal with Z > 36 using one of our recommended DFT methods (MN15) in combination with ZORA, a robust relativistic ECP identified to consistently describe molecular properties, and has been applied in QM/MM studies of metalloenzymes . There are minimal differences in the inner coordination geometries evaluated with a relativistic and non-relativistic ECP (≤0.8% inner-shell MPE; Table S3).…”

Section: Computational Methodologymentioning

confidence: 99%

Assessment of Density Functional Theory Methods for the Structural Prediction of Transition and Post-Transition Metal–Nucleic Acid Complexes

Boychuk

Wetmore

2023

J. Chem. Theory Comput.

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Understanding the structure of metal−nucleic acid systems is important for many applications such as the design of new pharmaceuticals, metal detection platforms, and nanomaterials. Herein, we explore the ability of 20 density functional theory (DFT) functionals to reproduce the crystal structure geometry of transition and post-transition metal−nucleic acid complexes identified in the Protein Data Bank and Cambridge Structural Database. The environmental extremes of the gas phase and implicit water were considered, and analysis focused on the global and inner coordination geometry, including the coordination distances. Although gas-phase calculations were unable to describe the structure of 12 out of the 53 complexes in our test set regardless of the DFT functional considered, accounting for the broader environment through implicit solvation or constraining the model truncation points to crystallographic coordinates generally afforded agreement with the experimental structure, suggesting that functional performance for these systems is likely due to the models rather than the methods. For the remaining 41 complexes, our results show that the reliability of functionals depends on the metal identity, with the magnitude of error varying across the periodic table. Furthermore, minimal changes in the geometries of these metal−nucleic acid complexes occur upon use of the Stuttgart−Dresden effective core potential and/or inclusion of an implicit water environment. The overall top three performing functionals are ωB97X-V, ωB97X-D3(BJ), and MN15, which reliably describe the structure of a broad range of metal−nucleic acid systems. Other suitable functionals include MN15-L, which is a cheaper alternative to MN15, and PBEh-3c, which is commonly used in QM/MM calculations of biomolecules. In fact, these five methods were the only functionals tested to reproduce the coordination sphere of Cu 2+ -containing complexes. For metal−nucleic acid systems that do not contain Cu 2+ , ωB97X and ωB97X-D are also suitable choices. These top-performing methods can be utilized in future investigations of diverse metal−nucleic acid complexes of relevance to biology and material science.

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“…4a and 4b), with a corresponding adsorption energy of -0.33 eV at 300 K (-0.40 eV at 0 K), and some small activation is present by bond elongation ∼0.05 Å (Figure 4c). Additionally, for the µ 1 − η 1 end-on mode of the E 4 state, the exposed Fe site with double hydrides for the 1S E 4 configuration experiences an octahedral coordination field, which was proven to facilitate the doubly generated d xz and d yz orbitals of Fe that favors backbonding in the end-on N 2 ligand 82 .…”

Section: Activation Of N 2 and H 2 Releasementioning

confidence: 99%

How Thermal Fluctuations Influence the Function of the FeMo-cofactor in Nitrogenase Enzymes

Li,

et al. 2023

Preprint

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The catalytic mechanism of N2 fixation by nitrogenase remains unresolved in how the strong N≡N bond is activated and why the reductive elimination of H2 is required. Here we use Density Functional Theory and physiologically relevant thermal simulations to elucidate the mechanism of the complete nitrogenase catalytic cycle. Over the accumulation of four reducing equivalents we find that protons and electrons transfer to the FeMo-cofactor to weaken and break its bridge Fe-S bond, leading to temporary H2S formation that exposes the Fe sites to weakly bind N2. Remarkably, we find that subsequent H2 formation is responsible for chemical activation to an N=N double bond accompanied by a low barrier for H2 release. We emphasize that finite temperature effects smooth out mechanistic differences between DFT functionals observed at 0 K, thus leading to a consistent understanding as to why H2 formation is an obligatory step in N2 adsorption and activation.

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Understanding the Electronic Structure Basis for N₂ Binding to FeMoco: A Systematic Quantum Mechanics/Molecular Mechanics Investigation

Cited by 12 publications

References 129 publications

N₂binding to the E₀–E₄states of nitrogenase

N₂binding to the E₀–E₄states of nitrogenase

Assessment of Density Functional Theory Methods for the Structural Prediction of Transition and Post-Transition Metal–Nucleic Acid Complexes

How Thermal Fluctuations Influence the Function of the FeMo-cofactor in Nitrogenase Enzymes

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Understanding the Electronic Structure Basis for N2 Binding to FeMoco: A Systematic Quantum Mechanics/Molecular Mechanics Investigation

Cited by 12 publications

References 129 publications

N2binding to the E0–E4states of nitrogenase

N2binding to the E0–E4states of nitrogenase

Assessment of Density Functional Theory Methods for the Structural Prediction of Transition and Post-Transition Metal–Nucleic Acid Complexes

How Thermal Fluctuations Influence the Function of the FeMo-cofactor in Nitrogenase Enzymes

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Understanding the Electronic Structure Basis for N₂ Binding to FeMoco: A Systematic Quantum Mechanics/Molecular Mechanics Investigation

N₂binding to the E₀–E₄states of nitrogenase

N₂binding to the E₀–E₄states of nitrogenase