Litcius/Paper detail

Metalloradical-driven enzymatic CO2 reduction by a dynamic Ni–Fe cluster

Yudhajeet Basak, Christian Lorent, Jae‐Hun Jeoung, Ingo Zebger, Holger Dobbek

2025Nature Catalysis20 citationsDOIOpen Access PDF

Abstract

Abstract Carbon monoxide dehydrogenases (CODHs) selectively catalyse the reversible reduction of CO 2 to CO and water. The catalytic centre of CODHs contains a unique [NiFe 4 (OH)(µ 3 -S) 4 ] cluster whose role in activating and converting CO 2 is poorly understood. Here we reveal the structures of all catalytically relevant oxidation states with and without substrates and products bound. We show that the Ni–Fe cluster combines a rigid Fe–S core with a dynamic Ni(I/II)–Fe(II) dyad. The redox-active element is the Ni ion, cycling between square-planar Ni(II) and T-shaped Ni(I) states with metalloradical character, the latter serving as the nucleophile for CO 2 activation. The Fe(II) ion switches between two positions, the one preceding CO 2 activation is close to Ni(I) with a potential Ni(I)–Fe(II) interaction and the other binds the substrates CO 2 and water. We demonstrate how the Ni–Fe cluster creates an efficient CO 2 reduction catalyst and provides a blueprint for the design of novel catalysts based on abundant transition metals.

Topics & Concepts

Reduction (mathematics)Cluster (spacecraft)EnzymeChemistryComputer scienceMathematicsBiochemistryGeometryProgramming languageCO2 Reduction Techniques and CatalystsMetal-Catalyzed Oxygenation MechanismsMetalloenzymes and iron-sulfur proteins