Use of Substrate Analogues and X-ray spectroscopy Reveals an all Ferrous C-Cluster in CO Dehydrogenase
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Abstract
Carbon monoxide (CO) dehydrogenase (CODH) plays a key role in prokaryotic one-carbon metabolism by detoxifying CO and by driving CO 2 reduction coupled to ATP production in the Wood-Ljungdahl Pathway. Here we focus on a Ni-Fe CODH (CODH-II), with an active site C-cluster, which is a [NiFe 4 S 4 ] cluster arranged as a [NiFe 3 S 4 ] subcluster with an additional, unique pendant Fe, e.g., [Fe 3 S 4 -Fe u ]. It catalyzes the reversible reduction of CO 2 to CO without the requirement for an overpotential and with insignificant proton reduction. The redox states associated with catalysis are defined as C red1 and C red2 . Despite crystal structures with near 1.0 A resolution, it has been a long-standing question where the electrons in these catalytically relevant redox states are stored within the C cluster. Using X-ray absorption spectroscopy (XAS), EPR, and substrate-analogue binding measurements, we clarify the electronic structure of these catalytically active states in addition to the resting state of CODH. We rule out recent postulates that catalysis involves a Ni 0 state, a metal-metal bond, or a hydride intermediate. We reveal that CODH rests in the diamagnetic C ox form, which contains Ni 2+ and an oxidized [Fe 3 S 4 -Fe u ] 2+ cluster. Then, the C-cluster undergoes reductive activation on Fe to form paramagnetic Cred1, which binds CO and analog cyanide. Generation of C red2 , which binds CO 2 and its analog cyanate, involves two sequential valence-localized electron transfers, generating Ni 1+ and then [Fe 3 S 4 -Fe u ], forming an all-ferrous cluster. Our work sheds light on how CODH avoids the thermodynamically unfavorable generation of a CO 2 radical anion intermediate formed in other catalytic systems by stabilizing electron density in the heterometallic C-cluster. We also highlight the importance of high-resolution XAS and use of substrate analogs to reveal the sequential, valence-localized electron transfers that occur during redox-dependent CODH catalysis. TOC Figure
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- europepmc
- last seen: 2026-05-20T01:45:00.602351+00:00
- unpaywall
- last seen: 2026-05-28T02:00:01.590549+00:00
License: CC-BY-NC-ND-4.0