磷酸三酯酶水解毒性神经毒剂的多状态多尺度对接研究

IF 2.9 Q3 CHEMISTRY, PHYSICAL Electronic Structure Pub Date : 2023-06-16 DOI:10.1088/2516-1075/acdf33
P. Gupta, Naziha Tarannam, Shani Zev, D. Major
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引用次数: 0

摘要

G型和V型神经毒剂是已知毒性最强的化合物之一,吸入几毫克可能导致潜在的死亡。近年来,野生型磷酸三酯酶(PTE)因其对这些致命化合物的解毒能力而备受关注。潜在的机制是通过羟基攻击有机磷神经毒剂的P或C中心,然后离开基团而进行的。PTE活性位点中心存在的两种Zn2+阳离子间接协助水解。除了野生型PTE,据报道,几种设计酶变体更有效地催化水解过程。在此,我们研究了八种有毒化合物与一种酶变体(PTE_27)的水解,该酶变体显示出比野生型更高的效率,如最近的一篇文章中所报道的。我们使用EnzyDock对接程序中实施的一致对接方案对接了所有八个配体的高能中间态和底物。此外,我们利用密度泛函理论在隐式氯仿溶剂中研究了所有八种配体的水解反应机制,发现这些配体的水解遵循三种不同的可能机制。最后,EnzyDock成功地预测了正确的对映异构体姿态,并将其作为低能量对接结构进行评分。
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Multistate multiscale docking study of the hydrolysis of toxic nerve agents by phosphotriesterase
The G- and V-type nerve agents are among the most toxic compounds known, where inhalation of a few mg could cause potential death. Over the years wild-type phosphotriesterase (PTE) has gained much attention due to its capability of detoxifying these deadly compounds. The underlying mechanism proceeds via a hydroxyl attack on the P or C centers of the organophosphate nerve agents followed by the departure of the leaving group. Two Zn2+ cations present in the active site center of PTE indirectly assist the hydrolysis. Apart from the wild-type PTE, several designer enzyme variants reportedly catalyze the hydrolysis process much more efficiently. Herein, we studied the hydrolysis of eight toxic compounds with one of the enzyme variants (PTE_27) that show higher efficiency than the wild type as reported in a recent article. We docked both the high energy intermediate state and substrate for all the eight ligands using a consensus docking scheme as implemented in the docking program EnzyDock. Additionally, we investigated the hydrolytic reaction mechanism for all eight ligands employing density functional theory in implicit chloroform solvent and found that hydrolysis for these ligands follows three different possible mechanisms. Finally, EnzyDock successfully predicted correct enantiomeric poses and also score these as low energy docked structures.
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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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