Floor Robert J, Wijma Hein J, Colpa Dana I, Ramos-Silva Aline, Jekel Peter A, Szymański Wiktor, Feringa Ben L, Marrink Siewert J, Janssen Dick B
Department of Biochemistry, Groningen Biomolecular Sciences and Biotechnology Institute, University of Groningen, Nijenborgh 4, 9747 AG Groningen (The Netherlands).
Chembiochem. 2014 Jul 21;15(11):1660-72. doi: 10.1002/cbic.201402128. Epub 2014 Jun 27.
We explored the use of a computational design framework for the stabilization of the haloalkane dehalogenase LinB. Energy calculations, disulfide bond design, molecular dynamics simulations, and rational inspection of mutant structures predicted many stabilizing mutations. Screening of these in small mutant libraries led to the discovery of seventeen point mutations and one disulfide bond that enhanced thermostability. Mutations located in or contacting flexible regions of the protein had a larger stabilizing effect than mutations outside such regions. The combined introduction of twelve stabilizing mutations resulted in a LinB mutant with a 23 °C increase in apparent melting temperature (Tm,app , 72.5 °C) and an over 200-fold longer half-life at 60 °C. The most stable LinB variants also displayed increased compatibility with co-solvents, thus allowing substrate conversion and kinetic resolution at much higher concentrations than with the wild-type enzyme.
我们探索了一种用于稳定卤代烷脱卤酶LinB的计算设计框架。能量计算、二硫键设计、分子动力学模拟以及对突变体结构的合理检查预测了许多稳定化突变。在小型突变体文库中对这些突变进行筛选,发现了17个点突变和1个增强热稳定性的二硫键。位于蛋白质柔性区域内或与之接触的突变比此类区域外的突变具有更大的稳定化作用。同时引入12个稳定化突变产生了一个LinB突变体,其表观解链温度(Tm,app)提高了23℃(达到72.5℃),并且在60℃下的半衰期延长了200多倍。最稳定的LinB变体还表现出与共溶剂的兼容性增强,因此与野生型酶相比,能够在高得多的浓度下进行底物转化和动力学拆分。
