Enantioselective Synthesis of Secondary Amines by Combining Oxidative Rearrangement and Biocatalysis in a One-Pot Process.

This contribution describes the development of chemoenzymatic one-pot processes, which combine an oxidative rearrangement and a biotransformation catalyzed by an imine reductase (IRED), for the synthesis of highly enantiomerically enriched secondary amines, such as an aryl-substituted pyrrolidine and a benzazepine. The benefits of this chemoenzymatic one-pot approach include high overall conversions (up to >99%), high enantiomeric excesses (up to >99% ee), and a straightforward synthetic approach toward secondary amines without the need to isolate the formed intermediate. For the initial chemical reaction, namely, the oxidative rearrangement, PhI(OAc)2 in methanol is used as a non-natural reagent, whereas the enzymatic step requires only stoichiometric amounts of d-glucose along with catalytic amounts of IRED, glucose dehydrogenase (GDH), and the cofactor NADPH. This methodology, demonstrating the compatibility of a "classic" organic synthesis using a non-natural, highly reactive reagent and a subsequent biocatalytic step, can be applied for different amines as substrates, thus making this concept a versatile tool in synthetic organic chemistry in general and for enantioselective synthesis of heterocyclic secondary amines in particular.

Fluorogenic Diversification of Unprotected Bromotryptophan by Aqueous Mizoroki-Heck Cross-Coupling.

Fluorescent styryl-tryptophans have been synthesized by a Mizoroki-Heck cross-coupling from unprotected bromotryptophan in aqueous medium showing promising spectrophotometric properties for possible application in fluorescence labelling of biomolecules. Moreover, this strategy permits a modular combination of biocatalytic halogenation by using immobilized FAD-dependent tryptophan halogenases and Pd-mediated chemocatalysis in a multistep one-pot process.