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In-crystal reaction cycle of a toluene-bound diiron hydroxylase

Author

Listed:
  • Justin F. Acheson

    (University of Wisconsin-Madison)

  • Lucas J. Bailey

    (University of Wisconsin-Madison)

  • Thomas C. Brunold

    (University of Wisconsin-Madison)

  • Brian G. Fox

    (University of Wisconsin-Madison)

Abstract

Electrophilic aromatic substitution is one of the most important and recognizable classes of organic chemical transformation. Enzymes create the strong electrophiles that are needed for these highly energetic reactions by using O2, electrons, and metals or other cofactors. Although the nature of the oxidants that carry out electrophilic aromatic substitution has been deduced from many approaches, it has been difficult to determine their structures. Here we show the structure of a diiron hydroxylase intermediate formed during a reaction with toluene. Density functional theory geometry optimizations of an active site model reveal that the intermediate is an arylperoxo Fe2+/Fe3+ species with delocalized aryl radical character. The structure suggests that a carboxylate ligand of the diiron centre may trigger homolytic cleavage of the O–O bond by transferring a proton from a metal-bound water. Our work provides the spatial and electronic constraints needed to propose a comprehensive mechanism for diiron enzyme arene hydroxylation that accounts for many prior experimental results.

Suggested Citation

  • Justin F. Acheson & Lucas J. Bailey & Thomas C. Brunold & Brian G. Fox, 2017. "In-crystal reaction cycle of a toluene-bound diiron hydroxylase," Nature, Nature, vol. 544(7649), pages 191-195, April.
    • Handle: RePEc:nat:nature:v:544:y:2017:i:7649:d:10.1038_nature21681
    DOI: 10.1038/nature21681
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    Cited by:

    1. Stephan Walleck & Thomas Philipp Zimmermann & Henning Hachmeister & Christian Pilger & Thomas Huser & Sagie Katz & Peter Hildebrandt & Anja Stammler & Hartmut Bögge & Eckhard Bill & Thorsten Glaser, 2022. "Generation of a μ-1,2-hydroperoxo FeIIIFeIII and a μ-1,2-peroxo FeIVFeIII Complex," Nature Communications, Nature, vol. 13(1), pages 1-11, December.

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