Modification of a Thermostable β-mannanase and Its High-Efficiency Expression

IF 0.5 4区 医学
Xiaochun Li
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Abstract

A β-mannanase from Aspergillus usamii (A. usamii) belonging to glycoside hydrolase (GH) family 5 (abbreviated as AuMan5A) was selected as the research subject to enhance the enzyme protein’s thermotolerance and catalytic efficiency by replacing a random coil (loop) structure on the enzyme molecule. Furthermore, the correlation between the structure and function of β-mannanase was clarified. Homology modeling was used to simulate the three-dimensional structure of AuMan5A, and mannopentaose was docked in the AuMan5A substrate binding groove. Based on the spatial characteristics and phylogenetic analyses of the complex structure, a non-conserved loop structure (Loop FG) was speculated to be involved in enzyme-substrate interactions. Therefore, Loop FG was selected as the modified region. Additionally, the corresponding fragments of Aspergillus nidulans, Aspergillus fumigatus, and Trichoderma harzianum β-mannanases were selected to replace the Loop FG sequence (316KSPDGGN322) of AuMan5A, respectively, based on the enzymological properties and structural characteristics of other fungal GH 5 family β-mannanases. Mutant enzyme bases were constructed by PCR, and using plasmid pPICZαA, the original and mutant enzymes were expressed in Pichia pastoris GS115 to analyze the enzymological properties of the expressed products. Recombinant enzymes re-AuMan5A, re-AuMan5A-Af, re-AuMan5A-An, and re-AuMan5A-Th had an optimum temperature of 65 °C, 75 °C, 65 °C, and 70 °C, respectively. Their activity half-lives at 70 °C were 10 min, 480 min, 5 min, and 25 min, respectively, and their melting temperatures were 64.5 °C, 76.6 °C, 63.2 °C, and 69.1 °C, respectively. Re-AuMan5A-Af, re-AuMan5A-An, and re-AuMan5A-Th had a kcat/km (catalytic efficiency) value that was 12.7, 6.0, and 11.0 times higher than re-AuMan5A, respectively, with re-AuMan5A-Af exhibiting the best temperature characteristics and catalytic efficiency. The G320-to-D320 mutation of AuMan5A during loop structure replacement significantly affected AuMan5A/Af’s enzymological properties, suggesting the vital role of G320 in improving AuMan5A/Af’s thermostability, specific activity, and catalytic efficiency.
耐热β-甘露聚糖酶的修饰及其高效表达
选择了一种来自美国曲霉(A.usamii)的β-甘露聚糖酶作为研究对象,该酶属于糖苷水解酶(GH)家族5(简称AuMan5A),通过取代酶分子上的随机线圈(环)结构来提高酶蛋白的耐热性和催化效率。进一步阐明了β-甘露聚糖酶的结构与功能之间的相关性。采用同源性建模方法模拟AuMan5A的三维结构,将甘露寡糖对接在AuMan5A底物结合槽中。基于该复杂结构的空间特征和系统发育分析,推测一种非保守环结构(loop-FG)参与了酶-底物的相互作用。因此,选择“循环FG”作为修改区域。此外,基于其他真菌GH 5家族β-甘露聚糖酶的酶学性质和结构特征,选择了相应的巢状曲霉、烟曲霉和哈茨木霉β-甘露聚糖酶片段分别取代AuMan5A的Loop-FG序列(316KSPDGGN322)。用聚合酶链式反应构建突变酶碱基,利用质粒pPICZαA在毕赤酵母GS115中表达原酶和突变酶,分析表达产物的酶学性质。重组酶re-AuMan5A、re-AuMan5A-Af、re-Au Man5A-An和re-Au man5A-Th的最适温度分别为65°C、75°C、65°C和70°C。它们在70°C下的活性半衰期分别为10分钟、480分钟、5分钟和25分钟,熔化温度分别为64.5°C、76.6°C、63.2°C和69.1°C。Re-AuMan5A-Af、Re-AuMan5A-An和Re-Au曼5A-Th的kcat/km(催化效率)值分别是Re-AuMan5A的12.7、6.0和11.0倍,其中Re-Au曼5A-Af表现出最佳的温度特性和催化效率。在环结构置换过程中,AuMan5A的G320-D320突变显著影响了AuMan5A/Af的酶学性质,表明G320在提高AuMan5A/Af的热稳定性、比活性和催化效率方面发挥着重要作用。
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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来源期刊
Journal of Biobased Materials and Bioenergy
Journal of Biobased Materials and Bioenergy 工程技术-材料科学:生物材料
自引率
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发文量
60
审稿时长
6 months
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