Rational Engineering of the Substrate Specificity of a Thermostable D-Hydantoinase (Dihydropyrimidinase).

Q2 Biochemistry, Genetics and Molecular Biology High-Throughput Pub Date : 2020-02-12 DOI:10.3390/ht9010005

Hovsep Aganyants, Pierre Weigel, Yeranuhi Hovhannisyan, Michèle Lecocq, Haykanush Koloyan, Artur Hambardzumyan, Anichka Hovsepyan, Jean-Noël Hallet, Vehary Sakanyan

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引用次数: 1

Abstract

D-hydantoinases catalyze an enantioselective opening of 5- and 6-membered cyclic structures and therefore can be used for the production of optically pure precursors for biomedical applications. The thermostable D-hydantoinase from Geobacillus stearothermophilus ATCC 31783 is a manganese-dependent enzyme and exhibits low activity towards bulky hydantoin derivatives. Homology modeling with a known 3D structure (PDB code: 1K1D) allowed us to identify the amino acids to be mutated at the substrate binding site and in its immediate vicinity to modulate the substrate specificity. Both single and double substituted mutants were generated by site-directed mutagenesis at appropriate sites located inside and outside of the stereochemistry gate loops (SGL) involved in the substrate binding. Substrate specificity and kinetic constant data demonstrate that the replacement of Phe159 and Trp287 with alanine leads to an increase in the enzyme activity towards D,L-5-benzyl and D,L-5-indolylmethyl hydantoins. The length of the side chain and the hydrophobicity of substrates are essential parameters to consider when designing the substrate binding pocket for bulky hydantoins. Our data highlight that D-hydantoinase is the authentic dihydropyrimidinase involved in the pyrimidine reductive catabolic pathway in moderate thermophiles.

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耐热d -羟酶(二氢嘧啶酶)底物特异性的合理工程研究。

d -羟化酶催化5元和6元环结构的对映选择性打开，因此可用于生产用于生物医学应用的光学纯前体。来自嗜热硬脂地杆菌ATCC 31783的耐热d -羟乙酸酶是一种依赖锰的酶，对大块羟乙酸衍生物表现出低活性。与已知的3D结构(PDB代码:1K1D)的同源性建模使我们能够确定在底物结合位点及其邻近区域发生突变的氨基酸，以调节底物特异性。在参与底物结合的立体化学门环(SGL)内外的适当位点上，通过定点诱变产生了单取代突变体和双取代突变体。底物特异性和动力学常数数据表明，用丙氨酸取代Phe159和Trp287导致酶对D, l -5-苄基和D, l -5-吲哚基甲基海因酮的活性增加。侧链的长度和底物的疏水性是设计大体积氢化酶底物结合袋时需要考虑的重要参数。我们的数据强调，d -羟化酶是真正的二氢嘧啶酶，参与中度嗜热菌的嘧啶还原分解代谢途径。

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来源期刊

High-Throughput Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

9 weeks

期刊介绍： High-Throughput (formerly Microarrays, ISSN 2076-3905) is a multidisciplinary peer-reviewed scientific journal that provides an advanced forum for the publication of studies reporting high-dimensional approaches and developments in Life Sciences, Chemistry and related fields. Our aim is to encourage scientists to publish their experimental and theoretical results based on high-throughput techniques as well as computational and statistical tools for data analysis and interpretation. The full experimental or methodological details must be provided so that the results can be reproduced. There is no restriction on the length of the papers. High-Throughput invites submissions covering several topics, including, but not limited to: -Microarrays -DNA Sequencing -RNA Sequencing -Protein Identification and Quantification -Cell-based Approaches -Omics Technologies -Imaging -Bioinformatics -Computational Biology/Chemistry -Statistics -Integrative Omics -Drug Discovery and Development -Microfluidics -Lab-on-a-chip -Data Mining -Databases -Multiplex Assays