Mutagenesis and subsite mapping underpin the importance for substrate specificity of the aglycon subsites of glycoside hydrolase family 11 xylanases.

Glycoside hydrolase family (GH) 11 xylanase A from Bacillus subtilis (BsXynA) was subjected to site-directed mutagenesis to probe the role of aglycon active site residues with regard to activity, binding of decorated substrates and hydrolysis product profile. Targets were those amino acids identified to be important by 3D structure analysis of BsXynA in complex with substrate bound in the glycon subsites and the +1 aglycon subsite. Several aromatic residues in the aglycon subsites that make strong substrate-protein interactions and that are indispensable for enzyme activity, were also important for the specificity of the xylanase. In the +2 subsite of BsXynA, Tyr65 and Trp129 were identified as residues that are involved in the binding of decorated substrates. Most interestingly, replacement of Tyr88 by Ala in the +3 subsite created an enzyme able to produce a wider variety of hydrolysis products than wild type BsXynA. The contribution of the +3 subsite to the substrate specificity of BsXynA was established more in detail by mapping the enzyme binding site of the wild type xylanase and mutant Y88A with labelled xylo-oligosaccharides. Also, the length of the cord - a long loop flanking the aglycon subsites of GH11 xylanases - proved to impact the hydrolytic action of BsXynA. The aglycon side of the active site cleft of BsXynA, therefore, offers great potential for engineering and design of xylanases with a desired specificity.