McKee Lauren S, Sunner Hampus, Anasontzis George E, Toriz Guillermo, Gatenholm Paul, Bulone Vincent, Vilaplana Francisco, Olsson Lisbeth
Wallenberg Wood Science Centre, Division of Glycoscience, School of Biotechnology, KTH Royal Institute of Technology, AlbaNova University Centre, 106 91 Stockholm, Sweden.
Wallenberg Wood Science Centre, Division of Industrial Biotechnology, Department of Biology and Biological Engineering, Chalmers University of Technology, 412 96 Gothenburg, Sweden.
Biotechnol Biofuels. 2016 Jan 4;9:2. doi: 10.1186/s13068-015-0417-6. eCollection 2016.
Lignocellulosic biomass from softwood represents a valuable resource for the production of biofuels and bio-based materials as alternatives to traditional pulp and paper products. Hemicelluloses constitute an extremely heterogeneous fraction of the plant cell wall, as their molecular structures involve multiple monosaccharide components, glycosidic linkages, and decoration patterns. The complete enzymatic hydrolysis of wood hemicelluloses into monosaccharides is therefore a complex biochemical process that requires the activities of multiple degradative enzymes with complementary activities tailored to the structural features of a particular substrate. Glucuronoarabinoxylan (GAX) is a major hemicellulose component in softwood, and its structural complexity requires more enzyme specificities to achieve complete hydrolysis compared to glucuronoxylans from hardwood and arabinoxylans from grasses.
We report the characterisation of a recombinant α-glucuronidase (Agu115) from Schizophyllum commune capable of removing (4-O-methyl)-glucuronic acid ((Me)GlcA) residues from polymeric and oligomeric xylan. The enzyme is required for the complete deconstruction of spruce glucuronoarabinoxylan (GAX) and acts synergistically with other xylan-degrading enzymes, specifically a xylanase (Xyn10C), an α-l-arabinofuranosidase (AbfA), and a β-xylosidase (XynB). Each enzyme in this mixture showed varying degrees of potentiation by the other activities, likely due to increased physical access to their respective target monosaccharides. The exo-acting Agu115 and AbfA were unable to remove all of their respective target side chain decorations from GAX, but their specific activity was significantly boosted by the addition of the endo-Xyn10C xylanase. We demonstrate that the proposed enzymatic cocktail (Agu115 with AbfA, Xyn10C and XynB) achieved almost complete conversion of GAX to arabinofuranose (Araf), xylopyranose (Xylp), and MeGlcA monosaccharides. Addition of Agu115 to the enzymatic cocktail contributes specifically to 25 % of the conversion. However, traces of residual oligosaccharides resistant to this combination of enzymes were still present after deconstruction, due to steric hindrances to enzyme access to the substrate.
Our GH115 α-glucuronidase is capable of finely tailoring the molecular structure of softwood GAX, and contributes to the almost complete saccharification of GAX in synergy with other exo- and endo-xylan-acting enzymes. This has great relevance for the cost-efficient production of biofuels from softwood lignocellulose.
软木中的木质纤维素生物质是生产生物燃料和生物基材料的宝贵资源,可替代传统的纸浆和纸张产品。半纤维素是植物细胞壁中极其不均一的部分,因为其分子结构涉及多种单糖成分、糖苷键和修饰模式。因此,将木材半纤维素完全酶解为单糖是一个复杂的生化过程,需要多种具有互补活性的降解酶,这些酶的活性是根据特定底物的结构特征量身定制的。葡糖醛酸阿拉伯木聚糖(GAX)是软木中的主要半纤维素成分,与硬木中的葡糖醛酸木聚糖和禾本科植物中的阿拉伯木聚糖相比,其结构复杂性需要更多的酶特异性才能实现完全水解。
我们报道了一种来自裂褶菌的重组α-葡糖醛酸酶(Agu115)的特性,该酶能够从聚合和寡聚木聚糖中去除(4-O-甲基)-葡糖醛酸((Me)GlcA)残基。该酶是云杉葡糖醛酸阿拉伯木聚糖(GAX)完全解构所必需的,并且与其他木聚糖降解酶协同作用,特别是一种木聚糖酶(Xyn10C)、一种α-L-阿拉伯呋喃糖苷酶(AbfA)和一种β-木糖苷酶(XynB)。该混合物中的每种酶都因其他活性而表现出不同程度的增强作用,这可能是由于对其各自目标单糖的物理接触增加所致。外切作用的Agu115和AbfA无法从GAX中去除所有各自的目标侧链修饰,但通过添加内切Xyn10C木聚糖酶,它们的比活性显著提高。我们证明,所提出的酶混合物(Agu115与AbfA、Xyn10C和XynB)几乎能将GAX完全转化为阿拉伯呋喃糖(Araf)、木吡喃糖(Xylp)和MeGlcA单糖。向酶混合物中添加Agu115对转化的贡献率为25%。然而,解构后仍存在对这种酶组合有抗性的痕量残留寡糖,这是由于酶接近底物时存在空间位阻。
我们的GH115α-葡糖醛酸酶能够精细调整软木GAX的分子结构,并与其他外切和内切木聚糖作用酶协同作用,有助于GAX几乎完全糖化。这对于从软木木质纤维素中经济高效地生产生物燃料具有重要意义。
