Engineered Fluorine Metabolism and Fluoropolymer Production in Living Cells

Fluorine has become an important element for the design of synthetic molecules for use in medicine, agriculture, and materials. Despite the many advantages provided by fluorine for tuning key molecular properties, it is rarely found in natural metabolism. We seek to expand the molecular space available for discovery through the development of new biosynthetic strategies that cross synthetic with natural compounds. Towards this goal, we engineered a microbial host for organofluorine metabolism and show that we can achieve the production of the fluorinated diketide 2‐fluoro‐3‐hydroxybutyrate at approximately 50 % yield. This fluorinated diketide can be used as a monomer in vivo to produce fluorinated poly(hydroxyalkanoate) (PHA) bioplastics with fluorine substitutions ranging from around 5–15 %. This system provides a platform to produce mm flux through the key fluoromalonyl coenzyme A (CoA) building block, thereby offering the potential to generate a broad range of fluorinated small‐molecule targets in living cells.     

Asymmetric Synthesis of Alkyl Fluorides: Hydrogenation of Fluorinated Olefins

The development of new general methods for the synthesis of chiral fluorine‐containing molecules is important for several scientific disciplines. We herein disclose a straightforward method for the preparation of chiral organofluorine molecules that is based on the iridium‐catalyzed asymmetric hydrogenation of trisubstituted alkenyl fluorides. This catalytic asymmetric process enables the synthesis of chiral fluorine molecules with or without carbonyl substitution. Owing to the tunable steric and electronic properties of the azabicyclo thiazole‐phosphine iridium catalyst, this stereoselective reaction could be optimized and was found to be compatible with various aromatic, aliphatic, and heterocyclic systems with a variety of functional groups, providing the highly desirable products in excellent yields and enantioselectivities.     

Cu/Pd Synergistic Dual Catalysis: Asymmetric α-Allylation of an α-CF3 Amide

Despite the burgeoning demand for fluorine-containing chemical entities, the construction of CF₃-containing stereogenic centers has remained elusive. Herein, we report the strategic merger of Cu^I/base-catalyzed enolization of an α-CF₃ amide and Pd⁰-catalyzed allylic alkylation in an enantioselective manner to deliver chiral building blocks bearing a stereogenic carbon center connected to a CF₃, an amide carbonyl, and a manipulable allylic group. The phosphine complexes of Cu^I and Pd⁰ engage in distinct catalytic roles without ligand scrambling to render the dual catalysis operative to achieve asymmetric α-allylation of the amide. The stereoselective cyclization of the obtained α-CF₃-γ,δ-unsaturated amides to give tetrahydropyran and γ-lactone-fused cyclopropane skeletons highlights the synthetic utility of the present catalytic method as a new entry to non-racemic CF₃-containing compounds.