A conformational equilibrium in the nitrogenase MoFe protein with an α-V70I amino acid substitution illuminates the mechanism of H2 formation.

Study of α-V70I-substituted nitrogenase MoFe protein identified Fe6 of FeMo-cofactor (Fe7S9MoC-homocitrate) as a critical N2 binding/reduction site. Freeze-trapping this enzyme during Ar turnover captured the key catalytic intermediate in high occupancy, denoted E4(4H), which has accumulated 4[e-/H+] as two bridging hydrides, Fe2-H-Fe6 and Fe3-H-Fe7, and protons bound to two sulfurs. E4(4H) is poised to bind/reduce N2 as driven by mechanistically-coupled H2 reductive-elimination of the hydrides. This process must compete with ongoing hydride protonation (HP), which releases H2 as the enzyme relaxes to state E2(2H), containing 2[e-/H+] as a hydride and sulfur-bound proton; accumulation of E4(4H) in α-V70I is enhanced by HP suppression. EPR and 95Mo ENDOR spectroscopies now show that resting-state α-V70I enzyme exists in two conformational states, both in solution and as crystallized, one with wild type (WT)-like FeMo-co and one with perturbed FeMo-co. These reflect two conformations of the Ile residue, as visualized in a reanalysis of the X-ray diffraction data of α-V70I and confirmed by computations. EPR measurements show delivery of 2[e-/H+] to the E0 state of the WT MoFe protein and to both α-V70I conformations generating E2(2H) that contains the Fe3-H-Fe7 bridging hydride; accumulation of another 2[e-/H+] generates E4(4H) with Fe2-H-Fe6 as the second hydride. E4(4H) in WT enzyme and a minority α-V70I E4(4H) conformation as visualized by QM/MM computations relax to resting-state through two HP steps that reverse the formation process: HP of Fe2-H-Fe6 followed by slower HP of Fe3-H-Fe7, which leads to transient accumulation of E2(2H) containing Fe3-H-Fe7. In the dominant α-V70I E4(4H) conformation, HP of Fe2-H-Fe6 is passively suppressed by the positioning of the Ile sidechain; slow HP of Fe3-H-Fe7 occurs first and the resulting E2(2H) contains Fe2-H-Fe6. It is this HP suppression in E4(4H) that enables α-V70I MoFe to accumulate E4(4H) in high occupancy. In addition, HP suppression in α-V70I E4(4H) kinetically unmasks hydride reductive-elimination without N2-binding, a process that is precluded in WT enzyme.

Citation

Dmitriy A Lukoyanov, Zhi-Yong Yang, Krista Shisler, John W Peters, Simone Raugei, Dennis R Dean, Lance C Seefeldt, Brian M Hoffman. A conformational equilibrium in the nitrogenase MoFe protein with an α-V70I amino acid substitution illuminates the mechanism of H2 formation. Faraday discussions. 2023 Jul 19;243(0):231-252

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PMID: 37021412

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