EC Number |
Application |
Reference |
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1.14.99.54 | degradation |
in presence of a Trichoderma reesei CL847 cocktail composed of mainly cellulases and xylanases, a boost of glucose release from poplar and pine is observed upon addition of AA14B enzyme to the cocktail. Addition of AA14A to a GH11 xylanase increases the release of xylooligomers from birchwood cellulosic fibers by 40% |
745847 |
1.14.99.54 | degradation |
In the presence of an electron source, LPMO increases the activity of a commercial cellulase on filter paper, and the xylanase activity of xylanase Xyn10A on beechwood xylan. Mixtures of 60% Celluclast 1.5 L, 20% Xyn10A and 20% LPMO increase the total reducing sugar production from pretreated wheat straw by 54%, while the conversions of glucan to glucose and xylan to xylose are increased by 40 and 57%, respectively |
-, 744804 |
1.14.99.54 | degradation |
lytic polysaccharide monooxygenase is able to cleave cellulose acetates with a degree of acetylation of up to 1.4 |
744639 |
1.14.99.54 | degradation |
oxidative activity of Cel61A displays a synergistic effect capable of boosting endoglucanase activity, and thereby substrate depolymerization of soy cellulose, by 27% |
744815 |
1.14.99.54 | degradation |
the intrinsic physicochemical characteristics of Kraft pulp fibers (e.g. cellulose accessibility/degree of polymerization/crystallinity/charge) are positively enhanced by the synergistic cooperation of endoglucanase, LPMO and xylanase. LPMO addition results in the oxidative cleavage of the pulps, increasing the negative charge on the cellulose fibers, although gross fiber properties (fiber length, width and morphology) are relatively unchanged. This improves cellulose nanofibrilliation while stabilizing the nanofibril suspension, without sacrificing nanocellulose thermostability |
746487 |
1.14.99.54 | degradation |
treatment with CelS2 reduces nonproductive binding of cellobiohydrolase onto cellulose surface |
-, 740287 |