Structure-function relationships in Gan42B, an intracellular GH42 β-galactosidase from Geobacillus stearothermophilus.

IF 2.2 4区生物学

Acta Crystallographica Section D: Biological Crystallography Pub Date : 2015-12-01 DOI:10.1107/S1399004715018672

H. V. Solomon, Orly Tabachnikov, S. Lansky, R. Salama, H. Feinberg, Y. Shoham, G. Shoham

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引用次数: 19

Abstract

Geobacillus stearothermophilus T-6 is a Gram-positive thermophilic soil bacterium that contains a battery of degrading enzymes for the utilization of plant cell-wall polysaccharides, including xylan, arabinan and galactan. A 9.4 kb gene cluster has recently been characterized in G. stearothermophilus that encodes a number of galactan-utilization elements. A key enzyme of this degradation system is Gan42B, an intracellular GH42 β-galactosidase capable of hydrolyzing short β-1,4-galactosaccharides into galactose units, making it of high potential for various biotechnological applications. The Gan42B monomer is made up of 686 amino acids, and based on sequence homology it was suggested that Glu323 is the catalytic nucleophile and Glu159 is the catalytic acid/base. In the current study, the detailed three-dimensional structure of wild-type Gan42B (at 2.45 Å resolution) and its catalytic mutant E323A (at 2.50 Å resolution), as determined by X-ray crystallography, are reported. These structures demonstrate that the three-dimensional structure of the Gan42B monomer generally correlates with the overall fold observed for GH42 proteins, consisting of three main domains: an N-terminal TIM-barrel domain, a smaller mixed α/β domain, and the smallest all-β domain at the C-terminus. The two catalytic residues are located in the TIM-barrel domain in a pocket-like active site such that their carboxylic functional groups are about 5.3 Å from each other, consistent with a retaining mechanism. The crystal structure demonstrates that Gan42B is a homotrimer, resembling a flowerpot in general shape, in which each monomer interacts with the other two to form a cone-shaped tunnel cavity in the centre. The cavity is ∼35 Å at the wide opening and ∼5 Å at the small opening and ∼40 Å in length. The active sites are situated at the interfaces between the monomers, so that every two neighbouring monomers participate in the formation of each of the three active sites of the trimer. They are located near the small opening of the cone tunnel, all facing the centre of the cavity. The biological relevance of this trimeric structure is supported by independent results obtained from gel-permeation chromatography. These data and their comparison to the structural data of related GH42 enzymes are used for a more general discussion concerning structure-activity aspects in this GH family.

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嗜热硬脂地杆菌细胞内GH42 β-半乳糖苷酶Gan42B的结构-功能关系。

嗜热硬脂地杆菌T-6是一种革兰氏阳性的嗜热土壤细菌，它含有一组降解酶，用于利用植物细胞壁多糖，包括木聚糖、阿拉伯聚糖和半乳聚糖。最近在嗜热G. stearothermophilus中发现了一个9.4 kb的基因簇，该基因簇编码一些半乳糖利用元件。该降解系统的一个关键酶是Gan42B，一种细胞内GH42 β-半乳糖苷酶，能够将短的β-1,4-半乳糖水解成半乳糖单位，使其具有很高的生物技术应用潜力。Gan42B单体由686个氨基酸组成，根据序列同源性，Glu323是催化亲核试剂，Glu159是催化酸/碱。在目前的研究中，报道了通过x射线晶体学确定的野生型Gan42B(分辨率为2.45 Å)及其催化突变体E323A(分辨率为2.50 Å)的详细三维结构。这些结构表明，Gan42B单体的三维结构通常与GH42蛋白的整体折叠相关，由三个主要结构域组成:n端TIM-barrel结构域，较小的混合α/β结构域和c端最小的all-β结构域。两个催化残基位于tim -桶结构域的口袋状活性位点上，使得它们的羧基官能团彼此相距约5.3 Å，符合保留机制。晶体结构表明，Gan42B是一种同源三聚体，其一般形状类似花盆，其中每个单体与其他两个单体相互作用，在中心形成锥形隧道腔。宽开口的空腔尺寸为~ 35 Å，小开口的空腔尺寸为~ 5 Å，长度为~ 40 Å。活性位点位于单体之间的界面上，因此每两个相邻单体都参与三聚体三个活性位点的形成。它们位于锥形隧道的小开口附近，都面向洞的中心。这种三聚体结构的生物学相关性得到了凝胶渗透色谱独立结果的支持。这些数据及其与相关GH42酶的结构数据的比较用于更广泛地讨论该GH家族的结构-活性方面。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Acta Crystallographica Section D: Biological Crystallography 生物-晶体学

自引率

13.60%

发文量

审稿时长

3 months

期刊介绍： Acta Crystallographica Section D welcomes the submission of articles covering any aspect of structural biology, with a particular emphasis on the structures of biological macromolecules or the methods used to determine them. Reports on new structures of biological importance may address the smallest macromolecules to the largest complex molecular machines. These structures may have been determined using any structural biology technique including crystallography, NMR, cryoEM and/or other techniques. The key criterion is that such articles must present significant new insights into biological, chemical or medical sciences. The inclusion of complementary data that support the conclusions drawn from the structural studies (such as binding studies, mass spectrometry, enzyme assays, or analysis of mutants or other modified forms of biological macromolecule) is encouraged. Methods articles may include new approaches to any aspect of biological structure determination or structure analysis but will only be accepted where they focus on new methods that are demonstrated to be of general applicability and importance to structural biology. Articles describing particularly difficult problems in structural biology are also welcomed, if the analysis would provide useful insights to others facing similar problems.