Effective degradation of hemicellulose is of utmost importance in a wide variety of applications in bioindustry. Five endoxylanases from different glycoside hydrolase families and microorganisms were tested with an arabinofuranosidase, Araf51A, for the hydrolysis of insoluble wheat arabinoxylan, which is a structural component of hemicellulose. The optimized combination was XynZ/Xyn11A/Araf51A with a loading ratio of 2:2:1, and the value of degree of synergy increased with the increase of Araf51A proportion in the enzyme mixture. Afterwards, selected enzymes were immobilized on commercial magnetic nanoparticles through covalent bonding. Both free and immobilized enzymes showed a similar conversion to reducing sugars after hydrolysis for 48 h. After 10 cycles, approximately 20% of the initial enzymatic activity of both the individual or mixture of immobilized enzymes was retained. A 5.5-fold increase in the production of sugars was obtained with a mixture of enzymes immobilized after 10 cycles in total compared with free enzymes. Importantly, a sustainable synergism between immobilized arabinofuranosidase and immobilized endoxylanases in the hydrolysis of arabinoxylan was demonstrated.
A novel artificial cellulase was developed by conjugating a DNA aptamer to an endoglucanase catalytic domain, thereby substituting the natural carbohydrate-binding module. Circular dichroism spectroscopy and adsorption isotherm showed the binding motif of cellulose-binding DNA aptamer (CelApt) was G-quadruplex and stem-loop structures stabilized in the presence of salts, and CelApt binding preferred the amorphous region of the solid cellulose. By introducing the revealed salt-switchable cellulose-binding nature of CelApt into a catalytic domain of a cellulase, we created CelApt-catalytic domain conjugate possessing both controllable adsorption on the solid substrates and equal enzymatic activity to the wild-type cellulase. Thus potential use of a responsive DNA aptamer for biocatalysis at a solid surface was demonstrated.
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