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<i>Cs</i>CCD2 Access Tunnel Design for a Broader Substrate Profile in Crocetin Production

Nan Liang, Mingdong Yao, Ying Wang, Jia Liu, Lu Feng, Zhiming Wang, Xiangyü Li, Wenhai Xiao, Ying‐Jin Yuan

2021Journal of Agricultural and Food Chemistry26 citationsDOI

Abstract

Crocetin, a high-value apocarotenoid in saffron, is widely applied to the fields of food and medicine. However, the existing method of obtaining crocetin through large-scale cultivation is far from meeting the market demand. Microbial synthesis of crocetin is a potential alternative to traditional resources, and it is found that carotenoid cleavage dioxygenase (CCD) is the critical enzyme to synthesize crocetin. So, in this study, we used “hybrid-tunnel” engineering to obtain variants of Crocus sativus-derived CsCCD2, essential for zeaxanthin conversion into crocetin, with a broader substrate specificity and higher catalytic efficiency. Variants including S323A, with a lower charge bias and a larger tunnel size than the wild-type, showed a 5-fold higher crocetin titer in yeast-based fermentations. S323A could also convert the β-carotene substrate to crocetin dialdehyde and exhibited a 12.83-fold greater catalytic efficiency (kcat/Km) toward zeaxanthin than the wild-type in vitro. This strategy enabled the production of 107 mg/L crocetin in 5 L fed-batch fermentation, higher than that previously reported. Our findings demonstrate that engineering access tunnels to expand the substrate profile by in silico protein design represents a viable strategy to refine the catalytic properties of enzymes across a range of applications.

Topics & Concepts

CrocetinZeaxanthinChemistryBioproductionSubstrate (aquarium)CrocinBiochemistryCarotenoidBiologyLuteinEcologySaffron Plant Research StudiesMedicinal Plants and Bioactive CompoundsAgriculture and Biological Studies
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