An iron-free nitrogenase? Computational estimation of the ability to bind/activate N2 in manganese and cobalt complexes

An iron-free nitrogenase? Computational estimation of the ability to bind/activate N2 in manganese and cobalt complexes

Activation of N 2 to ammonia occurs in nitrogenases at an unusual carbide-iron-sulfur active site. To deconvolute the factors that allow the nitrogenase Fe to bind N 2 , we have recently reported a density functional theory (DFT) study on a series of Fe(H 2 O) n R(N 2 ) complexes, Fe(0)/Fe(I)/Fe(II)...

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Bibliographic Details
Published in:Journal of coordination chemistry Vol. 77; no. 12-14; pp. 1597 - 1606
Main Authors: Doukeh, Rami, Craciun, Daniela, Lehene, Maria, Branzanic, Adrian M. V., Lupan, Alexandru, Silaghi-Dumitrescu, Radu
Format: Journal Article
Language:English
Published: Abingdon Taylor & Francis 17-07-2024
Taylor & Francis Ltd
Subjects:
Ammonia
Cobalt
Cobalt compounds
Density functional theory
DFT
Dinitrogen
Iron
Manganese
Nitrogenase
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Summary:Activation of N 2 to ammonia occurs in nitrogenases at an unusual carbide-iron-sulfur active site. To deconvolute the factors that allow the nitrogenase Fe to bind N 2 , we have recently reported a density functional theory (DFT) study on a series of Fe(H 2 O) n R(N 2 ) complexes, Fe(0)/Fe(I)/Fe(II)/Fe(III), and R = H 2 O, HO − , CH 2 2− , or H 2 S. Reported here are computations on Mn and Co complexes in settings and with methodology identical to those previously employed for the related Fe systems in order to compare the ability of these metals to activate N 2 . None of the Co(II) and Co(III) models form clear bonds with N 2 ; Co(0) and Co(I) do form such bonds but are not known to be possible (at least not in settings with available coordination positions) in biological systems. Mn(0) and Mn(I) are also found to efficiently bind and activate N 2 ; however, neither are known in biological systems. Mn(II), especially with a methylene ligand, appears able to form a weak metal-dinitrogen bond. However, considering that Fe(I) systems but not Mn(I) systems are known in biological inorganic centers, and considering that Fe(I)/Mn(I) do bind/activate N 2 more efficiently than Fe(II)/Mn(II), iron may be argued to be the better choice for a nitrogenase active site.
ISSN:0095-8972
1029-0389
DOI:10.1080/00958972.2024.2372812