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Comprehensive structural, infrared spectroscopic and kinetic investigations of the roles of the active-site arginine in bidirectional hydrogen activation by the [NiFe]-hydrogenase 'Hyd-2' from

The active site of [NiFe]-hydrogenases contains a strictly-conserved pendant arginine, the guanidine head group of which is suspended immediately above the Ni and Fe atoms. Replacement of this arginine (R479) in hydrogenase-2 from E. coli results in an enzyme that is isolated with a very tightly-bou...

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Published in:Chemical science (Cambridge) 2023-08, Vol.14 (32), p.8531-8551
Main Authors: Evans, Rhiannon M, Beaton, Stephen E, Rodriguez Macia, Patricia, Pang, Yunjie, Wong, Kin Long, Kertess, Leonie, Myers, William K, Bjornsson, Ragnar, Ash, Philip A, Vincent, Kylie A, Carr, Stephen B, Armstrong, Fraser A
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Summary:The active site of [NiFe]-hydrogenases contains a strictly-conserved pendant arginine, the guanidine head group of which is suspended immediately above the Ni and Fe atoms. Replacement of this arginine (R479) in hydrogenase-2 from E. coli results in an enzyme that is isolated with a very tightly-bound diatomic ligand attached end-on to the Ni and stabilised by hydrogen bonding to the Nζ atom of the pendant lysine and one of the three additional water molecules located in the active site of the variant. The diatomic ligand is bound under oxidising conditions and is removed only after a prolonged period of reduction with H 2 and reduced methyl viologen. Once freed of the diatomic ligand, the R479K variant catalyses both H 2 oxidation and evolution but with greatly decreased rates compared to the native enzyme. Key kinetic characteristics are revealed by protein film electrochemistry: most importantly, a very low activation energy for H 2 oxidation that is not linked to an increased H/D isotope effect. Native electrocatalytic reversibility is retained. The results show that the sluggish kinetics observed for the lysine variant arise most obviously because the advantage of a more favourable low-energy pathway is massively offset by an extremely unfavourable activation entropy. Extensive efforts to establish the identity of the diatomic ligand, the tight binding of which is an unexpected further consequence of replacing the pendant arginine, prove inconclusive. Changing the conserved active-site arginine of [NiFe]-hydrogenases into a lysine greatly lowers the rates of catalytic H 2 activation in each direction and results in the extremely tight binding of a diatomic ligand.
ISSN:2041-6520
2041-6539
DOI:10.1039/d2sc05641k