A novel algorithm for the virtual screening of extensive small molecule libraries against ERCC1/XPF protein-protein interaction for the identification of resistance-bypassing potential anticancer molecules.

Turkish journal of biology = Turk biyoloji dergisi Pub Date : 2024-04-03 eCollection Date: 2024-01-01 DOI:10.55730/1300-0152.2686
Salma Ghazy, Lalehan Oktay, Serdar Durdaği
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Abstract

Background and aim: Cancer cell's innate chemotherapeutic resistance continues to be an obstacle in molecular oncology. This theory is firmly tied to the cancer cells' integral DNA repair mechanisms continuously neutralizing the effects of chemotherapy. Amidst these mechanisms, the nuclear excision repair pathway is crucial in renovating DNA lesions prompted by agents like Cisplatin. The ERCC1/XPF complex stands center-stage as a structure-specific endonuclease in this repair pathway. Targeting the ERCC1/XPF dimerization brings forth a strategy to augment chemotherapy by eschewing the resistance mechanism integral to cancer cells. This study tracks and identifies small anticancer molecules, with ERCC1/XPF inhibiting potential, within extensive small-molecule compound libraries.

Materials and methods: A novel hybrid virtual screening algorithm, conjoining ligand- and target-based approaches, was developed. All-atom molecular dynamics (MD) simulations were then run on the obtained hit molecules to reveal their structural and dynamic contributions within the binding site. MD simulations were followed by MM/GBSA calculations to qualify the change in binding free energies of the protein/ligand complexes throughout MD simulations.

Results: Conducted analyses highlight new potential inhibitors AN-487/40936989 from the SPECS SC library, K219-1359, and K786-1161 from the ChemDiv Representative Set library as showing better predicted activity than previously discovered ERCC1/XPF inhibitor, CHEMBL3617209.

Conclusion: The algorithm implemented in this study expands our comprehension of chemotherapeutic resistance and how to overcome it through identifying ERCC1/XPF inhibitors with the aim of enhancing chemotherapeutic impact giving hope for ameliorated cancer treatment outcomes.

针对ERCC1/XPF蛋白-蛋白相互作用虚拟筛选大量小分子化合物库的新算法,以鉴定可绕过抗药性的潜在抗癌分子。
背景和目的:癌细胞与生俱来的化疗抗药性仍然是分子肿瘤学的一个障碍。这一理论与癌细胞不断中和化疗作用的 DNA 整体修复机制紧密相关。在这些机制中,核切除修复途径在修复顺铂等药物引起的DNA病变方面至关重要。ERCC1/XPF复合物作为结构特异性内切酶在这一修复途径中发挥着核心作用。以ERCC1/XPF二聚体为靶点,可以避开癌细胞不可或缺的抗药性机制,从而提出一种增强化疗的策略。这项研究在广泛的小分子化合物库中追踪并鉴定了具有ERCC1/XPF抑制潜力的小抗癌分子:开发了一种新颖的混合虚拟筛选算法,该算法结合了基于配体和靶点的方法。然后对获得的命中分子进行全原子分子动力学(MD)模拟,以揭示它们在结合位点内的结构和动力学贡献。MD 模拟之后还进行了 MM/GBSA 计算,以确定整个 MD 模拟过程中蛋白质/配体复合物结合自由能的变化:分析结果表明,SPECS SC 库中的新潜在抑制剂 AN-487/40936989、K219-1359 和 ChemDiv 代表集库中的 K786-1161 比之前发现的 ERCC1/XPF 抑制剂 CHEMBL3617209 显示出更好的预测活性:本研究采用的算法扩展了我们对化疗耐药性的理解,以及如何通过识别 ERCC1/XPF 抑制剂来克服耐药性,从而提高化疗效果,为改善癌症治疗效果带来希望。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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