25-Hydroxyvitamin D3 (25-OH-VD3) is the main active form of Vitamin D3 and has broad applications in clinical treatment and agriculture. Although current industrial production predominantly relies on chemical synthesis, the growing demand for green and efficient manufacturing has accelerated the development of microbial enzymatic conversion methods. Due to its high reaction specificity, the unspecific peroxygenase from Coprinopsis cinerea (CciUPO) represents a promising biocatalyst for the synthesis of 25-OH-VD3. However, its low catalytic efficiency limits further application in the biosynthesis of 25-OH-VD3. To address this, semi-rational design was employed to modify the substrate-binding pocket and non-conserved residues of CciUPO. The resulting triple mutant I73M/P108K/G245A increased the 25-OH-VD3 concentration to (87.83 ± 3.47) mg/L, representing a 41.18% increase over the wild type [(62.21 ± 3.02) mg/L]. The mechanism for enhanced catalytic efficiency was elucidated through analysis of the substrate-binding pocket, enzyme-substrate interactions, and molecular dynamics simulations. Subsequently, the fermentation conditions and multi-enzyme cascade reaction were optimized. Under optimized conditions with a substrate VD3 concentration of 0.5 g/L, the 25-OH-VD3 concentration further increased to (152.50 ± 1.95) mg/L. The combination of semi-rational engineering and process optimization of CciUPO offers a feasible, green and efficient strategy for the biosynthesis of 25-OH-VD3.
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Funding
National Key Research and Development Program of China(No. 2024YFA0917900)
Fundamental Research Funds for the Central Universities(No. JUSRP202504023)
RIGHTS & PERMISSIONS
Jiangnan University
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