Department of Applied Chemistry, National Chiao Tung University, Science Building 2, 1001 Ta Hsueh Road, Hsinchu, 30010, Taiwan.
Life Science Group, Scientific Research Division, National Synchrotron Radiation Research Center, 101 Hsin-Ann Road, Hsinchu, 30076, Taiwan.
Appl Microbiol Biotechnol. 2016 Oct;100(19):8411-24. doi: 10.1007/s00253-016-7536-2. Epub 2016 May 20.
Glycosyltransferase-1 from Bacillus cereus (BcGT1) catalyzes a reaction that transfers a glucosyl moiety to flavonoids, such as quercetin, kaempferol, and myricetin. The enzymatic glucosidation shows a broad substrate specificity when the reaction is catalyzed by wild-type BcGT1. Preliminary assays demonstrated that the F240A mutant significantly improves the regioselectivity of enzymatic glucosidation toward quercetin. To unveil and further to control the catalytic function of BcGT1, mutation of F240 to other amino acids, such as C, E, G, R, Y, W, and K, was performed. Among these mutants, F240A, F240G, F240R, and F240K greatly altered the regioselectivity. The quercetin-3-O-glucoside, instead of quercetin-7-O-glucoside as for the wild-type enzyme, was obtained as the major product. Among these mutants, F240R showed nearly 100 % product specificity but only retained 25 % catalytic efficiency of wild-type enzyme. From an inspection of the protein structure, we found two other amino acids, F132 and F138, together with F240, are likely to form a hydrophobic binding region, which is sufficiently spacious to accommodate substrates with varied aromatic moieties. Through the replacement of a phenylalanine by a tyrosine residue in the substrate-binding region, the mutants may be able to fix the orientation of flavonoids, presumably through the formation of a hydrogen bond between substrates and mutants. Multiple mutants-F240R_F132Y, F240R_F138Y, and F240R_F132Y_F138Y-were thus constructed for further investigation. The multiple points of mutants not only maintained the high product specificity but also significantly improved the catalytic efficiency, relative to F240R. The same product specificity was obtained when kaempferol and myricetin were used as a substrate.
来自蜡状芽孢杆菌(Bacillus cereus)的糖基转移酶-1(BcGT1)催化将葡萄糖基转移到类黄酮(如槲皮素、山奈酚和杨梅素)的反应。当野生型 BcGT1 催化反应时,酶促葡糖苷化显示出广泛的底物特异性。初步实验表明,F240A 突变体显著提高了酶促葡糖苷化对槲皮素的区域选择性。为了揭示和进一步控制 BcGT1 的催化功能,对 F240 进行了突变为其他氨基酸,如 C、E、G、R、Y、W 和 K。在这些突变体中,F240A、F240G、F240R 和 F240K 极大地改变了区域选择性。与野生型酶相比,主要产物是槲皮素-3-O-葡糖苷,而不是槲皮素-7-O-葡糖苷。在这些突变体中,F240R 表现出近 100%的产物特异性,但仅保留了野生型酶 25%的催化效率。通过检查蛋白质结构,我们发现另外两个氨基酸 F132 和 F138 与 F240 一起可能形成一个疏水性结合区域,该区域足够宽敞,可以容纳具有不同芳香基团的底物。通过在底物结合区域用酪氨酸取代苯丙氨酸,突变体可能能够固定类黄酮的取向,推测是通过在底物和突变体之间形成氢键。因此,构建了多个突变体-F240R_F132Y、F240R_F138Y 和 F240R_F132Y_F138Y 进行进一步研究。与 F240R 相比,多点突变体不仅保持了高产物特异性,而且还显著提高了催化效率。当使用山奈酚和杨梅素作为底物时,也获得了相同的产物特异性。
