A modular enzyme with combined hemicellulose-removing and LPMO activity increases cellulose accessibility in softwood.

Zarah Forsberg, Tina R Tuveng, Vincent G H Eijsink
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Abstract

Because of the association with other complex polysaccharides, extracting and utilizing cellulose from lignocellulosic materials requires the combined action of a broad range of carbohydrate-active enzymes, including multiple glycoside hydrolases (GHs) and lytic polysaccharide monooxygenases (LPMOs). The interplay between these enzymes and the way in which Nature orchestrates their co-existence and combined action are topics of great scientific and industrial interest. To gain more insight into these issues, we have studied the lignocellulose-degrading abilities of an enzyme from Caldibacillus cellulovorans (CcLPMO10-Man5), comprising an LPMO domain, a GH5 mannanase domain and two family 3 carbohydrate-binding modules (CBM3). Using a natural softwood substrate, we show that this enzyme promotes cellulase activity, i.e., saccharification of cellulose, both by removing mannan covering the cellulose and by oxidatively breaking up the cellulose structure. Synergy with CcLPMO10-Man5 was most pronounced for two tested cellobiohydrolases, whereas effects were smaller for a tested endoglucanase, which is in line with the notion that cellobiohydrolases and LPMOs attack the same crystalline regions of the cellulose, whereas endoglucanases attack semi-crystalline and amorphous regions. Importantly, the LPMO domain of CcLPMO10-Man5 is incapable of accessing the softwood cellulose in absence of the mannanase domain. Considering that LPMOs not bound to a substrate are sensitive to autocatalytic inactivation, this intramolecular synergy provides a perfect rationale for the evolution of modular enzymes such as CcLPMO10-Man5. The intramolecular coupling of the LPMO with a mannanase and two CBMs ensures that the LPMO is directed to areas where mannans are removed and cellulose thus becomes available.

一种兼具半纤维素去除和 LPMO 活性的模块化酶可提高软木中纤维素的可及性。
由于纤维素与其他复杂多糖的结合,从木质纤维素材料中提取和利用纤维素需要多种碳水化合物活性酶的共同作用,包括多种糖苷水解酶(GHs)和溶解多糖单氧酶(LPMOs)。这些酶之间的相互作用以及大自然如何协调它们的共存和联合作用,是科学界和工业界非常感兴趣的话题。为了更深入地了解这些问题,我们研究了来自钙化纤维芽孢杆菌的一种酶(CcLPMO10-Man5)的木质纤维素降解能力,该酶由一个 LPMO 结构域、一个 GH5 甘氨酸酶结构域和两个 3 族碳水化合物结合模块(CBM3)组成。我们利用一种天然软木底物证明,这种酶通过去除覆盖在纤维素上的甘露聚糖和氧化分解纤维素结构,促进纤维素酶的活性,即纤维素的糖化。与 CcLPMO10-Man5 的协同作用对两种测试的纤维素水解酶最为明显,而对一种测试的内切葡聚糖酶的影响较小,这符合纤维素水解酶和 LPMO 攻击纤维素的相同结晶区域,而内切葡聚糖酶攻击半结晶和无定形区域的观点。重要的是,在没有甘露聚糖酶结构域的情况下,CcLPMO10-Man5 的 LPMO 结构域无法进入软木纤维素。考虑到未与底物结合的 LPMO 对自动催化失活很敏感,这种分子内协同作用为 CcLPMO10-Man5 等模块化酶的进化提供了完美的理由。LPMO 与一种甘露聚糖酶和两种 CBM 的分子内耦合确保了 LPMO 被导向甘露聚糖被去除的区域,从而使纤维素变得可用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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