Abstract
BackgroundRenin has become an attractive target in controlling hypertension because of the high specificity towards its only substrate, angiotensinogen. The conversion of angiotensinogen to angiotensin I is the first and rate-limiting step of renin-angiotensin system and thus designing inhibitors to block this step is focused in this study.MethodsLigand-based quantitative pharmacophore modeling methodology was used in identifying the important molecular chemical features present in the set of already known active compounds and the missing features from the set of inactive compounds. A training set containing 18 compounds including active and inactive compounds with a substantial degree of diversity was used in developing the pharmacophore models. A test set containing 93 compounds, Fischer randomization, and leave-one-out methods were used in the validation of the pharmacophore model. Database screening was performed using the best pharmacophore model as a 3D structural query. Molecular docking and density functional theory calculations were used to select the hit compounds with strong molecular interactions and favorable electronic features.ResultsThe best quantitative pharmacophore model selected was made of one hydrophobic, one hydrogen bond donor, and two hydrogen bond acceptor features with high a correlation value of 0.944. Upon validation using an external test set of 93 compounds, Fischer randomization, and leave-one-out methods, this model was used in database screening to identify chemical compounds containing the identified pharmacophoric features. Molecular docking and density functional theory studies have confirmed that the identified hits possess the essential binding characteristics and electronic properties of potent inhibitors.ConclusionA quantitative pharmacophore model of predictive ability was developed with essential molecular features of a potent renin inhibitor. Using this pharmacophore model, two potential inhibitory leads were identified to be used in designing novel and future renin inhibitors as antihypertensive drugs.
Highlights
Renin has become an attractive target in controlling hypertension because of the high specificity towards its only substrate, angiotensinogen
The cost difference value of Hypo1 signifies that it can correlate the experimental and estimated activity values of the training set compounds more than 90%
Hypo1 was generated with one hydrophobic aliphatic (HY-AL), one hydrogen bond donor (HBD) and two hydrogen bond acceptor (HBA) features with a high correlation coefficient value of 0.944
Summary
Renin has become an attractive target in controlling hypertension because of the high specificity towards its only substrate, angiotensinogen. Inhibition of renin would favor more complete blockade of the system [5] Potent inhibitors of this enzyme could provide a new alternative way to treat hypertension without inhibiting other biological substances. The second is based on the N-terminal portion of the substrate, angiotensinogen, for this binds the active site of renin. These approaches produced only weak inhibitors [8]. Aliskiren is the first of these new nonpeptide inhibitors to be approved by the FDA for the treatment of hypertension but its synthesis include many steps This invites much simpler compounds to be designed as potent renin inhibitors [11]. This study was focused to identify novel scaffolds with the potential to turn as the new category of renin inhibitors
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