粪肠球菌丙氨酸外消旋酶的动力学和计算结构表征

Arie Van Wieren, E. Bouchard, S. Majumdar
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摘要

耐万古霉素肠球菌(VRE)菌株的激增对公众和临床健康构成了严重威胁。VRE菌株是耐多药肠球菌感染的主要原因,通常是从医疗器械中获得的。因此,有必要为这种病原体寻找新的抗菌靶点和药物。丙氨酸外消旋酶可能是一个有价值的药物靶点,因为它在粪便大肠杆菌的生存中起着至关重要的作用。粪便中的Alr(EF_Alr)是从大肠杆菌中异源产生和纯化的。,并在不同pH值下测定稳态动力学常数。使用与L-丙氨酸脱氢酶的偶联反应,在340nm处测量NADH的产生速率,以观察在D-至L-丙氨酸方向上的EF_Alr活性。在pH 9时发现最高的催化效率为8.61±0.5 s-1 mM-1。此外,通过同源性建模和序列比较研究,确定了丙氨酸外消旋反应的暂定活性位点残基Lys40和Tyr268。使用UCSF Chimera,将EF_Alr同源性模型的结构叠加,并与来自粪肠球菌的Alr的晶体结构进行比较。关键词:丙氨酸赛马;粪肠球菌;万古霉素耐药肠球菌;同调建模;pH最佳值;动力学表征;SWISS-MODEL服务器;稳态动力学
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Enzymatic and Structural Characterization of Alanine Racemase from Enterococcus faecium by Kinetic and Computational Studies
The surge in vancomycin-resistant enterococci (VRE) strains poses a serious threat to public and clinical health. VRE strains are the leading cause of multi-drug resistant enterococcal infections and are commonly acquired from medical devices. Therefore, it is essential to discover new antibacterial targets and drugs for this pathogen. Alanine racemase could be a valuable drug target due to its crucial role in E. faecium survival. Alr from E. faecium (EF_Alr) was heterologously produced and purified from E. coli., and the steady-state kinetic constants were determined at different pH values. Using a coupled reaction with L-alanine dehydrogenase, rate of production of NADH was measured at 340 nm to observe EF_Alr activity in the D- to L-alanine direction. The highest catalytic efficiency, 8.61 ± 0.5 s-1 mM-1, was found at pH 9. Additionally, the tentative active site residues, Lys40 and Tyr268, for the alanine racemization reaction were assigned by homology modeling and sequence comparison studies. Using UCSF Chimera, the structure of the EF_Alr homology model was superimposed and compared to the crystal structure of Alr from E. faecalis. KEYWORDS: Alanine Racemase; Enterococcus faecium; Vancomycin-Resistant Enterococci; Homology Modeling; pH Optimum; Kinetic Characterization; SWISS-MODEL Server; Steady-State Kinetics
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