Chemical analogue based drug design for cancer treatment targeting PI3K: integrating machine learning and molecular modeling

IF 3.9 2区化学 Q2 CHEMISTRY, APPLIED

Molecular Diversity Pub Date : 2024-08-17 DOI:10.1007/s11030-024-10966-x

Mohammed A. Bazuhair, Anwar A. Alghamdi, Othman Baothman, Muhammad Afzal, Sami I. Alzarea, Faisal Imam, Ehssan Moglad, Hisham N. Altayb

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Abstract

Cancer is a generic term for a group of disorders defined by uncontrolled cell growth and the potential to invade or spread to other parts of the body. Gene and epigenetic alterations disrupt normal cellular control, leading to abnormal cell proliferation, resistance to cell death, blood vessel development, and metastasis (spread to other organs). One of the several routes that play an important role in the development and progression of cancer is the phosphoinositide 3-kinase (PI3K) signaling pathway. Moreover, the gene PIK3CG encodes the catalytic subunit gamma (p110γ) of phosphoinositide 3-kinase (PI3Kγ), a member of the PI3K family. Therefore, in this study, PIK3CG was targeted to inhibit cancer by identifying a novel inhibitor through computational methods. The study screened 1015 chemical fragments against PIK3CG using machine learning-based binding estimation and docking to select the potential compounds. Later, the analogues were generated from the selected hits, and 414 analogues were selected, which were further screened, and as most potential candidates, three compounds were obtained: (a) 84,332, 190,213, and 885,387. The protein–ligand complex’s stability and flexibility were then investigated by dynamic modeling. The 100 ns simulation revealed that 885,387 exhibited the steadiest deviation and constant creation of hydrogen bonds. Compared to the other compounds, 885,387 demonstrated a superior binding free energy (ΔG = −18.80 kcal/mol) with the protein when the MM/GBSA technique was used. The study determined that 885,387 showed significant therapeutic potential and justifies further experimental investigation as a possible inhibitor of the PIK3CG target implicated in cancer.

Graphical Abstract

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基于化学类似物的 PI3K 靶向癌症治疗药物设计：机器学习与分子建模的整合。

癌症是一组疾病的统称，其定义是细胞生长失控，并有可能侵入或扩散到身体其他部位。基因和表观遗传学的改变破坏了正常的细胞控制，导致细胞异常增殖、抵抗细胞死亡、血管发育和转移（扩散到其他器官）。磷酸肌酸 3- 激酶（PI3K）信号通路是在癌症发生和发展过程中发挥重要作用的几条途径之一。此外，PIK3CG 基因编码 PI3K 家族成员磷脂酶（PI3Kγ）的催化亚基γ（p110γ）。因此，本研究以 PIK3CG 为靶点，通过计算方法找出一种新型抑制剂来抑制癌症。该研究利用基于机器学习的结合估计和对接筛选出 1015 个针对 PIK3CG 的化学片段，从而选出潜在的化合物。随后，从筛选出的命中化合物中生成类似物，并进一步筛选出 414 种类似物，作为最有潜力的候选化合物，得到了三种化合物：(a) 84 332、190 213 和 885 387。然后通过动态建模研究了蛋白质配体复合物的稳定性和灵活性。100 ns 模拟显示，885,387 表现出最稳定的偏离和氢键的持续产生。与其他化合物相比，在使用 MM/GBSA 技术时，885,387 与蛋白质的结合自由能（ΔG = -18.80 kcal/mol）更优越。研究结果表明，885,387 具有显著的治疗潜力，有理由将其作为一种可能的癌症 PIK3CG 靶点抑制剂进行进一步的实验研究。

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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来源期刊

Molecular Diversity 化学-化学综合

CiteScore

7.30

自引率

7.90%

发文量

219

审稿时长

2.7 months

期刊介绍： Molecular Diversity is a new publication forum for the rapid publication of refereed papers dedicated to describing the development, application and theory of molecular diversity and combinatorial chemistry in basic and applied research and drug discovery. The journal publishes both short and full papers, perspectives, news and reviews dealing with all aspects of the generation of molecular diversity, application of diversity for screening against alternative targets of all types (biological, biophysical, technological), analysis of results obtained and their application in various scientific disciplines/approaches including: combinatorial chemistry and parallel synthesis; small molecule libraries; microwave synthesis; flow synthesis; fluorous synthesis; diversity oriented synthesis (DOS); nanoreactors; click chemistry; multiplex technologies; fragment- and ligand-based design; structure/function/SAR; computational chemistry and molecular design; chemoinformatics; screening techniques and screening interfaces; analytical and purification methods; robotics, automation and miniaturization; targeted libraries; display libraries; peptides and peptoids; proteins; oligonucleotides; carbohydrates; natural diversity; new methods of library formulation and deconvolution; directed evolution, origin of life and recombination; search techniques, landscapes, random chemistry and more;