The One-Electron Reduced Active-Site FeFe-Cofactor of Fe-Nitrogenase Contains a Hydride Bound to a Formally Oxidized Metal-Ion Core

Lukoyanov, Dmitriy; Harris, Derek F.; Yang, Zhi Yong; Pérez-González, Ana; Dean, Dennis R.; Seefeldt, Lance C.; Hoffman, Brian M.

doi:10.1021/acs.inorgchem.2c00180

Cited by 12 publications

(20 citation statements)

References 30 publications

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“…A way to sort out these problems is to study simpler states with a lower number of possibilities. Most computational , and experimental , studies agree that the E 1 state involves the protonation of the S2B μ 2 -bridging sulfide ligand of the FeMo cluster (but a recent experimental study of Fe-nitrogenase instead suggested a hydride ion).…”

Section: Introductionmentioning

confidence: 99%

QM/MM Study of Partial Dissociation of S2B for the E₂ Intermediate of Nitrogenase

2022

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Nitrogenase is the only enzyme that can cleave the triple bond in N 2 , making nitrogen available for all lifeforms. Previous computational studies have given widely diverging results regarding the reaction mechanism of the enzyme. For example, some recent studies have suggested that one of the μ 2 -bridging sulfide ligands (S2B) may dissociate from one of the Fe ions when protonated in the doubly reduced and protonated E 2 state, whereas other studies indicated that such half-dissociated states are unfavorable. We have examined how the relative energies of 26 structures of the E 2 state depend on details of combined quantum mechanical and molecular mechanical (QM/MM) calculations. We show that the selection of the broken-symmetry state, the basis set, relativistic effects, the size of the QM system, relaxation of the surroundings, and the conformations of the bound protons may affect the relative energies of the various structures by up to 12, 22, 9, 20, 37, and 33 kJ/mol, respectively. However, they do not change the preferred type of structures. On the other hand, the choice of the DFT functional strongly affects the preferences. The hybrid B3LYP functional strongly prefers doubly protonation of the central carbide ion, but such a structure is not consistent with experimental EPR data. Other functionals suggest structures with a hydride ion, in agreement with the experiments, and show that the ion bridges between Fe2 and Fe6. Moreover, there are two structures of the same type that are degenerate within 1−5 kJ/mol, in agreement with the observation of two EPR signals. However, the pure generalized gradient approximation (GGA) functional TPSS favors structures with a protonated S2B also bridging Fe2 and Fe6, whereas r 2 SCAN (meta-GGA) and TPSSh (hybrid) prefer structures with S2B dissociated from Fe2 (but remaining bound to Fe6). The energy difference between the two types of structure is so small (7−18 kJ/mol) that both types need to be considered in future investigations of the mechanism of nitrogenase.

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Section: Introductionmentioning

confidence: 99%

QM/MM Study of Partial Dissociation of S2B for the E₂ Intermediate of Nitrogenase

2022

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“…The results are in line with a recent X-ray study, 9 but in strong disagreement with a recent EPR study. 10 The accuracy of the present calculations has been benchmarked on a set of redox enzymes indicating an accuracy of about 3 kcal mol À1 , also for the redox transitions, for all of them. 12 Also, the results for the N 2 activation in E 4 is in perfect agreement with observations by EPR.…”

Section: Discussionmentioning

confidence: 89%

“…Recent experiments have shown that the ground state for the cofactor of V-nitrogenase has the redox state (3Fe(II), 4Fe(III), V(III)), which is an S = 0 (or integer spin non-Kramers) state. 18 To repeat, the EPR study led to a suggested structure with a bridging hydride for E 1 , 10 while the X-ray study led to a suggested protonated belt sulfide. 9 Therefore, the suggested oxidation states were quite different with (2Fe(II), 5Fe(III), Mo(III)) for the EPR study and (4Fe(II), 3Fe(III), Mo(III)) for the X-ray study.…”

Section: Resultsmentioning

confidence: 98%

“…16 The cluster models for Mo-nitrogenase were taken from the previous studies. 6,10 For Mo-nitrogenase, besides the ligands of the cofactor, homocitrate, Cys275 and His442, the second sphere amino acids His195, Arg96, Arg359, Glu380, Phe381 and Gln191, were included in the model. For V-nitrogenase, besides the ligands of the cofactor, homocitrate, Cys257, His423, and a carbonate, the second sphere amino acids Gln176, Lys83, His180, Thr335, Arg339, Lys361 and Phe362 were included in the model.…”

Section: Methodsmentioning

confidence: 99%

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Can the E₁state in nitrogenase tell if there is an activation process prior to catalysis?

Siegbahn

2023

Phys. Chem. Chem. Phys.

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“…The experiments concerned studies of a state obtained after only one reduction generally termed the E 1 state. In one study using X‐ray spectroscopy, it was concluded that there is a reduction of one of the irons and no hydride is present [34], while in an EPR study it was concluded that there should be a hydride present, implying that one of the irons is instead oxidized [35]. At present, model calculations suggest a hydride in the E 1 state, but no hydride in the A 1 state.…”

Section: Discussionmentioning

confidence: 99%

Computational modeling of redox enzymes

Siegbahn

2022

FEBS Letters

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A computational methodology is briefly described, which appears to be able to accurately describe the mechanisms of redox active enzymes. The method is built on hybrid density functional theory where the inclusion of a fraction of exact exchange is critical. Two examples of where the methodology has been applied are described. The first example is the mechanism for water oxidation in photosystem II, and the second one is the mechanism for N2 activation by nitrogenase. The mechanism for PSII has obtained very strong support from subsequent experiments. For nitrogenase, the calculations suggest that there should be an activation process prior to catalysis, which is still strongly debated.

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The One-Electron Reduced Active-Site FeFe-Cofactor of Fe-Nitrogenase Contains a Hydride Bound to a Formally Oxidized Metal-Ion Core

Cited by 12 publications

References 30 publications

QM/MM Study of Partial Dissociation of S2B for the E₂ Intermediate of Nitrogenase

QM/MM Study of Partial Dissociation of S2B for the E₂ Intermediate of Nitrogenase

Can the E₁state in nitrogenase tell if there is an activation process prior to catalysis?

Computational modeling of redox enzymes

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The One-Electron Reduced Active-Site FeFe-Cofactor of Fe-Nitrogenase Contains a Hydride Bound to a Formally Oxidized Metal-Ion Core

Cited by 12 publications

References 30 publications

QM/MM Study of Partial Dissociation of S2B for the E2 Intermediate of Nitrogenase

QM/MM Study of Partial Dissociation of S2B for the E2 Intermediate of Nitrogenase

Can the E1state in nitrogenase tell if there is an activation process prior to catalysis?

Computational modeling of redox enzymes

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Product

Resources

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QM/MM Study of Partial Dissociation of S2B for the E₂ Intermediate of Nitrogenase

QM/MM Study of Partial Dissociation of S2B for the E₂ Intermediate of Nitrogenase

Can the E₁state in nitrogenase tell if there is an activation process prior to catalysis?