International Cooperation Base of Pesticide and Green Synthesis (Hubei), Key Laboratory of Pesticide & Chemical Biology (CCNU), Ministry of Education, Department of Chemistry, Central China Normal University, Wuhan 430079, China.
Institute of Marine Drugs, Guangxi University of Chinese Medicine, Nanning, 530200, People's Republic of China.
J Chem Inf Model. 2020 Sep 28;60(9):4388-4402. doi: 10.1021/acs.jcim.9b01197. Epub 2020 Apr 9.
drug design actively seeks to use sets of chemical rules for the fast and efficient identification of structurally new chemotypes with the desired set of biological properties. Fragment-based design tools have been successfully applied in the discovery of noncovalent inhibitors. Nevertheless, these tools are rarely applied in the field of covalent inhibitor design. Herein, we present a new protocol, called Cov_FB3D, which involves the assembly of potential novel covalent inhibitors by identifying the active fragments in the covalently binding site of the target protein. In this protocol, we propose a BA-SAMP strategy, which combines the noncovalent moiety score with the X-Score as the molecular mechanism (MM) level, and the covalent candidate score with the PM7 as the QM level. The synthetic accessibility of each suggested compound could be further evaluated with machine-learning-based synthetic complexity evaluation (SCScore). An in-depth test of this protocol against the crystal structures of 15 covalent complexes consisting of BTK inhibitors, KRAS inhibitors, EGFR inhibitors, EphB1 inhibitors, MAGL inhibitors, and MAPK inhibitors revealed that most of these inhibitors could be reproduced from the fragments by Cov_FB3D. The binding modes of most generated reference poses could accurately reproduce the known binding mode of most of the reference covalent adduct in the binding site (RMSD ≤ 2 Å). In particular, most of these inhibitors were ranked in the top 2%, using the BA-SAMP strategy. Notably, the novel human ALDOA inhibitor () with potent inhibitory activity (0.34 ± 0.03 μM) and greater synthetic accessibility was successfully designed by this protocol. The positive results confirm the abilities of Cov_FB3D protocol.
药物设计积极寻求利用化学规则集,快速有效地识别具有所需生物特性的结构新颖的化学型。基于片段的设计工具已成功应用于非共价抑制剂的发现。然而,这些工具在共价抑制剂设计领域很少应用。在此,我们提出了一种新的方案,称为 Cov_FB3D,它通过识别靶蛋白共价结合位点中的活性片段,组装潜在的新型共价抑制剂。在该方案中,我们提出了 BA-SAMP 策略,该策略将非共价部分得分与 X-Score 作为分子机制 (MM) 水平结合,将共价候选物得分与 PM7 作为 QM 水平结合。每个建议化合物的合成可接近性可以通过基于机器学习的合成复杂度评估 (SCScore) 进一步评估。对该方案对由 BTK 抑制剂、KRAS 抑制剂、EGFR 抑制剂、EphB1 抑制剂、MAGL 抑制剂和 MAPK 抑制剂组成的 15 个共价复合物的晶体结构进行的深入测试表明,这些抑制剂中的大多数可以由 Cov_FB3D 从片段中复制。大多数生成的参考构象的结合模式可以准确地再现已知的参考共价加合物在结合位点中的结合模式(RMSD≤2Å)。特别是,使用 BA-SAMP 策略,大多数抑制剂的排名在前 2%。值得注意的是,成功设计了具有强抑制活性(0.34±0.03μM)和更高合成可接近性的新型人 ALDOA 抑制剂()。阳性结果证实了 Cov_FB3D 方案的能力。
