3,4,5-三羟基苯甲酸新型类似物作为 HSP90Alpha 抑制剂的对接和模拟研究

IF 0.7 4区化学 Q4 CHEMISTRY, ORGANIC

Letters in Organic Chemistry Pub Date : 2024-07-12 DOI:10.2174/0115701786312992240702100154

Tanya Gupta, Ritu Kataria, Asim Kumar, Rubina Bhutani, Satish Sardana

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引用次数: 0

摘要

HSP90 是一种重要的分子伴侣蛋白，能对环境压力做出反应，并帮助微生物细胞存活。这种蛋白质是应激反应不可或缺的一部分，有助于稳定微生物生存所必需的各种蛋白质。因此，许多组织适应内源压力的能力关键取决于适当的伴侣蛋白活性。然而，由于伴侣蛋白功能的改变与许多疾病的发生之间存在关联，伴侣蛋白活性的调节剂已成为药物发现的一个新的发展领域。抑制 HSP90alpha 可以破坏蛋白质的正常折叠，从而损害真菌的生长和毒力。在这项工作中，我们利用 OSIRIS Property Explorer 和 DruLiTo 软件筛选出了没食子酸衍生物的新线索。我们对筛选出的新线索进行了 ADME-T 研究，以便进一步筛选。利用 Schrodinger v21 和 GROMACS 软件对所选化合物进行了对接和分子模拟研究，以预测 3,4,5-三羟基苯甲酸新型先导化合物在抑制 HSP90alpha 酶方面的生物活性。化合物 4N、18N、15N 和 14N 的对接得分分别为 -6.5、-6.4、-5.91 和 -5.98，与标准环丙沙星的对接得分相当。化合物 4N 和化合物 14N 与 HSP90alpha（PDB ID：1YC1）发生了显著的结合相互作用，因此被选作进一步的分子动力学研究对象。RMSD、H BOND 和 RMSF 分析证实了化合物 4N 和 14N 与 HSP90 酶的稳定结合。RMSF 图显示，HSP90alpha 酶与不同配体的结合波动小于 0.35 nm。由此可以得出结论，配体的结合可以使蛋白质的构象保持稳定。化合物 4N 和 14N 被认为是最佳的理论先导物，可进一步将其作为 HSP90 alpha 抑制剂进行抗菌活性实验研究。因此，这些衍生物有望成为开发具有广谱抗细菌和真菌活性的新型抗菌剂的候选物质。

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Docking and Simulation Studies on Novel Analogues of 3,4,5-Trihydroxy Benzoic Acid as HSP90Alpha Inhibitors

HSP90 assists as a crucial molecular chaperone that responds to environmental stressors and helps in the survival of cells in microorganisms. This protein is integral to the stress response, aiding in the stabilization of various proteins essential for microbial survival. Consequently, the ability of a number of tissues to adjust to endogenous stress depends critically on appropriate chaperone activity. Modulators of chaperone activity, however, have emerged as a novel and developing area of drug discovery due to the association between changed chaperone function and the development of numerous illnesses. Inhibition of HSP90alpha can disrupt proper protein folding, thus impairing growth and virulence in fungi. In this work, we selected novel leads of gallic acid derivatives with the help of OSIRIS Property Explorer and DruLiTo software. Selected leads were subjected to ADME-T studies for further screening. Docking and molecular simulation studies on selected compounds were performed using Schrodinger v21 and GROMACS software to predict the bioactivity of novel leads of 3,4,5 trihydroxy benzoic acid for suppression of the HSP90alpha enzyme. Compounds 4N, 18N, 15N, and 14N showed good docking scores of -6.5, -6.4, -5.91, and -5.98, respectively, which was comparable to standard ciprofloxacin. Compound 4N and compound 14N demonstrated notable binding interactions and were selected for further investigation through molecular dynamics studies with HSP90alpha (PDB ID: 1YC1). RMSD, H BOND, and RMSF analysis confirmed the stable binding of compounds 4N and 14 N with the HSP90 enzyme. The RMSF plot showed less than 0.35 nm fluctuation for the HSP90alpha enzyme in complex with different ligands. It can be concluded that ligand binding can cause stability to the conformation of the protein. Compounds 4N and 14N are considered to be the best theoretical lead, which can further be studied experimentally as HSP90 alpha inhibitors for antimicrobial activity. Ongoing research aims to uncover more insights into the specific mechanisms of action, optimize structural features for enhanced efficacy, and explore potential synergies with existing antimicrobial agents. As a result, these derivatives hold promise as candidates for the development of novel antimicrobial agents with a broad spectrum of activity against bacteria and fungi

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来源期刊

Letters in Organic Chemistry 化学-有机化学

CiteScore

1.30

自引率

12.50%

发文量

135

审稿时长

7 months

期刊介绍： Aims & Scope Letters in Organic Chemistry publishes original letters (short articles), research articles, mini-reviews and thematic issues based on mini-reviews and short articles, in all areas of organic chemistry including synthesis, bioorganic, medicinal, natural products, organometallic, supramolecular, molecular recognition and physical organic chemistry. The emphasis is to publish quality papers rapidly by taking full advantage of latest technology for both submission and review of the manuscripts. The journal is an essential reading for all organic chemists belonging to both academia and industry.