Semi-rational design based on the interaction between SmFMO and FAD isoalloxazine ring to enhance the enzyme activity.

Flavin monooxygenases (FMOs) have been widely used in the biosynthesis of natural compounds due to their excellent stereoselectivity, regioselectivity and chemoselectivity. Stenotrophomonas maltophilia flavin monooxygenase (SmFMO) has been reported to catalyze the oxidation of various thiols to corresponding sulfoxides, but its activity is relatively low. Herein, we obtained a mutant SmFMOF52G which showed 4.35-fold increase in kcat/Km (4.96 mM-1s-1) and 6.84-fold increase in enzyme activity (81.76 U/g) compared to the SmFMOWT (1.14 mM-1s-1 and 11.95 U/g) through semi-rational design guided by structural analysis and catalytic mechanism combined with high-throughput screening. By forming hydrogen bond with O4 atom of FAD isoalloxazine ring and reducing steric hindrance, the conformation of FAD isoalloxazine ring in SmFMOF52G is more stable, and NADPH and substrate are closer to FAD isoalloxazine ring, shortening the distances of hydrogen transfer and substrate oxygenation, thereby increasing the rate of reduction and oxidation reactions and enhancing enzyme activity. Additionally, the overall structural stability and substrate binding capacity of the SmFMOF52G have significant improved than that of SmFMOWT. The strategy used in this study to improve the enzyme activity of FMOs may have generality, providing important references for the rational and semi-rational engineering of FMOs.

Computation-Aided Phylogeny-Oriented Engineering of ß-Xylosidase: Modification of "Blades" to Enhance Stability and Activity for the Bioconversion of Hemicellulose to Produce Xylose.

Hemicellulose is a highly abundant, ubiquitous, and renewable natural polysaccharide, widely present in agricultural and forestry residues. The enzymatic hydrolysis of hemicellulose has generally been accomplished using ß-xylosidases, but concomitantly increasing the stability and activity of these enzymes remains challenging. Here, we rationally engineered a ß-xylosidase from Bacillus clausii to enhance its stability by computation-aided design combining ancestral sequence reconstruction and structural analysis. The resulting combinatorial mutant rXYLOM25I/S51L/S79E exhibited highly improved robustness, with a 6.9-fold increase of the half-life at 60 °C, while also exhibiting improved pH stability, catalytic efficiency, and hydrolytic activity. Structural analysis demonstrated that additional interactions among the propeller blades in the catalytic module resulted in a much more compact protein structure and induced the rearrangement of the opposing catalytic pocket to mediate the observed improvement of activity. Our work provides a robust biocatalyst for the hydrolysis of agricultural waste to produce various high-value-added chemicals and biofuels.