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<sup>13</sup>C ENDOR Characterization of the Central Carbon within the Nitrogenase Catalytic Cofactor Indicates That the CFe<sub>6</sub>Core Is a Stabilizing “Heart of Steel”

Dmitriy Lukoyanov, Zhi‐Yong Yang, Ana Pérez‐González, Simone Raugei, Dennis R. Dean, Lance C. Seefeldt, Brian M. Hoffman

2022Journal of the American Chemical Society23 citationsDOIOpen Access PDF

Abstract

Substrates and inhibitors of Mo-dependent nitrogenase bind and react at Fe ions of the active-site FeMo-cofactor [7Fe–9S–C–Mo–homocitrate] contained within the MoFe protein α-subunit. The cofactor contains a CFe6 core, a carbon centered within a trigonal prism of six Fe, whose role in catalysis is unknown. Targeted 13C labeling of the carbon enables electron-nuclear double resonance (ENDOR) spectroscopy to sensitively monitor the electronic properties of the Fe–C bonds and the spin-coupling scheme adopted by the FeMo-cofactor metal ions. This report compares 13CFe6 ENDOR measurements for (i) the wild-type protein resting state (E0; α-Val70) to those of (ii) α-Ile70, (iii) α-Ala70-substituted proteins; (iv) crystallographically characterized CO-inhibited “hi-CO” state; (v) E4(4H) Janus intermediate, activated for N2 binding/reduction by accumulation of 4[e–/H+]; (vi) E4(2H)* state containing a doubly reduced FeMo-cofactor without Fe-bound substrates; and (vii) propargyl alcohol reduction intermediate having allyl alcohol bound as a ferracycle to FeMo-cofactor Fe6. All states examined, both S = 1/2 and 3/2 exhibited near-zero 13C isotropic hyperfine coupling constants, Ca = [−1.3 ↔ +2.7] MHz. Density functional theory computations and natural bond orbital analysis of the Fe−C bonds show that this occurs because a (3 spin-up/3 spin-down) spin-exchange configuration of CFe6 Fe-ion spins produces cancellation of large spin-transfers to carbon in each Fe–C bond. Previous X-ray diffraction and DFT both indicate that trigonal-prismatic geometry around carbon is maintained with high precision in all these states. The persistent structure and Fe–C bonding of the CFe6 core indicate that it does not provide a functionally dynamic (hemilabile) “beating heart”─instead it acts as “a heart of steel”, stabilizing the structure of the FeMo-cofactor-active site during nitrogenase catalysis.

Topics & Concepts

ChemistryCrystallographyNitrogenaseSpin statesCofactorResonance (particle physics)StereochemistryInorganic chemistryAtomic physicsNitrogenPhysicsNitrogen fixationBiochemistryOrganic chemistryEnzymeMetalloenzymes and iron-sulfur proteinsOrganometallic Complex Synthesis and CatalysisAmmonia Synthesis and Nitrogen Reduction
<sup>13</sup>C ENDOR Characterization of the Central Carbon within the Nitrogenase Catalytic Cofactor Indicates That the CFe<sub>6</sub>Core Is a Stabilizing “Heart of Steel” | Litcius