糖苷酶 BcX 活性位点的双模底物结合。

Mahin Saberi, Aleksandra Chikunova, Fredj Ben Bdira, Anneloes Cramer-Blok, Monika Timmer, Patrick Voskamp, Marcellus Ubbink
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引用次数: 0

摘要

环状芽孢杆菌木聚糖酶(BcX)属于糖苷水解酶家族 11,通过保留、双置换机制降解木聚糖。该酶被认为是以过程方式水解糖苷键,其活性位点裂隙较大,有六个亚位点,可结合六个木糖单元。这种活性位点结构表明,低聚木糖底物可以多种方式结合。在无催化活性的变体 BcX E78Q 的晶体结构中,可以观察到底物木三糖位于活性位点,并与已知的二级结合位点和蛋白质表面的第三个位点结合。用不同长度的木糖低聚物进行核磁共振(NMR)滴定,得到了活性位点核共振的非线性化学位移轨迹,表明这些底物有多种结合方向,其结合和解离在 NMR 时间尺度上快速交换,在微秒到毫秒的时间尺度上交换。活性位点结合可以用 2 :1 模型,解离常数在低摩尔和高摩尔范围内。对活性位点残基的广泛诱变表明,紧密结合发生在糖醛酸结合位点,并由 Trp9 和拇指区稳定。突变 F125A 和 W71A 会导致巨大的结构重排。糖元位点的结合在整个活性位点都有感应,而弱结合主要影响苷元位点。与这两个活性位点的相互作用在很大程度上是相互独立的,与次级结合位点的结合也是相互独立的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Bimodal substrate binding in the active site of the glycosidase BcX

Bimodal substrate binding in the active site of the glycosidase BcX

Bacillus circulans xylanase (BcX) from the glycoside hydrolase family 11 degrades xylan through a retaining, double-displacement mechanism. The enzyme is thought to hydrolyze glycosidic bonds in a processive manner and has a large, active site cleft, with six subsites allowing the binding of six xylose units. Such an active site architecture suggests that oligomeric xylose substrates can bind in multiple ways. In the crystal structure of the catalytically inactive variant BcX E78Q, the substrate xylotriose is observed in the active site, as well as bound to the known secondary binding site and a third site on the protein surface. Nuclear magnetic resonance (NMR) titrations with xylose oligomers of different lengths yield nonlinear chemical shift trajectories for active site nuclei resonances, indicative of multiple binding orientations for these substrates for which binding and dissociation are in fast exchange on the NMR timescale, exchanging on the micro- to millisecond timescale. Active site binding can be modeled with a 2 : 1 model with dissociation constants in the low and high millimolar range. Extensive mutagenesis of active site residues indicates that tight binding occurs in the glycon binding site and is stabilized by Trp9 and the thumb region. Mutations F125A and W71A lead to large structural rearrangements. Binding at the glycon site is sensed throughout the active site, whereas the weak binding mostly affects the aglycon site. The interactions with the two active site locations are largely independent of each other and of binding at the secondary binding site.

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