Reshaping the Binding Pocket of Cellobiose 2‑Epimerase for Improved Substrate Affinity and Isomerization Activity for Enabling Green Synthesis of Lactulose

• Published in: Journal of agricultural and food chemistry Vol. 70; no. 50; pp. 15879 - 15893
• Main Authors: Wang, Lu, Gu, Jiali, Zhao, Wei, Wang, Mingming, Ng, Kuan Rei, Lyu, Xiaomei, Yang, Ruijin
• Format: Journal Article
• Language: English
• Published: United States American Chemical Society 21.12.2022
• Subjects: Biotechnology and Biological Transformations; Cellobiose - metabolism; Isomerism; Lactose - chemistry; Lactulose - chemistry; Racemases and Epimerases - genetics; Racemases and Epimerases - metabolism; Substrate Specificity; binding region; cellobiose 2-epimerase; substrate affinity; isomerization activity; molecular dynamics simulation
• ISSN: 0021-8561; 1520-5118; 1520-5118
• DOI: 10.1021/acs.jafc.2c06980

Enzymatic isomerization of lactose into lactulose via cellobiose 2-epimerase (CE) could provide an eco-friendly route for the industrial production of lactulose, a valuable food prebiotic. However, poor substrate affinity for lactose and preference for epimerization over isomerization hinder this application. Previous studies on CE improvement have focused on random mutagenesis or active site rational design; little is known about the relationship between substrate binding and enzyme efficacy, which was hence the subject of this study. First, residues 372W and 308W were identified as key for disaccharide recognition in CEs based on crystal structure alignment of the N-acetyl-glucosamine 2-epimerase superfamily and site-directed mutation. This binding domain was then reshaped through site saturation mutagenesis, resulting in seven mutants with enhanced isomerization activity. The optimal mutant CsCE/Q371E had significantly enhanced substrate affinity (K m, 269.65 mM vs K m, 417.5 mM), reduced epimerization activity, and 3.3-fold increased isomerization activity over the original CsCE. Molecular dynamics simulation further revealed that substituting Gln-371 with Glu strengthened the hydrogen-bonding network and altered the active site–substrate interactions, increasing the substrate stability and shifting the catalytic direction. This study uncovered new information about the substrate binding region and its mechanisms and impact on CE catalytic performance, paving the way for potential commercial applications.