Abstract
We have investigated the implications of the recent crystallographic findings that the µ2-bridging S2B sulfide ligand may reversibly dissociate from the active-site FeMo cluster of nitrogenase. We show with combined quantum mechanical and molecular mechanical (QM/MM) calculations that once S2B has dissociated, N2 may bind in that position and can be protonated to two NH3 groups by thermodynamically favourable steps. The substrate forms hydrogen bonds with two protein ligands, Gln-191 and His-195. For all steps, we have studied three possible protonation states of His-195 (protonated on either ND1, NE2 or both). We find that the thermodynamically favoured path involves an end-on NNH2 structure, a mixed side-on/end-on H2NNH structure, a side-on H2NNH2 structure, a bridging NH2 structure and a bridging NH3 structure. In all cases, His-195 seems to be protonated on the NE2 atom. Dissociation of the NH3 product is often unfavourable and requires either further reduction or protonation of the cluster or rebinding of S2B. In conclusion, our calculations show that dissociation of S2B gives rise to a natural binding and reaction site for nitrogenase, between the Fe2 and Fe6 atoms, which can support an alternating reaction mechanism with favourable energetics.
Highlights
Nitrogenase (EC 1.18/19.6.1) is the only enzyme that can cleave the strong triple bond in N2 [1,2,3]
We have investigated the implications of the recent crystallographic findings that the m2-bridging S2B sulfide ligand may reversibly dissociate from the active-site FeMo cluster of nitrogenase
We show with combined quantum mechanical and molecular mechanical (QM/MM) calculations that once S2B has dissociated, N2 may bind in that position and can be protonated to two NH3 groups by thermodynamically favourable steps
Summary
Nitrogenase (EC 1.18/19.6.1) is the only enzyme that can cleave the strong triple bond in N2 [1,2,3] This is one of the most important reaction in nature: Even if the atmosphere of earth contains 78% N2, nitrogen is typically a limiting element for plant growth and a major component of artificial fertilizers. The reason for this is that the triple bond in N2 is very strong, making the molecule inert [3,4]. After hydrolysis of the ATP molecules, the Fe protein is released and a new reduced
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