单加氧酶
化学
酶
多糖
辅因子
生物化学
生物催化
过氧化氢
催化作用
溶解循环
生物
反应机理
病毒学
细胞色素P450
病毒
作者
Bastien Bissaro,Åsmund K. Røhr,Gerdt Müller,Piotr Chylenski,Morten Skaugen,Zarah Forsberg,Svein Jarle Horn,Gustav Vaaje-Kolstad,Vincent G. H. Eijsink
标识
DOI:10.1038/nchembio.2470
摘要
Enzymes currently known as lytic polysaccharide monooxygenases (LPMOs) play an important role in the conversion of recalcitrant polysaccharides, but their mode of action has remained largely enigmatic. It is generally believed that catalysis by LPMOs requires molecular oxygen and a reductant that delivers two electrons per catalytic cycle. Using enzyme assays, mass spectrometry and experiments with labeled oxygen atoms, we show here that H2O2, rather than O2, is the preferred co-substrate of LPMOs. By controlling H2O2 supply, stable reaction kinetics are achieved, the LPMOs work in the absence of O2, and the reductant is consumed in priming rather than in stoichiometric amounts. The use of H2O2 by a monocopper enzyme that is otherwise cofactor-free offers new perspectives regarding the mode of action of copper enzymes. Furthermore, these findings have implications for the enzymatic conversion of biomass in Nature and in industrial biorefining.
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