Cytochrome P450s (CYPs) are important enzymes in the secondary metabolism of plants and have been recognized as key players in bioengineering and synthetic biology. Previously reported CYP76AH1 and CYP76AH3, having greater than 80% sequence homology, played a continuous catalytic role in the biosynthesis of tanshinones in Salvia miltiorrhiza. Homology modeling indicates that four sites might be responsible for differences in catalytic activity between the two enzymes. A series of modeling-based mutational variants of CYP76AH1 were designed to integrate the functions of the two CYPs. The mutant CYP76AH1D301E,V479F, which integrated the functions of CYP76AH1 and CYP76AH3, was found to efficiently catalyze C11 and C12 hydroxylation and C7 oxidation of miltiradiene substrates. Integration and utilization of CYP76AH1D301E,V479F by synthetic biology methods allowed the robust production of 11-hydroxy ferruginol, sugiol, and 11-hydroxy sugiol in yeast. The functionally integrated CYP gene after active site modifications improves catalytic efficiency by reducing the transfer of intermediate metabolites between component proteins. This provides a synthetic biology reference for improving the catalytic efficiencies of systems that produce plant natural products in microorganisms.
Keywords: Cytochrome P450s (CYPs); functional integration; modeling-based mutations; protein engineering; synthetic biology.