Baeyer-Villiger monooxygenases catalyze oxidations that are of interest for biocatalytic applications. Among these enzymes, phenylacetone monooxygenase (PAMO) from Thermobifida fusca is the only protein showing remarkable stability. While related enzymes often present a broad substrate scope, PAMO accepts only a limited number of substrates. Due to the absence of a substrate in the elucidated crystal structure of PAMO, the substrate binding site of this protein has not yet been defined. In this study, a structural model of cyclopentanone monooxygenase, which acts on a broad range of compounds, has been prepared and compared with the structure of PAMO. This revealed 15 amino acid positions in the active site of PAMO that may account for its relatively narrow substrate specificity. We designed and analyzed 30 single and multiple mutants in order to verify the role of these positions. Extensive substrate screening revealed several mutants that displayed increased activity and altered regio-or enantioselectivity in Baeyer-Villiger reactions and sulfoxidations. Further substrate profiling resulted in the identification of mutants with improved catalytic properties toward synthetically attractive compounds. Moreover, the thermostability of the mutants was not compromised in comparison to that of the wild-type enzyme. Our data demonstrate that the positions identified within the active site of PAMO, namely, V54, I67, Q152, and A435, contribute to the substrate specificity of this enzyme. These findings will aid in more dedicated and effective redesign of PAMO and related monooxygenases toward an expanded substrate scope.Enzymes have been gaining increasing attention as efficient and selective catalysts to be used in synthetic chemistry. Baeyer-Villiger monooxygenases (BVMOs) comprise a group of enzymes that are particularly interesting for synthetic applications. These biocatalysts employ molecular oxygen as a mild oxidant to oxidize carbonylic compounds. Apart from catalyzing Baeyer-Villiger reactions, BVMOs are capable of oxidizing a range of heteroatoms (e.g., sulfur, nitrogen, and boron). Furthermore, they often perform these reactions with high chemo-, regio-, and enantioselectivity (5, 15, 30). The use of oxygen, which is a cheap and clean oxidant, and their diversity of catalyzed reactions make BVMOs attractive candidates for biocatalytic processes.The identification of phenylacetone monooxygenase (PAMO) in the moderately thermophilic bacterium Thermobifida fusca has brought about a breakthrough in the research on BVMOs (11). PAMO is a thermostable enzyme that can easily be expressed in Escherichia coli and purified. Besides, its crystal structure has been solved as the first structure of a BVMO (17). While PAMO shows excellent stability, even in the presence of organic solvents (6, 28), its substrate specificity is rather restricted. The enzyme accepts mainly small aromatic ketones and sulfides (7, 26), whereas the oxidations of bulkier ketones occur with lower activity and selectivity (27). However, the unique...
