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Algorithm-aided engineering of aliphatic halogenase WelO5* for the asymmetric late-stage functionalization of soraphens.

Johannes BüchlerSumire Honda MalcaDavid PatschMoritz VossNicholas J TurnerUwe T BornscheuerOliver AllemannCamille Le ChapelainAlexandre LumbrosoOlivier LoiseleurRebecca M Buller
Published in: Nature communications (2022)
Late-stage functionalization of natural products offers an elegant route to create novel entities in a relevant biological target space. In this context, enzymes capable of halogenating sp 3 carbons with high stereo- and regiocontrol under benign conditions have attracted particular attention. Enabled by a combination of smart library design and machine learning, we engineer the iron/α-ketoglutarate dependent halogenase WelO5* for the late-stage functionalization of the complex and chemically difficult to derivatize macrolides soraphen A and C, potent anti-fungal agents. While the wild type enzyme WelO5* does not accept the macrolide substrates, our engineering strategy leads to active halogenase variants and improves upon their apparent k cat and total turnover number by more than 90-fold and 300-fold, respectively. Notably, our machine-learning guided engineering approach is capable of predicting more active variants and allows us to switch the regio-selectivity of the halogenases facilitating the targeted analysis of the derivatized macrolides' structure-function activity in biological assays.
Keyphrases
  • machine learning
  • wild type
  • artificial intelligence
  • copy number
  • big data
  • deep learning
  • working memory
  • high throughput
  • magnetic resonance
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  • gene expression
  • single cell
  • postmenopausal women