The novel formate oxidase from Aspergillus oryzae (AoFOx) is a useful catalyst to promote H2O2-dependent oxyfunctionalisation reactions. In this contribution we exploit the substrate promiscuity of AoFOx to fully oxidise methanol and formaldehyde to CO2 and drive peroxygenase-catalysed stereoselective oxyfunctionalisation reactions. The highly atom efficient H2O2 generation system also enabled high catalytic turnover of the peroxygenase production enzyme.@en

Fungal peroxygenases are deemed emergent biocatalysts for selective C-H bond oxyfunctionalization reactions. In this study, we have engineered a functional and stable self-sufficient chimeric peroxygenase-oxidase fusion. The bifunctional biocatalyst carried a laboratory-evolved version of the fungal peroxygenase fused to an evolved fungal aryl-alcohol oxidase that supplies H2O2 in situ. Enzyme fusion libraries with peptide linkers of different sizes and amino acid compositions were designed, while attached leader sequences favored secretion in yeast. The most promising functional enzyme fusions were characterized biochemically and further tested for the synthesis of dextrorphan, a metabolite of the antitussive drug dextromethorphan. This reaction system was optimized to control the aromatic alcohol transformation rate, and therefore the H2O2 supply, to achieve total turnover numbers of 62,000, the highest value reported for the biocatalytic synthesis of dextrorphan to date. Accordingly, our study opens an avenue for the use of peroxygenase-aryl alcohol oxidase fusions in the pharmaceutical and chemical sectors. @en

The generation of enantiodivergent biocatalysts for C-H oxyfunctionalizations is ever more important in modern synthetic chemistry. Here, we have applied the FuncLib algorithm based on phylogenetic and Rosetta calculations to design a diverse repertoire of active, stable, and enantiodivergent fungal peroxygenases. 24 designs, each carrying 4-5 mutations in the catalytic core, were expressed functionally in yeast and benchmarked against characteristic model compounds. Several designs were active and stable in a range of temperature and pH, displaying unprecedented enantiodivergence, changing regioselectivity from alkyl to aromatic hydroxylation, and increasing catalytic efficiencies up to 10-fold, with 15-fold improvements in total turnover numbers over the parental enzyme. We find that this dramatic functional divergence stems from beneficial epistasis among the mutations and an extensive reorganization of the heme channel. Our work demonstrates that FuncLib can rapidly design highly functional libraries enriched in enantioselective peroxygenases not seen in nature for a range of biotechnological applications. @en