| Project Detail |
As the EU is committed to becoming the world’s first climate-neutral continent, fossil fuels need to be replaced by sustainable alternatives. A potential alternative is the upcycling of lignocellulosic biomass to biofuels. However, the cost-efficient generation of biofuel from cellulose is considerably hindered by the recalcitrance of the cellulose biopolymer. In 2010, the discovery of a new family of copper-dependent metalloenzymes called lytic polysaccharide monooxygenases (LPMOs) spurred great hopes as LPMOs were shown to significantly boost the degradation of cellulose and other polysaccharides.
Today, eight families of LPMOs have been classified with remarkably diverse substrate specificities and regioselectivities. Furthermore, the metal active sites are in rather different surroundings. Despite combined efforts from experimental and theoretical sides, the reaction mechanism of LPMOs has remained elusive. The here proposed “LyticPol” project suggests that previous theoretical studies lacked general conclusions because they (i) considered too few LPMO families and (ii) employed insufficient theoretical methods for the enzyme environment.
The “LyticPol” project aims at elucidating the reaction mechanism of LPMOs, by using a novel theoretical method on a large set of representative LPMO structures. From knowing the mechanism, the reaction conditions of LPMOs can be fine-tuned and the full industrial potential can be reached. This is expected to have substantial economic and social impact. Hence, the results of the “LyticPol” project will be communicated not only to scientific experts but also to the general public. The project will be carried out by Dr. Erna K. Wieduwilt (EKW) under the supervision of Prof. Erik D. Hedegård at the University of Southern Denmark. The project itself and the training of EKW will contribute decisively to her career goal of becoming an innovative and independent researcher in the field of theoretical bio-inorganic chemistry. |
