合理设计
药物设计
化学
PI3K/AKT/mTOR通路
苯并呋喃
分子模型
管道(软件)
计算生物学
虚拟筛选
计算机科学
组合化学
药代动力学
码头
计算模型
铅化合物
生物利用度
药物发现
同源建模
纳米技术
药效团
药理学
领域(数学分析)
协议(科学)
药品
计算化学
作者
Moufida Touhami,Hadjer Mehidi,Nadia Benhalima,Fatima Bouasria,Mehdi Adjdir
标识
DOI:10.1002/slct.202504509
摘要
ABSTRACT This work presents a novel computational pipeline for designing benzofuran‐derived mTOR inhibitors, combining advanced machine learning techniques with molecular modeling approaches. Using a carefully selected set of 52 benzofuran analogs, we established a highly predictive 3D‐QSAR model (R 2 = 0.94, Q 2 = 0.78) that identified crucial molecular features influencing inhibitory activity. Through systematic virtual screening, compound A7 emerged as the most promising candidate, exhibiting exceptional binding energy (‐8.49 kcal/mol) to the mTOR catalytic domain through specific interactions with Val2240 (1.86 Å hydrogen bond) and Tyr2225 (π‐stacking). Quantum mechanical analyses uncovered distinctive electronic properties of A7, including a small HOMO‐LUMO energy separation (2.0 eV) and favorable charge distribution patterns. Comprehensive pharmacokinetic evaluation revealed optimal drug‐like characteristics for A7, with excellent predicted oral bioavailability (96% absorption) and minimal toxicity concerns. Our integrated computational strategy demonstrates the potential of benzofuran derivatives as mTOR‐targeted therapeutics while providing a validated protocol for structure‐based drug discovery.
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