Lim Hocheol
Bioinformatics and Molecular Design Research Center (BMDRC), Incheon, Republic of Korea.
J Cheminform. 2024 May 24;16(1):59. doi: 10.1186/s13321-024-00845-w.
De novo molecular design is the process of searching chemical space for drug-like molecules with desired properties, and deep learning has been recognized as a promising solution. In this study, I developed an effective computational method called Scoring-Assisted Generative Exploration (SAGE) to enhance chemical diversity and property optimization through virtual synthesis simulation, the generation of bridged bicyclic rings, and multiple scoring models for drug-likeness. In six protein targets, SAGE generated molecules with high scores within reasonable numbers of steps by optimizing target specificity without a constraint and even with multiple constraints such as synthetic accessibility, solubility, and metabolic stability. Furthermore, I suggested a top-ranked molecule with SAGE as dual inhibitors of acetylcholinesterase and monoamine oxidase B through multiple desired property optimization. Therefore, SAGE can generate molecules with desired properties by optimizing multiple properties simultaneously, indicating the importance of de novo design strategies in the future of drug discovery and development. SCIENTIFIC CONTRIBUTION: The scientific contribution of this study lies in the development of the Scoring-Assisted Generative Exploration (SAGE) method, a novel computational approach that significantly enhances de novo molecular design. SAGE uniquely integrates virtual synthesis simulation, the generation of complex bridged bicyclic rings, and multiple scoring models to optimize drug-like properties comprehensively. By efficiently generating molecules that meet a broad spectrum of pharmacological criteria-including target specificity, synthetic accessibility, solubility, and metabolic stability-within a reasonable number of steps, SAGE represents a substantial advancement over traditional methods. Additionally, the application of SAGE to discover dual inhibitors for acetylcholinesterase and monoamine oxidase B not only demonstrates its potential to streamline and enhance the drug development process but also highlights its capacity to create more effective and precisely targeted therapies. This study emphasizes the critical and evolving role of de novo design strategies in reshaping the future of drug discovery and development, providing promising avenues for innovative therapeutic discoveries.
从头分子设计是在化学空间中搜索具有所需特性的类药物分子的过程,深度学习已被认为是一种有前途的解决方案。在本研究中,我开发了一种有效的计算方法,称为评分辅助生成探索(SAGE),通过虚拟合成模拟、桥连双环的生成以及多个类药物评分模型来增强化学多样性和性质优化。在六个蛋白质靶点中,SAGE通过在无约束甚至在诸如合成可及性、溶解度和代谢稳定性等多个约束条件下优化靶点特异性,在合理的步骤数内生成了高分分子。此外,我通过多个所需性质的优化,提出了一种经SAGE筛选的排名靠前的分子作为乙酰胆碱酯酶和单胺氧化酶B的双重抑制剂。因此,SAGE可以通过同时优化多个性质来生成具有所需特性的分子,这表明从头设计策略在未来药物发现和开发中的重要性。科学贡献:本研究的科学贡献在于开发了评分辅助生成探索(SAGE)方法,这是一种显著增强从头分子设计的新型计算方法。SAGE独特地整合了虚拟合成模拟、复杂桥连双环的生成以及多个评分模型,以全面优化类药物性质。通过在合理的步骤数内有效地生成满足广泛药理学标准(包括靶点特异性、合成可及性、溶解度和代谢稳定性)的分子,SAGE代表了相对于传统方法的重大进步。此外,将SAGE应用于发现乙酰胆碱酯酶和单胺氧化酶B的双重抑制剂,不仅证明了其简化和增强药物开发过程的潜力,还突出了其创造更有效和精准靶向疗法的能力。本研究强调了从头设计策略在重塑未来药物发现和开发中的关键且不断演变的作用,为创新治疗发现提供了有前景的途径。
