Engineering of a Thermostable Biocatalyst for the Synthesis of 2-O-Glucosylglycerol

2-O-Glucosylglycerol is accumulated by various bacteria and plants in response to environmental stress. It is widely applied as a bioactive moisturising ingredient in skin care products, for which it is manufactured via enzymatic glucosylation of glycerol by the sucrose phosphorylase from Leuconostoc mesenteroides. This industrial process is operated at room temperature due to the mediocre stability of the biocatalyst, often leading to microbial contamination. The highly thermostable sucrose phosphorylase from Bifidobacterium adolescentis could be a better alternative in that regard, but this enzyme is not fit for production of 2-O-glucosylglycerol due to its low regioselectivity and poor affinity for glycerol. In this work, the thermostable phosphorylase was engineered to alleviate these problems. Several engineering approaches were explored, ranging from site-directed mutagenesis to conventional, binary, iterative or combinatorial randomisation of the active site, resulting in the screening of similar to 3,900 variants. Variant P134Q displayed a 21-fold increase in catalytic efficiency for glycerol, as well as a threefold improvement in regioselectivity towards the 2-position of the substrate, while retaining its activity for several days at elevated temperatures.

Automated summary

2-O-Glucosylglycerol is a substance accumulated by bacteria and plants in response to environmental stress, widely used in skin care products. In this study, a thermostable phosphorylase was engineered to improve its efficiency and stability for producing 2-O-Glucosylglycerol, resulting in a variant with increased catalytic efficiency, improved regioselectivity, and retained activity at elevated temperatures.