De Lemos Esteves Frédéric, Gouders Thierry, Lamotte-Brasseur Josette, Rigali Sébastien, Frère Jean-Marie
Centre d'Ingénierie des Protéines, Institut de Chimie, B6a, Université de Liège, Sart Tilman, B-4000 Liège, Belgium.
Protein Sci. 2005 Feb;14(2):292-302. doi: 10.1110/ps.04978705.
Endo-beta-1,4-xylanases of the family 11 glycosyl-hydrolases are catalytically active over a wide range of pH. Xyl1 from Streptomyces sp. S38 belongs to this family, and its optimum pH for enzymatic activity is 6. Xyn11 from Bacillus agaradhaerens and XylJ from Bacillus sp. 41M-1 share 85% sequence identity and have been described as highly alkalophilic enzymes. In an attempt to better understand the alkalophilic adaptation of xylanases, the three-dimensional structures of Xyn11 and Xyl1 were compared. This comparison highlighted an increased number of salt-bridges and the presence of more charged residues in the catalytic cleft as well as an eight-residue-longer loop in the alkalophilic xylanase Xyn11. Some of these charges were introduced in the structure of Xyl1 by site-directed mutagenesis with substitutions Y16D, S18E, G50R, N92D, A135Q, E139K, and Y186E. Furthermore, the eight additional loop residues of Xyn11 were introduced in the homologous loop of Xyl1. In addition, the coding sequence of the XylJ catalytic domain was synthesized by recursive PCR, expressed in a Streptomyces host, purified, and characterized together with the Xyl1 mutants. The Y186E substitution inactivated Xyl1, but the activity was restored when this mutation was combined with the G50R or S18E substitutions. Interestingly, the E139K mutation raised the optimum pH of Xyl1 from 6 to 7.5 but had no effect when combined with the N92D substitution. Modeling studies identified the possible formation of an interaction between the introduced lysine and the substrate, which could be eliminated by the formation of a putative salt-bridge in the N92D/E139K mutant.
11 家族糖基水解酶的内切-β-1,4-木聚糖酶在很宽的 pH 范围内都具有催化活性。链霉菌属 S38 的 Xyl1 属于该家族,其酶活性的最适 pH 为 6。嗜碱芽孢杆菌的 Xyn11 和芽孢杆菌属 41M-1 的 XylJ 具有 85%的序列同一性,被描述为高度嗜碱酶。为了更好地理解木聚糖酶的嗜碱适应性,对 Xyn11 和 Xyl1 的三维结构进行了比较。这种比较突出显示,嗜碱木聚糖酶 Xyn11 的盐桥数量增加,催化裂隙中存在更多带电荷残基,并且有一个长八个残基的环。通过定点诱变,用 Y16D、S18E、G50R、N92D、A135Q、E139K 和 Y186E 替换,在 Xyl1 的结构中引入了其中一些电荷。此外,将 Xyn11 的另外八个环残基引入 Xyl1 的同源环中。另外,通过递归 PCR 合成了 XylJ 催化结构域的编码序列,在链霉菌宿主中表达、纯化,并与 Xyl1 突变体一起进行了表征。Y186E 替换使 Xyl1 失活,但当该突变与 G50R 或 S18E 替换结合时,活性得以恢复。有趣的是,E139K 突变将 Xyl1 的最适 pH 从 6 提高到了 7.5,但与 N92D 替换结合时没有效果。建模研究确定了引入的赖氨酸与底物之间可能形成相互作用,而在 N92D/E139K 突变体中,这种相互作用可能会因假定的盐桥形成而消除。