Abstract
1,3–1,4-β-glucanase is an important biocatalyst in brewing industry and animal feed industry, while its low thermostability often reduces its application performance. In this study, the thermostability of a mesophilic β-glucanase from Bacillus terquilensis was enhanced by rational design and engineering of disulfide bonds in the protein structure. Protein spatial configuration was analyzed to pre-exclude the residues pairs which negatively conflicted with the protein structure and ensure the contact of catalytic center. The changes in protein overall and local flexibility among the wild-type enzyme and the designated mutants were predicted to select the potential disulfide bonds for enhancement of thermostability. Two residue pairs (N31C-T187C and P102C-N125C) were chosen as engineering targets and both of them were proved to significantly enhance the protein thermostability. After combinational mutagenesis, the double mutant N31C-T187C/P102C-N125C showed a 48.3% increase in half-life value at 60°C and a 4.1°C rise in melting temperature (Tm) compared to wild-type enzyme. The catalytic property of N31C-T187C/P102C-N125C mutant was similar to that of wild-type enzyme. Interestingly, the optimal pH of double mutant was shifted from pH6.5 to pH6.0, which could also increase its industrial application. By comparison with mutants with single-Cys substitutions, the introduction of disulfide bonds and the induced new hydrogen bonds were proved to result in both local and overall rigidification and should be responsible for the improved thermostability. Therefore, the introduction of disulfide bonds for thermostability improvement could be rationally and highly-effectively designed by combination with spatial configuration analysis and molecular dynamics simulation.
Highlights
A total of 28 potential residue pairs were predicted to meet the geometric parameters for the formation of disulfide bonds excluding the native one (C32-C61) in BglTM by Disulfide by design (DbD) software (S2 Table)
The combinational screening method considering of spatial configuration of secondary structures, catalytic center, local and overall protein flexibility proved to be high effective
Two disulfide bonds (N31C-T187C and P102C-N125C) were directly selected from 28 potential residue pairs, which enhanced the thermostability of β-glucanase
Summary
1,3–1,4-β-glucanases (1,3–1,4-β-D-glucan 4-glucanohydrolase; EC 3.2.1.73) can hydrolyze high molecular weight β-glucans into oligosaccharides and they are widely applied in beer brewing and animal feed industries [1]. In the animal feed industry, especially for broiler chicken and piglets, the addition of β-glucanases can improve the digestibility of cereal-based feed and reduce sanitary problems [3]. In both industries, the performance of β-glucanases is greatly dependent upon their thermostability and acidic pH stability. Other biochemical properties, including pH stability and catalytic efficiency, of the mutants were characterized and compared with wild-type enzyme To our knowledge, this was the first study which improved the thermostability of 1,3–1,4-β-glucanases by disulfide bond engineering
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