Improved thermostability, acid tolerance as well as catalytic efficiency of Streptomyces rameus L2001 GH11 xylanase by N-terminal replacement

The N-terminal of xylanase from 11 family of glycoside hydrolases (GH11 xylanase) has an important effect on its thermostability and catalytic properties. Previous studies have unearthed five important residues located in the N-terminal and successfully improved the thermostability of several GH11 xylanases using amino acid substitutions. In the present study, we applied this tactic to construct a mutant of XynA from Streptomyces rameus L2001, XynAR, and studied its biochemical, catalytic and hydrolytic properties. The results showed that thermostability, acid tolerance as well as catalytic efficiency of XynAR significantly improved compared to those of XynA, while the hydrolytic characteristics changed. Computer simulation analysis showed that this tactic created new hydrogen bonds and electrostatic interactions in the N-terminal, resulting in decrease in the flexibility of N-terminal and surface electrostatic potential as well as a change in the profile of hydrogen bonds between the subsites and substrate in the cleft region of xylanase. This study showed that amino acid substitutions at the key sites of the N-terminal of GH11 xylanase can improve its thermostability and catalytic properties.