金黄色葡萄球菌 AgrA LytTR 结构域的计算突变和酚嗪支架抑制:生物物理研究的启示。

IF 2.6 3区 生物学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
BioMed Research International Pub Date : 2024-09-18 eCollection Date: 2024-01-01 DOI:10.1155/2024/8843954
Prince Manu, Prisca Baah Nketia, Priscilla Osei-Poku, Alexander Kwarteng
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引用次数: 0

摘要

由于金黄色葡萄球菌在顽固性感染中的作用,其生物膜的形成是临床环境中的一大挑战。AgrA 蛋白是生物膜形成过程中的一个关键调节因子,是一个很有希望的治疗干预靶点。本研究通过靶向 AgrA 研究卤代吩嗪化合物的抗生物膜潜力,并探索其分子相互作用,从而为药物开发提供见解。我们采用分子对接、分子动力学模拟和计算诱变来评估卤代吩嗪化合物(C1 至 C7、HP 和 HP-14)与 AgrA 的结合。进行了结合自由能分析,以评估这些化合物与 AgrA-DNA 复合物的亲和力。此外,还研究了这些化合物对 AgrA 结构构象和盐桥相互作用的影响。无结合能分析表明,与AgrA的Apo形式相比,所有化合物都增强了结合亲和力,AgrA的ΔGbind为-80.75 kcal/mol。化合物 C7(-113.84 kcal/mol)、HP-14(-115.23 kcal/mol)和 HP(-112.28 kcal/mol)的结合亲和力最强,凸显了它们的有效性。分子动力学模拟表明,这些化合物与 AgrA 的疏水裂隙结合,破坏了 His174-Glu163 和 His174-Glu226 之间重要的盐桥相互作用。这种破坏导致了结构构象的改变和 DNA 结合亲和力的降低,与抑制生物膜的实验结果相吻合。卤代吩嗪化合物通过靶向 AgrA,破坏其 DNA 结合功能,有效抑制了生物膜的形成。这项研究证实了这些化合物作为抗生物膜药物的潜力,并为针对 AgrA-DNA 相互作用的合理药物设计奠定了基础。未来的研究应侧重于进一步优化这些先导化合物,并探索 AgrA 上的其他活性位点,以开发治疗生物膜相关感染的新型疗法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Computational Mutagenesis and Inhibition of Staphylococcus aureus AgrA LytTR Domain Using Phenazine Scaffolds: Insight From a Biophysical Study.

Biofilm formation by Staphylococcus aureus is a major challenge in clinical settings due to its role in persistent infections. The AgrA protein, a key regulator in biofilm development, is a promising target for therapeutic intervention. This study investigates the antibiofilm potential of halogenated phenazine compounds by targeting AgrA and explores their molecular interactions to provide insights for drug development. We employed molecular docking, molecular dynamics simulations, and computational mutagenesis to evaluate the binding of halogenated phenazine compounds (C1 to C7, HP, and HP-14) to AgrA. Binding free energy analysis was performed to assess the affinity of these compounds for the AgrA-DNA complex. Additionally, the impact of these compounds on AgrA's structural conformation and salt bridge interactions was examined. The binding-free energy analysis revealed that all compounds enhance binding affinity compared to the Apo form of AgrA, which has a ΔGbind of -80.75 kcal/mol. The strongest binding affinities were observed with compounds C7 (-113.84 kcal/mol), HP-14 (-115.23 kcal/mol), and HP (-112.28 kcal/mol), highlighting their effectiveness. Molecular dynamics simulations demonstrated that these compounds bind at the hydrophobic cleft of AgrA, disrupting essential salt bridge interactions between His174-Glu163 and His174-Glu226. This disruption led to structural conformational changes and reduced DNA binding affinity, aligning with experimental findings on biofilm inhibition. The halogenated phenazine compounds effectively inhibit biofilm formation by targeting AgrA, disrupting its DNA-binding function. The study supports the potential of these compounds as antibiofilm agents and provides a foundation for rational drug design targeting the AgrA-DNA interaction. Future research should focus on further optimizing these lead compounds and exploring additional active sites on AgrA to develop novel treatments for biofilm-associated infections.

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来源期刊
BioMed Research International
BioMed Research International BIOTECHNOLOGY & APPLIED MICROBIOLOGY-MEDICINE, RESEARCH & EXPERIMENTAL
CiteScore
6.70
自引率
0.00%
发文量
1942
审稿时长
19 weeks
期刊介绍: BioMed Research International is a peer-reviewed, Open Access journal that publishes original research articles, review articles, and clinical studies covering a wide range of subjects in life sciences and medicine. The journal is divided into 55 subject areas.
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