作为潜在未开发抗癌靶点的 TOE1 的异位共价抑制:基于结构的虚拟筛选和共价分子动力学分析。

IF 2.6 4区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Ibrahim Oluwatobi Kehinde, Ernest Oduro-Kwateng, Mahmoud E S Soliman
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引用次数: 0

摘要

癌症由于其复杂的分子机制和对传统疗法的抗药性,仍然是治疗开发中的一项艰巨挑战。最近的证据表明,TOE1 可能在癌症进展中发挥作用,使其成为一个有吸引力的治疗干预靶点,然而,文献中探索 TOE1 抑制剂抗癌潜力的研究非常有限。在此,我们通过全面的虚拟筛选过程,探索了一个由 13,900 个半胱氨酸靶向共价抑制剂组成的化合物库,试图找出可开发成有效抗 TOE1 癌症疗法的潜在化合物。首先根据化合物的结合亲和力进行筛选,然后根据其是否符合药物的类似性质进行筛选,最后根据其与活性半胱氨酸(Cys80)的有效共价模型进行筛选。结果发现,分别有 66 个化合物、28 个化合物和 3 个化合物的结合亲和力、最佳类药物性和共价对接得分高于参考化合物。与参比化合物相比,筛选出的前三个化合物(0462、2204 和 7034)在相互作用概况、共价结合动力学、自由结合能量和每残基能量贡献方面均表现出优势。值得注意的是,化合物 0462 贡献了最高的自由结合能,并显著增强了 TOE1 的稳定性和刚性,同时限制了残基的灵活性。这项研究阐述了共价抑制 TOE1 的分子力学基础,同时为进一步研究和将筛选出的 TOE1 抑制剂(尤其是化合物 0462)转化为新型癌症疗法提供了有力的依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Allosteric covalent inhibition of TOE1 as potential unexplored anti-cancer target: structure-based virtual screening and covalent molecular dynamics analysis.

Cancer remains a formidable challenge in therapeutic development owing to its complex molecular mechanisms and resistance to conventional treatments. Recent evidence suggests that TOE1 may play a role in cancer progression, making it an attractive target for therapeutic interventions, nevertheless, very limited research in literature has explored the potential of TOE1 inhibitors as anti-cancer. Herein, by exploring a library of 13,900 cysteine-targeted covalent inhibitors via a comprehensive virtual screening process, we sought to identify potential compounds that could be developed into effective cancer therapies against TOE1. The compounds were first screened based on their binding affinity, followed by their compliance with drug-like properties, and finally, by their effective covalent modeling to a reactive cysteine (Cys80). A total of 66 compounds, 28 compounds, and 3 compounds were found to have higher binding affinities, optimum drug-likeness, and higher covalent docking scores, respectively, than the reference compound. The top three screened compounds, 0462, 2204, and 7034, demonstrated favorable interaction profiles, covalent binding dynamics, free binding energetics, and per-residue energy contributions as compared to the reference compound. Notably, compound 0462 contributed to the highest free binding energy and significantly enhanced the stability and rigidity of TOE1, while restricting residue flexibility. This study provides an account of the molecular mechanics underpinning the covalent inhibition of TOE1, while providing a compelling case for further investigation and translation of the screened TOE1 inhibitors, particularly compound 0462, as novel therapeutics against cancer.

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来源期刊
Journal of Receptors and Signal Transduction
Journal of Receptors and Signal Transduction 生物-生化与分子生物学
CiteScore
6.60
自引率
0.00%
发文量
19
审稿时长
>12 weeks
期刊介绍: Journal of Receptors and Signal Tranduction is included in the following abstracting and indexing services: BIOBASE; Biochemistry and Biophysics Citation Index; Biological Abstracts; BIOSIS Full Coverage Shared; BIOSIS Previews; Biotechnology Abstracts; Current Contents/Life Sciences; Derwent Chimera; Derwent Drug File; EMBASE; EMBIOLOGY; Journal Citation Reports/ Science Edition; PubMed/MedLine; Science Citation Index; SciSearch; SCOPUS; SIIC.
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