Litcius/Paper detail

Biomimetic <i>S</i> ‐Adenosylmethionine Regeneration Starting from Multiple Byproducts Enables Biocatalytic Alkylation with Radical SAM Enzymes**

Lukas Gericke, Dipali Mhaindarkar, Lukas Karst, Sören Jahn, Marco Kuge, Michael K. F. Mohr, Jana Gagsteiger, Nicolas V. Cornelissen, Xiaojin Wen, Silja Mordhorst, Henning J. Jessen, Andrea Rentmeister, Florian P. Seebeck, Gunhild Layer, Christoph Loenarz, Jennifer N. Andexer

2023ChemBioChem32 citationsDOIOpen Access PDF

Abstract

S-Adenosylmethionine (SAM) is an enzyme cofactor involved in methylation, aminopropyl transfer, and radical reactions. This versatility renders SAM-dependent enzymes of great interest in biocatalysis. The usage of SAM analogues adds to this diversity. However, high cost and instability of the cofactor impedes the investigation and usage of these enzymes. While SAM regeneration protocols from the methyltransferase (MT) byproduct S-adenosylhomocysteine are available, aminopropyl transferases and radical SAM enzymes are not covered. Here, we report a set of efficient one-pot systems to supply or regenerate SAM and SAM analogues for all three enzyme classes. The systems' flexibility is showcased by the transfer of an ethyl group with a cobalamin-dependent radical SAM MT using S-adenosylethionine as a cofactor. This shows the potential of SAM (analogue) supply and regeneration for the application of diverse chemistry, as well as for mechanistic studies using cofactor analogues.

Topics & Concepts

BiocatalysisAlkylationChemistryEnzymeOrganic chemistryCombinatorial chemistryRegeneration (biology)BiochemistryCatalysisBiologyReaction mechanismCell biologyMetalloenzymes and iron-sulfur proteinsSulfur-Based Synthesis TechniquesAdvanced Photocatalysis Techniques