Elaine O'Reilly

Cytochromes P450 as useful biocatalysts: addressing the limitations

Cytochrome P450 monooxygenases (P450s or CYPs) are a unique family of enzymes which are capable of catalysing the regio- and stereospecific oxidation of non-functionalised hydrocarbons. Despite the enormous synthetic potential of P450s, these enzymes have yet to be extensively employed for research purposes or in industry. Lack of stability, low activity, narrow substrate specificity, expensive cofactor requirements, limited solvent tolerance and electron supply are some of the main reasons why the academic and industrial implementation of these important biocatalysts remains a challenge. Considering the significance of P450s, many research groups have focused on improving their properties in an effort to make more robust catalysts with broad synthetic applications. This article focuses on some of the factors that have limited the exploitation of P450s and explores some of the significant steps that have been taken towards addressing these limitations.

A Regio‐ and Stereoselective ω‐Transaminase/Monoamine Oxidase Cascade for the Synthesis of Chiral 2,5‐Disubstituted Pyrrolidines

Biocatalytic approaches to the synthesis of optically pure chiral amines, starting from simple achiral building blocks, are highly desirable because such motifs are present in a wide variety of important natural products and pharmaceutical compounds. Herein, a novel one-pot ω-transaminase (TA)/monoamine oxidase (MAO-N) cascade process for the synthesis of chiral 2,5-disubstituted pyrrolidines is reported. The reactions proceeded with excellent enantio- and diastereoselectivity (>94 % ee; >98 % de) and can be performed on a preparative scale. This methodology exploits the complementary regio- and stereoselectivity displayed by both enzymes, which ensures that the stereogenic center established by the transaminase is not affected by the monoamine oxidase, and highlights the potential of this multienzyme cascade for the efficient synthesis of chiral building blocks.

Chiral Amine Synthesis Using ω‐Transaminases: An Amine Donor that Displaces Equilibria and Enables High‐Throughput Screening

The widespread application of ω-transaminases as biocatalysts for chiral amine synthesis has been hampered by fundamental challenges, including unfavorable equilibrium positions and product inhibition. Herein, an efficient process that allows reactions to proceed in high conversion in the absence of by-product removal using only one equivalent of a diamine donor (ortho-xylylenediamine) is reported. This operationally simple method is compatible with the most widely used (R)- and (S)-selective ω-TAs and is particularly suitable for the conversion of substrates with unfavorable equilibrium positions (e.g., 1-indanone). Significantly, spontaneous polymerization of the isoindole by-product generates colored derivatives, providing a high-throughput screening platform to identify desired ω-TA activity.

Monoamine Oxidase–ω-Transaminase Cascade for the Deracemisation and Dealkylation of Amines

Herein we report a one‐pot protocol for the deracemisation of chiral benzylic amines employing a novel monoamine oxidase–ω‐transaminase cascade, allowing access to enantiopure compounds in >99 % ee. We also demonstrate that the same enzymatic cascade can be employed for the dealkylation of secondary amines with >99 % conversion.

Substrate promiscuity of cytochrome P450 RhF

Cytochrome P450 RhF displays a high degree of substrate promiscuity, mediating a range of O-dealkylations, aromatic hydroxylations, epoxidations and asymmetric sulfoxidations. The self-sufficient nature of this CYP coupled with its ability to catalyse the oxidation of a wide range of functional groups highlights this enzyme as an excellent starting template for directed evolution and promising alternate to P450 BM3.

Chimeric Self-sufficient P450cam-RhFRed Biocatalysts with Broad Substrate Scope

Summary A high-throughput screening protocol for evaluating chimeric, self-sufficient P450 biocatalysts and their mutants against a panel of substrates was developed, leading to the identification of a number of novel biooxidation activities.

A New Generation of Smart Amine Donors for Transaminase-Mediated Biotransformations.

The application of ω-transaminase biocatalysts for the synthesis of optically pure chiral amines presents a number of challenges, including difficulties associated with displacing the challenging reaction equilibria. Herein, we report a highly effective approach using low equivalents of the new diamine donor, cadaverine, which enables high conversions of challenging substrates to the corresponding chiral amines in excellent ee. This approach paves the way for the design of self-sufficient fermentation processes combining transaminase biotransformations with existing strategies for cadaverine production by decarboxylation of endogenous lysine.

Tuneable 3D printed bioreactors for transaminations under continuous-flow

A method to efficiently immobilize enzymes on 3D printed continuous-flow devices is presented. Application of these chemically modified devices enables rapid screening of immobilization mechanisms and reaction conditions, simple transfer of optimised conditions into tailored printed microfluidic reactors and development of continuous-flow biocatalytic processes. The bioreactors showed good activity (8–20.5 μmol h−1 mgenz−1) in the kinetic resolution of 1-methylbenzylamine, and very good stability (ca. 100 h under flow).