Ren Ji-Xia, Zhang Rui-Tao, Zhang Hui, Cao Xue-Song, Liu Li-Ke, Xie Yong
College of Life Science, Liaocheng University, Liaocheng 252059, People's Republic of China; Institute of Medicinal Plant Development, Chinese Academy of Medical Science & Peking Union Medical college, 151 Malianwa North Road, Haidian District, Beijing 100193, People's Republic of China.
Black Donkey Research Institute, Dongeejiao Company Limited, Liaocheng 252000, Shandong, People's Republic of China.
Biomed Pharmacother. 2016 Dec;84:199-207. doi: 10.1016/j.biopha.2016.09.034. Epub 2016 Sep 19.
Ebola virus is a single-stranded, negative-sense RNA virus that causes acute and serious life-threatening illness. In recent years the Ebola virus has spread through several countries in Africa, highlighting the need to develop new treatments for this disease and boosting a new research effort on this subject. However, so far there is no valid treatment for disease created by this pathogen. The Ebola virus Viral Protein 35 (VP35) is a multifunctional protein which is critical for virus replication and infection, and it is considered as a future target for drug development. In this study, we collected 144 VP35 inhibitors which shared the same core scaffold, and a common feature pharmacophore model HypoA was built based on inhibitor-receptor complexes. All 141 compounds were aligned based on the common feature pharmacophore model HypoA (three compounds could not map onto HypoA). The pharmacophore model HypoA was further optimized according to the actual interactions between inhibitors and VP35 protein, resulting in a new pharmacophore model HypoB which was applied for virtual screening. A 3D QSAR model was established by applying the 141 aligned compounds. For the training set, the 3D QSAR model gave a correlation coefficient r of 0.897, for the test set, the correlation coefficient r was 0.757. Then a virtual screening was carried out, which comprehensively employing the common feature pharmacophore model, 3D QSAR model and docking study, their combination in a hybrid protocol could help to mutually compensate for their limitations and capitalized on their mutual strengths. After the above three virtual screening methods orderly filtering, seven potential inhibitors with novel scaffolds were identified as new VP35 inhibitors. The mapping results of hit compounds onto pharmacophore model and 3D QSAR model, and the molecular interactions of the potential inhibitors with the active site residues have been discussed in detail.
埃博拉病毒是一种单链、负链RNA病毒,可引发急性且严重的危及生命的疾病。近年来,埃博拉病毒已在非洲的多个国家传播,凸显出开发针对该疾病新疗法的必要性,并推动了关于这一主题的新研究工作。然而,迄今为止,对于这种病原体引发的疾病尚无有效的治疗方法。埃博拉病毒的病毒蛋白35(VP35)是一种多功能蛋白,对病毒复制和感染至关重要,它被视为未来药物开发的靶点。在本研究中,我们收集了144种具有相同核心骨架的VP35抑制剂,并基于抑制剂-受体复合物构建了一个共同特征药效团模型HypoA。所有141种化合物根据共同特征药效团模型HypoA进行了比对(三种化合物无法映射到HypoA上)。根据抑制剂与VP35蛋白之间的实际相互作用,对药效团模型HypoA进行了进一步优化,得到了一个新的药效团模型HypoB,并将其应用于虚拟筛选。通过应用这141种比对后的化合物建立了一个三维定量构效关系(3D QSAR)模型。对于训练集,3D QSAR模型的相关系数r为0.897,对于测试集,相关系数r为0.757。然后进行了虚拟筛选,综合运用共同特征药效团模型、3D QSAR模型和对接研究,它们在混合方案中的结合有助于相互弥补各自的局限性并利用彼此的优势。经过上述三种虚拟筛选方法的有序筛选,七种具有新型骨架的潜在抑制剂被鉴定为新的VP35抑制剂。已详细讨论了命中化合物在药效团模型和3D QSAR模型上的映射结果,以及潜在抑制剂与活性位点残基的分子相互作用。
