Conversion of Similar Xenochemicals to Dissimilar Products: Exploiting Competing Reactions in Whole-Cell Catalysis

Francesca Sannelli, Camilla Hjortdal Sindahl, Stefan Warthegau, Pernille Rose Jensen, Sebastian Meier*

*Corresponding author for this work

Research output: Contribution to journalJournal articleResearchpeer-review

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Abstract

Many enzymes have latent activities that can be used in the conversion of non-natural reactants for novel organic conversions. A classic example is the conversion of benzaldehyde to a phenylacetyl carbinol, a precursor for ephedrine manufacture. It is often tacitly assumed that purified enzymes are more promising catalysts than whole cells, despite the lower cost and easier maintenance of the latter. Competing substrates inside the cell have been known to elicit currently hard-to-predict selectivities that are not easily measured inside the living cell. We employ NMR spectroscopic assays to rationally combine isomers for selective reactions in commercial S. cerevisiae. This approach uses internal competition between alternative pathways of aldehyde clearance in yeast, leading to altered selectivities compared to catalysis with the purified enzyme. In this manner, 4-fluorobenzyl alcohol and 2-fluorophenylacetyl carbinol can be formed with selectivities on the order of 90%. Modification of the cellular redox state can be used to tune product composition further. Hyperpolarized NMR shows that cellular reaction and pathway usage are affected by the xenochemical. Overall, we find that the rational construction of ternary or more complex substrate mixtures can be used forIn-Cell NMR spectroscopy to optimize upgrading of similar xenochemicals to dissimilar products with cheap whole-cell catalysts.
Original languageEnglish
Article number5157
JournalMolecules
Volume28
Issue number13
Number of pages18
ISSN1420-3049
Publication statusPublished - 2023

Keywords

  • Carboligation
  • D-DNP NMR
  • In-Cell NMR
  • Pyruvate decarboxylase
  • Substrate mixtures
  • Sustainable chemistry
  • Whole-cell catalysis
  • Yeast catalysis

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