The role of the C domain in the thermostability of GH70 enzymes investigated by domain swapping

Abstract

Abstract Sucrose-active enzymes belonging to the glycoside hydrolase (GH) family 70 are attractive tools for the synthesis of oligosaccharides, polysaccharides or glycoconjugates. However, their thermostability is an important issue for the development of robust and cost-effective enzyme-based processes. Indeed, GH70 enzymes are mesophilic and no thermophilic representatives have been described so far. Furthermore, structurally guided engineering is a challenge given the size of these proteins (120 to 250 kDa) and their organization in five domains. Herein, we have investigated the possible role of the domain C in the stability of GH70 enzymes. The alternansucrase (ASR) is the most stable enzyme of the GH70 family. Structural comparison of ASR to other GH70 enzymes highlighted the compactness of its domain C. We assumed that this atypical structure might be involved in the stability of this enzyme and decided to introduce this domain in another much less stable GH70 enzyme of known three-dimensional structure, the branching sucrase GBD-CD2. The chimeric GBD-CD2 exhibited a lower specific activity on sucrose substrate but its specificity was unchanged with the enzyme remaining specific for the branching of dextran via α-1,2 linkage formation. Interestingly, the chimera showed a higher melting temperature and residual activity than the wild-type enzyme after 10 min incubation at 30 °C showing that the domain C can affect GH70 enzyme stability and could be a potential target of both random or rational mutagenesis to further improve their stability.