热稳定性
双功能
四聚体
固定化酶
合理设计
组合化学
蛋白质工程
生物催化
化学
热稳定性
动力学
磷酸果糖激酶2
生物化学
仿生材料
分子动力学
化学工程
熔点
糖
色谱法
酶
突变体
作者
Ziyi Li,Jiangang Yang,Yan Men,Ying Yang,Yueming Zhu,Yuanxia Sun
标识
DOI:10.1021/acs.jafc.5c09729
摘要
d-allulose, a low-calorie rare sugar produced by d-allulose 3-epimerase (DAE), has broad application potential, but its production is limited by the poor thermostability and immobilization efficiency of DAE. In this study, a multimerization-promoting tag (Mp-tag) was fused to the N-terminus of DAE from Ruminococcus sp. (RDAE), targeting the dimer-dimer interface of its tetrameric structure. The optimized triple mutant Mp-tag enhanced interdimer interactions, increasing the melting temperature from 64.9 °C (without Mp-tag) to 71.8 °C. Molecular dynamics simulations confirmed that Mp-tag stabilized tetramer formation by lowering interdimer binding free energy. To improve immobilization, a glutamate-rich immobilization-promoting tag (Ip-tag) was fused to the N-terminus of the Mp-tag, enhancing site-specific binding and increasing immobilized activity recovery by 30.69%. The resulting immobilized bifunctional-tagged enzyme retained over 90% activity after 500 reaction cycles. This strategy also proved effective for other tetrameric DAEs, demonstrating its general applicability for enhancing enzyme stability and immobilization in biocatalytic processes.
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