Improvement of substrate specificity of the direct electron transfer type FAD-dependent glucose dehydrogenase catalytic subunit

IF 4.1 2区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Joseph A. Kerrigan Jr. , Hiromi Yoshida , Junko Okuda-Shimazaki , Brenda Temple , Katsuhiro Kojima , Koji Sode
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引用次数: 0

Abstract

The heterotrimeric flavin adenine dinucleotide (FAD) dependent glucose dehydrogenase derived from Burkholderia cepacia (BcGDH) has many exceptional features for its use in glucose sensing—including that this enzyme is capable of direct electron transfer with an electrode in its heterotrimeric configuration. However, this enzyme’s high catalytic activity towards not only glucose but also galactose presents an engineering challenge. To increase the substrate specificity of this enzyme, it must be engineered to reduce its activity towards galactose while maintaining its activity towards glucose. To aid in these mutagenesis studies, the crystal structure composed of BcGDH’s small subunit and catalytic subunit (BcGDHγα), in complex with D-glucono-1,5-lactone was elucidated and used to construct the three-dimensional model for targeted, site-directed mutagenesis. BcGDHγα was then mutated at three different residues, glycine 322, asparagine 474 and asparagine 475. The single mutations that showed the greatest glucose selectivity were combined to create the resulting mutant, α-G322Q-N474S-N475S. The α-G322Q-N474S-N475S mutant and BcGDHγα wild type were then characterized with dye-mediated dehydrogenase activity assays to determine their kinetic parameters. The α-G322Q-N474S-N475S mutant showed more than a 2-fold increase in Vmax towards glucose and this mutant showed a lower activity towards galactose in the physiological range (5 mM) of 4.19 U mg−1, as compared to the wild type, 86.6 U mg−1. This resulting increase in specificity lead to an 81.7 gal/glc % activity for the wild type while the α-G322Q-N474S-N475S mutant had just 10.9 gal/glc % activity at 5 mM. While the BcGDHγα wild type has high specificity towards galactose, our engineering α-G322Q-N474S-N475S mutant showed concentration dependent response to glucose and was not affected by galactose.
改善直接电子传递型 FAD 依赖性葡萄糖脱氢酶催化亚基的底物特异性。
来源于伯克霍尔德头孢菌素的依赖于黄素腺嘌呤二核苷酸(FAD)的异三聚体葡萄糖脱氢酶(BcGDH)在葡萄糖传感中的应用具有许多特殊的功能,包括这种酶能够在其异三聚体构型中与电极直接进行电子转移。然而,这种酶不仅对葡萄糖具有高催化活性,而且对半乳糖也具有高催化活性,这给工程设计带来了挑战。为了提高这种酶的底物特异性,必须对其进行工程改造,以降低其对半乳糖的特异性,同时保持其对葡萄糖的活性。为了帮助这些诱变研究,我们阐明了 BcGDH 的小亚基和催化亚基(BcGDHγα)与 D-葡萄糖醛酸-1,5-内酯复合物的晶体结构,并利用该结构构建了用于靶向定点诱变的三维模型。然后对 BcGDHγα 的三个不同残基(甘氨酸 322、天冬酰胺 474 和天冬酰胺 475)进行了突变,将显示出最大葡萄糖选择性的单个突变结合起来,产生了突变体 α-G322Q-N474S-N475S。α-G322Q-N474S-N475S突变体和BcGDHγα野生型随后通过染料介导的脱氢酶活性测定来确定其动力学参数。与野生型的 86.6 U mg-1 相比,α-G322Q-N474S-N475S 突变体在生理范围(5mM)内对葡萄糖的活性较低,仅为 4.19 U mg-1。这种特异性的增加导致野生型的活性为 81.7gal/glc %,而 α-G322Q-N474S-N475S 突变体在 5mM 时的活性仅为 10.9gal/glc %。虽然 BcGDHγα 野生型对半乳糖具有高度特异性,但我们的工程α-G322Q-N474S-N475S 突变体对葡萄糖的反应具有浓度依赖性,不受半乳糖的影响。
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来源期刊
Journal of biotechnology
Journal of biotechnology 工程技术-生物工程与应用微生物
CiteScore
8.90
自引率
2.40%
发文量
190
审稿时长
45 days
期刊介绍: The Journal of Biotechnology has an open access mirror journal, the Journal of Biotechnology: X, sharing the same aims and scope, editorial team, submission system and rigorous peer review. The Journal provides a medium for the rapid publication of both full-length articles and short communications on novel and innovative aspects of biotechnology. The Journal will accept papers ranging from genetic or molecular biological positions to those covering biochemical, chemical or bioprocess engineering aspects as well as computer application of new software concepts, provided that in each case the material is directly relevant to biotechnological systems. Papers presenting information of a multidisciplinary nature that would not be suitable for publication in a journal devoted to a single discipline, are particularly welcome.
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