Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates
Gergel S, Soler J, Klein A, Schülke KH, Hauer B, Garcia-Borràs M, Hammer S (2023)
Nature Catalysis 6(7): 606-617.
Zeitschriftenaufsatz
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Autor*in
Gergel, SebastianUniBi;
Soler, Jordi;
Klein, AlinaUniBi;
Schülke, Kai HannesUniBi;
Hauer, Bernhard;
Garcia-Borràs, Marc;
Hammer, StephanUniBi
Einrichtung
Projekt
Abstract / Bemerkung
**Abstract**
Ketones are crucial intermediates in synthesis and frequent moieties in many products. The direct regioselective synthesis of ketones from internal alkenes could simplify synthetic routes and solve a long-standing challenge in catalysis. Here we report the laboratory evolution of a cytochrome P450 enzyme for the direct oxidation of internal arylalkenes to ketones with several thousand turnovers. This evolved ketone synthase benefits from 15 crucial mutations, most of them distal to the active site. Computational analysis revealed that all these mutations collaborate to generate and tame a highly reactive carbocation intermediate. This is achieved through a confined, rigid, and geometrically and electrostatically preorganized active site. The engineered enzyme exploits a metal–oxo species for ketone synthesis and enables various challenging alkene functionalization reactions. This includes the catalytic, enantioselective oxidation of internal alkenes to ketones and formal asymmetric hydrofunctionalizations of internal alkenes in combination with other biocatalysts.
Ketones are crucial intermediates in synthesis and frequent moieties in many products. The direct regioselective synthesis of ketones from internal alkenes could simplify synthetic routes and solve a long-standing challenge in catalysis. Here we report the laboratory evolution of a cytochrome P450 enzyme for the direct oxidation of internal arylalkenes to ketones with several thousand turnovers. This evolved ketone synthase benefits from 15 crucial mutations, most of them distal to the active site. Computational analysis revealed that all these mutations collaborate to generate and tame a highly reactive carbocation intermediate. This is achieved through a confined, rigid, and geometrically and electrostatically preorganized active site. The engineered enzyme exploits a metal–oxo species for ketone synthesis and enables various challenging alkene functionalization reactions. This includes the catalytic, enantioselective oxidation of internal alkenes to ketones and formal asymmetric hydrofunctionalizations of internal alkenes in combination with other biocatalysts.
Erscheinungsjahr
2023
Zeitschriftentitel
Nature Catalysis
Band
6
Ausgabe
7
Seite(n)
606-617
Urheberrecht / Lizenzen
eISSN
2520-1158
Page URI
https://pub.uni-bielefeld.de/record/2980877
Zitieren
Gergel S, Soler J, Klein A, et al. Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates. Nature Catalysis. 2023;6(7):606-617.
Gergel, S., Soler, J., Klein, A., Schülke, K. H., Hauer, B., Garcia-Borràs, M., & Hammer, S. (2023). Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates. Nature Catalysis, 6(7), 606-617. https://doi.org/10.1038/s41929-023-00979-4
Gergel, Sebastian, Soler, Jordi, Klein, Alina, Schülke, Kai Hannes, Hauer, Bernhard, Garcia-Borràs, Marc, and Hammer, Stephan. 2023. “Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates”. Nature Catalysis 6 (7): 606-617.
Gergel, S., Soler, J., Klein, A., Schülke, K. H., Hauer, B., Garcia-Borràs, M., and Hammer, S. (2023). Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates. Nature Catalysis 6, 606-617.
Gergel, S., et al., 2023. Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates. Nature Catalysis, 6(7), p 606-617.
S. Gergel, et al., “Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates”, Nature Catalysis, vol. 6, 2023, pp. 606-617.
Gergel, S., Soler, J., Klein, A., Schülke, K.H., Hauer, B., Garcia-Borràs, M., Hammer, S.: Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates. Nature Catalysis. 6, 606-617 (2023).
Gergel, Sebastian, Soler, Jordi, Klein, Alina, Schülke, Kai Hannes, Hauer, Bernhard, Garcia-Borràs, Marc, and Hammer, Stephan. “Engineered cytochrome P450 for direct arylalkene-to-ketone oxidation via highly reactive carbocation intermediates”. Nature Catalysis 6.7 (2023): 606-617.
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