Department of Integrative Biology, School of Biosciences and Technology, VIT University, Vellore, India.
J Cell Biochem. 2018 Jan;119(1):960-966. doi: 10.1002/jcb.26262. Epub 2017 Aug 18.
Discovering a potential drug for HCV treatment is a challenging task in the field of drug research. This study initiates with computational screening and modeling of promising ligand molecules. The foremost modeling method involves the identification of novel compound and its molecular interaction based on pharmacophore features. A total of 197 HCV compounds for NS3/4A protein target were screened for our study. The pharmacophore models were generated using PHASE module implemented in Schrodinger suite. The pharmacophore features include one hydrogen bond acceptor, one hydrogen bond donor, and three hydrophobic sites. As a result, based on mentioned hypothesis the model ADHHH.159 corresponds to the CID 59533233. Furthermore, docking was performed using maestro for all the 197 compounds. Among these, the CID 59533313 and 59533233 possess the best binding energy of -11.75 and -10.40 kcal/mol, respectively. The interactions studies indicated that the CID complexed with the NS3/4A protein possess better binding affinity with the other compounds. Further the compounds were subjected to calculate the ADME properties. Therefore, it can be concluded that these two compounds could be a potential alternative drug for the development of HCV.
发现一种有潜力的 HCV 治疗药物是药物研究领域的一项艰巨任务。本研究从计算筛选和有前途的配体分子建模开始。首要的建模方法涉及根据药效团特征识别新型化合物及其分子相互作用。总共筛选了 197 种 HCV 化合物用于我们的研究。使用 Schrodinger 套件中的 PHASE 模块生成药效团模型。药效团特征包括一个氢键受体、一个氢键供体和三个疏水位点。因此,根据上述假设,模型 ADHHH.159 对应于 CID 59533233。此外,使用 maestro 对所有 197 种化合物进行对接。在这些化合物中,CID 59533313 和 59533233 的结合能分别为-11.75 和-10.40 kcal/mol,具有最佳的结合能。相互作用研究表明,与其他化合物相比,CID 与 NS3/4A 蛋白的复合物具有更好的结合亲和力。进一步对化合物进行 ADME 性质计算。因此,可以得出结论,这两种化合物可能是开发 HCV 的潜在替代药物。
