Peroxygenases represent a class of versatile heme-thiolate enzymes capable of catalysing highly selective oxyfunctionalisation reactions, particularly the hydroxylation of non-activated C-H bonds. This transformation, which poses substantial challenges in conventional organic synthesis, underscores the potential of peroxygenases in green chemistry applications. While cytochrome P450 monooxygenases have long been the primary focus for such biocatalytic transformations, their industrial adoption has been limited due to complex electron transfer chains and cofactor requirements. In contrast, peroxygenases bypass these limitations by directly utilising hydrogen peroxide (H₂O₂) to activate the catalytic heme site, thereby circumventing the oxygen dilemma typically encountered in P450 catalysis. Key milestones in peroxygenase research include the identification of chloroperoxidase from Caldariomyces fumago and the subsequent discovery of unspecific peroxygenases, such as those from Agrocybe aegerita, which exhibit broad substrate specificity and high catalytic efficiency. Here, we explore the mechanistic pathway of peroxygenase-catalysed reactions, emphasising the formation and decay of Compound I and the catalytic cycle's various functional outcomes. Critical aspects such as in situ H₂O₂ generation to mitigate enzyme inactivation, substrate loading strategies for practical applications, and the role of enzyme and reaction engineering in enhancing regio- and stereoselectivity are examined. Additionally, we address challenges in reaction scalability and operational stability for preparative-scale applications, offering insights into innovative protocols involving immobilised enzymes and non-aqueous reaction media. This review highlights recent advancements in the peroxygenase field and underscores the enzyme's promising role in sustainable oxyfunctionalisation reactions.

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In this study, we present a significant advancement in the field of enzymatic asymmetric reductive amination (ARA) of ketones, a pivotal reaction for chiral amine synthesis. Through a combination of semirational enzyme design and bioprocess development, we achieve the dual activation and stabilization of amine dehydrogenase (AmDH) to meet industrial demands. The engineered AmDH exhibits remarkable catalytic efficiency (turnover number, TON >1,000,000) and exceptional stability (half-life >7 days at 50 °C), with a broadened substrate scope including various aryl alkyl ketones and fatty ketones. Leveraging biobased oleic acid as an activator and stabilizer, we achieved kilogram-scale synthesis of chiral amines. Furthermore, the integration of AmDH with chemical catalysts in chemoenzymatic cascades has enabled the synthesis of a wide array of pharmaceutically relevant amines from diverse substrates, demonstrating the enzyme’s versatility and potential to transform synthetic chemistry.

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Unspecific peroxygenase from Agrocybe aegerite (AaeUPO) is a remarkable catalyst for the oxyfunctionalization of non-activated C−H bonds under mild conditions. It exhibits comparable activity to P450 monooxygenase but offers the advantage of using H₂O₂ instead of a complex electron transport chain to reductively activate O₂. Here, we demonstrate the successful oxidation of cyclohexane to cyclohexanol/cyclohexanone (KA-oil) using sol-gel encapsulated AaeUPO. Remarkably, cyclohexane serves both as a solvent and a substrate in this system, which simplifies product isolation. The ratio of cyclohexanone to cyclohexanol using this approach is remarkably higher compared to the oxidation using free AaeUPO in aqueous media using acetonitrile as a cosolvent. The utilization of sol-gel encapsulated AaeUPO offers a promising approach for oxyfunctionalization reactions and improves the chances for this enzyme to be incorporated in the same pot with other chemical transformations.

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The downstream product transformation of lignin depolymerization is of great interest in the production of high-value aromatic chemicals. However, this transformation is often impeded by chemical oxidation under harsh reaction conditions. In this study, we demonstrate that hypohalites generated in situ by the vanadium-containing chloroperoxidase from Curvularia inaequalis (CiVCPO) can halogenate various electron-rich and electron-poor phenol and phenolic acid substrates. Specifically, CiVCPO enabled decarboxylative halogenation, deformylative halogenation, halogenation, and direct oxidation reactions. The versatile transformation routes for the valorization of phenolic compounds showed up to 99% conversion and 99% selectivity, with a turnover number of 60,700 and a turnover frequency of 60 s^-1 for CiVCPO. This study potentially expands the biocatalytic toolbox for lignin valorization.

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Vicinal halohydrins are key building blocks to produce bioactive molecules and drugs, especially if they can be obtained in enantiomerically pure form. In this study, we present a bi-enzymatic sequence that allows to obtain vic-halohydrins through a photochemoenzymatic olefin hydroxy halogenation followed by a lipase catalysed kinetic resolution. The absolute configuration of the resulting products was determined using Mosher's method.@en

Synthetic biohybrid systems by coupling artificial system with nature's machinery may offer a disruptive solution to address the global energy crisis. We developed a versatile electroenzymatic pathway for the continuous synthesis of valuable chemicals, facilitated by formate-driven NADH regeneration. Utilizing a bismuth electrocatalyst, we achieved stable CO2 reduction to formate with approximately 90 % Faraday efficiency at a current density of 150 mA cm−2. The generated formate acts as a mediator to regenerate NADH, which is then coupled with immobilized redox enzymes—alcohol dehydrogenase (ADH), L-lactate dehydrogenase (LDH), and L-glutamate dehydrogenase (GDH)—to produce targeted chemicals at significant rates and exceptionally high turnover numbers (1.8×106 to 3.1×106). These achievements not only underscore the efficiency of the system but also its practical applicability in industrial settings. By leveraging in situ generated formate, this innovative approach demonstrates the potential of integrating electrocatalysis with enzymatic reactions for sustainable and efficient chemical production on a practical scale.@en

Enzymes are making a significant impact on chemical synthesis. However, the range of chemical products achievable through biocatalysis is still limited compared to the vast array of products possible with organic synthesis. For instance, azoxy products have rarely been synthesized using enzyme catalysts. In this study, we discovered that fungal unspecific peroxygenases are promising catalysts for synthesizing azoxy products from simple aniline starting materials. The catalytic features (up to 48,450 turnovers and a turnover frequency of 6.7 s–1) and substrate transformations (up to 99% conversion with 98% chemoselectivity) highlight the synthetic potential. We propose a mechanism where peroxygenase-derived hydroxylamine and nitroso compounds spontaneously (non-enzymatically) form the desired azoxy products. This work expands the reactivity repertoire of biocatalytic transformations in the underexplored field of azoxy compound formation reactions.@en

We report the synthesis and characterization of an artificial peroxygenase (CoN4SA-POase) with CoN4 active sites by supporting single-atom cobalt on polymeric carbon nitrogen, which exhibits high activity, selectivity, stability, and reusability in the oxidation of aromatic alkanes to ketones. Density functional theory calculations reveal a different catalytic mechanism for the artificial peroxygenase from that of natural peroxygenases. In addition, continuous-flow systems are employed to combine CoN4SA-POase with enantiocomplementary ketoreductases as well as an amine dehydrogenase, enabling the enantioselective synthesis of chiral alcohols and amines from hydrocarbons with significantly improved productivity. This work, emulating nature and beyond nature, provides a promising design concept for heme enzyme-based transformations.@en

Ene-reductases from the old yellow enzyme (OYE) family have been traditionally employed in the reduction of conjugated C═C double bonds. This study explores the underutilized oxidative potential of OYEs, demonstrating their capability to catalyze the enantioselective desaturation of carbonyl compounds. Utilizing a deprotonated tyrosine residue as a catalytic base, we developed a method to enable OYE-catalyzed desaturation at ambient temperature and alkaline pH without the need for high-temperature conditions. Through screening of various OYE enzymes, we identified several candidates from different genera with enhanced desaturase activity across different substrates. This work broadens the scope of biocatalytic applications for OYEs, introducing a novel approach to the synthesis of chiral α,β-unsaturated carbonyl compounds.@en

Cofactor imbalance obstructs the productivities of metabolically engineered cells. Herein, we employed a minimally perturbing system, xylose reductase and lactose (XR/lactose), to increase the levels of a pool of sugar phosphates which are connected to the biosynthesis of NAD(P)H, FAD, FMN, and ATP in Escherichia coli. The XR/lactose system could increase the amounts of the precursors of these cofactors and was tested with three different metabolically engineered cell systems (fatty alcohol biosynthesis, bioluminescence light generation, and alkane biosynthesis) with different cofactor demands. Productivities of these cells were increased 2-4-fold by the XR/lactose system. Untargeted metabolomic analysis revealed different metabolite patterns among these cells, demonstrating that only metabolites involved in relevant cofactor biosynthesis were altered. The results were also confirmed by transcriptomic analysis. Another sugar reducing system (glucose dehydrogenase) could also be used to increase fatty alcohol production but resulted in less yield enhancement than XR. This work demonstrates that the approach of increasing cellular sugar phosphates can be a generic tool to increase in vivo cofactor generation upon cellular demand for synthetic biology.

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Editorial.@en

Photobiocatalysis is currently in vogue. The number of reports combining the disciplines of biocatalysis and photocatalysis is rapidly increasing. While the synthetic possibilities enabled by photobiocatalysis are fascinating, the economic feasibility and environmental impact are largely neglected in the current literature. In this contribution, we present a range of key indicators for economic feasibility and environmental impact that may be useful for readers to assess their own work and thereby avoid unrealistic exaggerations. We also critically review the current state of the art in photobiocatalysis and question its synthetic practicability beyond the laboratory. With this contribution, we aim to provoke an open discussion.@en

This review analyzes a development in biochemistry, enzymology and biotechnology that originally came as a surprise. Following the establishment of directed evolution of stereoselective enzymes in organic chemistry, the concept of partial or complete deconvolution of selective multi-mutational variants was introduced. Early deconvolution experiments of stereoselective variants led to the finding that mutations can interact cooperatively or antagonistically with one another, not just additively. During the past decade, this phenomenon was shown to be general. In some studies, molecular dynamics (MD) and quantum mechanics/molecular mechanics (QM/MM) computations were performed in order to shed light on the origin of non-additivity at all stages of an evolutionary upward climb. Data of complete deconvolution can be used to construct unique multi-dimensional rugged fitness pathway landscapes, which provide mechanistic insights different from traditional fitness landscapes. Along a related line, biochemists have long tested the result of introducing two point mutations in an enzyme for mechanistic reasons, followed by a comparison of the respective double mutant in so-called double mutant cycles, which originally showed only additive effects, but more recently also uncovered cooperative and antagonistic non-additive effects. We conclude with suggestions for future work, and call for a unified overall picture of non-additivity and epistasis.@en

This study presents a three-step one pot enzymatic cascade for the synthesis of a δ-lactone. Utilising acetaldehyde, combining 2-deoxyribose-5-phosphate aldolase (DERA) with an alcohol dehydrogenase (ADH) and a cofactor regeneration system this δ-lactone is synthesised with the same stereochemistry as the statin side chain precursor. The initial stage in this cascade involves the double aldol reaction, catalysed by DERA to produce the chiral lactone precursor from the achiral substrate acetaldehyde. The main challenge at this stage is the instability of DERA in the presence of high acetaldehyde concentrations. Therefore, Lactobacillus brevis DERA with a high natural acetaldehyde tolerance was genetically engineered to further improve this property. LbDERA C42M E78K exhibited improved activity and stability (no activity loss over 2 h) compared to the wild type (20% activity loss). In the second stage of the cascade, the aldol product is selectively oxidised to the lactone. A commercially available ADH was identified to selectively catalyse this oxidation using NADP⁺ as electron acceptor. NADP⁺ regeneration was achieved using O₂ as substrate in two different ways: using either photo-activated flavin or NADPH oxidase (NOX). The lactone was successfully purified from the enzymatic cascades from a preparative scale reaction in 97% purity with an optical rotation [α]_D = +34.2° (c = 0.7), proving the feasibility in a multi-enzyme three-step one-pot cascade.

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Contemporary Biocatalysis heavily relies on enzyme engineering as natural enzymes frequently lack the requisite attributes for effective organic synthesis. The inherent limitations in stability, catalytic activity, and selectivity of wild-type enzymes often hinder their suitability for chemical synthesis. Over the past 25 years, there has been an unprecedented advancement in protein engineering tools, empowering enzymologists to customise enzymes to precisely meet the demands of organic synthesis. In this discussion, we delineate some of the most crucial techniques in enzyme engineering and their significance in facilitating chemical synthesis.

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Chemoenzymatic cascade catalysis has emerged as a revolutionary tool for streamlining traditional retrosynthetic disconnections, creating new possibilities for the asymmetric synthesis of valuable chiral compounds. Here we construct a one-pot concurrent chemoenzymatic cascade by integrating organobismuth-catalyzed aldol condensation with ene-reductase (ER)-catalyzed enantioselective reduction, enabling the formal asymmetric α-benzylation of cyclic ketones. To achieve this, we develop a pair of enantiocomplementary ERs capable of reducing α-arylidene cyclic ketones, lactams, and lactones. Our engineered mutants exhibit significantly higher activity, up to 37-fold, and broader substrate specificity compared to the parent enzyme. The key to success is due to the well-tuned hydride attack distance/angle and, more importantly, to the synergistic proton-delivery triade of Tyr28-Tyr69-Tyr169. Molecular docking and density functional theory (DFT) studies provide important insights into the bioreduction mechanisms. Furthermore, we demonstrate the synthetic utility of the best mutants in the asymmetric synthesis of several key chiral synthons.

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The biocatalytic oxidative deamination of β-amino alcohols holds significant practical potential in kinetic resolution and/or deracemization process to access (R)-β-amino alcohols. This study exemplifies a notable instance of acquisition and utilization of this valuable oxidative deamination activity. Initially, the mutation N261M (M0) was identified to endow a native valine dehydrogenase with oxidative deamination activity toward a few (S)-β-amino alcohols. Subsequently, a phylogenetic analysis-guided, double-code saturation mutagenesis strategy was proposed to engineer M0's side-chain binding site. This strategy facilitated the substrate-specific evolution of M0, resulting in the creation of a panel of mutants (M1-M4) with noteworthy oxidative deamination activity toward structurally diverse (S)-β-amino alcohols. Using these engineered amine dehydrogenases, termed as β-amino alcohol dehydrogenases (β-AADHs), the complete kinetic resolution and even deracemization of a range of β-amino alcohols have been achieved. This work reports distinct biocatalysts and a synthetic strategy for the synthesis of enantiopure (R)-β-amino alcohols and offers an innovative approach for substrate-specificity engineering of enzymes.

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Lignin is the most abundant renewable and sustainable source of aromatic compounds to replace fossil resources, causing environmental issues. However, most lignin generated from pulping and biorefinery processes is combusted or discarded as waste. In this work, we first propose a photocatalytic artificial wood platform consisting of lignin and cellulose, inspired by woody cell walls, where lignin is arranged around cellulose fibers. The wood-mimetic particles were fabricated through reconstitution after the complete dissolution of lignin and cellulose. Intensive characterization revealed that the introduction of cellulose suppressed lignin’s self-aggregation, which limits its practical photocatalytic applications. As a result, the artificial wood photocatalyst exhibited a 3.2 times higher production rate of H2O2 from oxygen and water than lignin under solar light. The wood-mimetic photocatalyst was further coupled with an unspecific peroxygenase (UPO) biocatalyst to catalyze the selective oxygenation of inert C–H bonds using H2O2 as an oxidant. The wood-UPO hybrid catalyst demonstrated a universal photobiocatalytic oxyfunctionalization of various hydrocarbons with a higher total turnover number and turnover frequency than the lignin-UPO catalyst. This work suggests a practical strategy to utilize waste lignin as a photocatalyst and further demonstrates sustainable biosolar oxygenation reactions using sunlight and water as green energy and electron sources, respectively.@en

Oleate hydratases open a biocatalytic access to hydroxy fatty acids by hydration of unsaturated fatty acids. Their practical applicability, however, is hampered by their low stability. In this study we report the immobilization of the oleate hydratase from Rhodococcus erythropolis PR4 on functionalized porous, spherical polymer beads. Different carrier materials promoting covalent, hydrophobic, ionic and his-tag affinity were screened and immobilization yields typically >95 % were observed. The highest activity recovery of 32 % was achieved by immobilization via ionic interaction with quaternary ammonium functionalized beads. Biochemical properties of the enzyme immobilized via ionic interaction remain unchanged upon immobilization. The immobilized enzyme was applied for synthesis of 10-hydroxystearic acid remaining stable under process conditions. Conversion of up to 100 mM oleic acid gave 10-hydroxystearic acid achieving a TON of up to 19,000. Successful recycling of the biocatalyst for up to ten cycles further demonstrate its potential for the synthesis of 10-hydroxystearic acid.@en

An enzymatic method for the selective hydroxylation of phenols using a peroxygenase from Aspergillus brasiliensis (AbrUPO) is reported. A broad range of phenolic starting materials can be selectively transformed into the corresponding hydroquinones. Semi-preparative syntheses of several hydroquinones were realised without further optimization pointing out the applicability of this enzyme as biocatalyst.

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