糖苷水解酶家族10木聚糖酶突变体形成稳定Ser-His催化双偶体促进氮偶分解。

IF 1.2 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Journal of applied glycoscience Pub Date : 2018-02-20 eCollection Date: 2018-01-01 DOI:10.5458/jag.jag.JAG-2017_011
Ryuichiro Suzuki, Zui Fujimoto, Satoshi Kaneko, Tsunemi Hasegawa, Atsushi Kuno
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引用次数: 3

摘要

糖苷水解酶的活性需要羧基作为催化剂。橄榄绿链霉菌E-86中的一种保留木聚糖酶属于糖苷水解酶家族10,具有Glu128和Glu236,分别具有酸/碱和亲核试剂的功能。我们之前开发了一种独特的保留木聚糖酶突变体N127S/E128H,其去糖基化是由叠氮化物触发的。晶体学研究表明,在反应循环中,ser - he催化二元体的短暂形成可能降低了叠氮解反应。在本研究中,我们通过位点诱变和对N127S/E128H的晶体学研究,设计了一种具有增强稳定性的催化二元体。N127S/E128H与pNP-X2和木戊糖的Michaelis配合物比较表明,Ser127可以与Thr82形成替代氢键,从而破坏Ser-His催化二元体的形成。在N127S/E128H中引入T82A突变,提高了一阶速率常数(是N127S/E128H的6倍)。我们证实了在三突变体的Michaelis复合体中存在一个稳定的Ser-His氢键,它形成了His128的生产性互变异构体,作为酸催化剂。由于叠氮糖基可应用于click化学的聚糖生物偶联,因此酶辅助合成叠氮糖基可为糖生物学领域的研究做出贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Enhanced Azidolysis by the Formation of Stable Ser-His Catalytic Dyad in a Glycoside Hydrolase Family 10 Xylanase Mutant.

Enhanced Azidolysis by the Formation of Stable Ser-His Catalytic Dyad in a Glycoside Hydrolase Family 10 Xylanase Mutant.

Enhanced Azidolysis by the Formation of Stable Ser-His Catalytic Dyad in a Glycoside Hydrolase Family 10 Xylanase Mutant.

Enhanced Azidolysis by the Formation of Stable Ser-His Catalytic Dyad in a Glycoside Hydrolase Family 10 Xylanase Mutant.

Glycoside hydrolases require carboxyl groups as catalysts for their activity. A retaining xylanase from Streptomyces olivaceoviridis E-86 belonging to glycoside hydrolase family 10 possesses Glu128 and Glu236 that respectively function as acid/base and nucleophile. We previously developed a unique mutant of the retaining xylanase, N127S/E128H, whose deglycosylation is triggered by azide. A crystallographic study reported that the transient formation of a Ser-His catalytic dyad in the reaction cycle possibly reduced the azidolysis reaction. In the present study, we engineered a catalytic dyad with enhanced stability by site-directed mutagenesis and crystallographic study of N127S/E128H. Comparison of the Michaelis complexes of N127S/E128H with pNP-X2 and with xylopentaose showed that Ser127 could form an alternative hydrogen bond with Thr82, which disrupts the formation of the Ser-His catalytic dyad. The introduction of T82A mutation in N127S/E128H produces an enhanced first-order rate constant (6 times that of N127S/E128H). We confirmed the presence of a stable Ser-His hydrogen bond in the Michaelis complex of the triple mutant, which forms the productive tautomer of His128 that acts as an acid catalyst. Because the glycosyl azide is applicable in the bioconjugation of glycans by using click chemistry, the enzyme-assisted production of the glycosyl azide may contribute to the field of glycobiology.

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来源期刊
Journal of applied glycoscience
Journal of applied glycoscience BIOCHEMISTRY & MOLECULAR BIOLOGY-
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