Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target

Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target

The search for new therapies for the treatment of Arterial hypertension is a major concern in the scientific community. Here, we employ a computational biochemistry protocol to evaluate the performance of six compounds (Lig783, Lig1022, Lig1392, Lig2177, Lig3444 and Lig6199) to act as antihypertensi...

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Main Authors: Desmond MacLeod-Carey, Eduardo Solis-Céspedes, Emilio Lamazares, Karel Mena-Ulecia
Format: Article
Language:English
Published: Elsevier 2020-05-01
Series:Saudi Pharmaceutical Journal
Subjects:
Ligand efficiency
ADME-Tox
Antihypertensive
Molecular dynamics
MM-GBSA
Online Access:http://www.sciencedirect.com/science/article/pii/S1319016420300657
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spelling doaj-1b8b38957b0446eb9140752cc24912e72020-11-25T02:15:30ZengElsevierSaudi Pharmaceutical Journal1319-01642020-05-01285582592Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a targetDesmond MacLeod-Carey0Eduardo Solis-Céspedes1Emilio Lamazares2Karel Mena-Ulecia3Universidad Autónoma de Chile, Facultad de Ingeniería, Instituto de Ciencias Químicas Aplicadas, Inorganic Chemistry and Molecular Materials Center, El Llano Subercaseaux 2801, San Miguel, Santiago, ChileVicerrectoría de Investigación y Postgrado, Universidad Católica del Maule, 3460000 Talca, ChileUniversidad de Concepción, Biotechnology and Biopharmaceutical Laboratory, Pathophysiology Department, School of Biological Sciences, Victor Lamas 1290, P.O. Box 160-C, Concepción, ChileUniversidad Católica de Temuco, Facultad de Recursos Naturales, Departamento de Ciencias Biolígicas y Químicas, Ave. Rudecindo Ortega #02950, Temuco, Chile; Corresponding author at: Universidad Católica de Temuco, Facultad de Recursos Naturales, Departamento de Ciencias Biológicas y Químicas, Ave. Rudecindo Ortega #02950, Temuco, Región de la Araucanía, Chile.The search for new therapies for the treatment of Arterial hypertension is a major concern in the scientific community. Here, we employ a computational biochemistry protocol to evaluate the performance of six compounds (Lig783, Lig1022, Lig1392, Lig2177, Lig3444 and Lig6199) to act as antihypertensive agents. This protocol consists of Docking experiments, efficiency calculations of ligands, molecular dynamics simulations, free energy, pharmacological and toxicological properties predictions (ADME-Tox) of the six ligands against Thermolysin. Our results show that the docked structures had an adequate orientation in the pocket of the Thermolysin enzymes, reproducing the X-ray crystal structure of Inhibitor-Thermolysin complexes in an acceptable way. The most promising candidates to act as antihypertensive agents among the series are Lig2177 and Lig3444. These compounds form the most stable ligand-Thermolysin complexes according to their binding free energy values obtained in the docking experiments as well as MM-GBSA decomposition analysis calculations. They present the lowest values of Ki, indicating that these ligands bind strongly to Thermolysin. Lig2177 was oriented in the pocket of Thermolysin in such a way that both OH of the dihydroxyl-amino groups to establish hydrogen bond interactions with Glu146 and Glu166. In the same way, Lig3444 interacts with Asp150, Glu143 and Tyr157. Additionally, Lig2177 and Lig3444 fulfill all the requirements established by Lipinski Veber and Pfizer 3/75 rules, indicating that these compounds could be safe compounds to be used as antihypertensive agents. We are confident that our computational biochemistry protocol can be used to evaluate and predict the behavior of a broad range of compounds designed in silicoagainst a protein target.http://www.sciencedirect.com/science/article/pii/S1319016420300657Ligand efficiencyADME-ToxAntihypertensiveMolecular dynamicsMM-GBSA
collection DOAJ
language English
format Article
sources DOAJ
author Desmond MacLeod-Carey
Eduardo Solis-Céspedes
Emilio Lamazares
Karel Mena-Ulecia
spellingShingle Desmond MacLeod-Carey
Eduardo Solis-Céspedes
Emilio Lamazares
Karel Mena-Ulecia
Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target
Saudi Pharmaceutical Journal
Ligand efficiency
ADME-Tox
Antihypertensive
Molecular dynamics
MM-GBSA
author_facet Desmond MacLeod-Carey
Eduardo Solis-Céspedes
Emilio Lamazares
Karel Mena-Ulecia
author_sort Desmond MacLeod-Carey
title Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target
title_short Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target
title_full Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target
title_fullStr Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target
title_full_unstemmed Evaluation of new antihypertensive drugs designed in silico using Thermolysin as a target
title_sort evaluation of new antihypertensive drugs designed in silico using thermolysin as a target
publisher Elsevier
series Saudi Pharmaceutical Journal
issn 1319-0164
publishDate 2020-05-01
description The search for new therapies for the treatment of Arterial hypertension is a major concern in the scientific community. Here, we employ a computational biochemistry protocol to evaluate the performance of six compounds (Lig783, Lig1022, Lig1392, Lig2177, Lig3444 and Lig6199) to act as antihypertensive agents. This protocol consists of Docking experiments, efficiency calculations of ligands, molecular dynamics simulations, free energy, pharmacological and toxicological properties predictions (ADME-Tox) of the six ligands against Thermolysin. Our results show that the docked structures had an adequate orientation in the pocket of the Thermolysin enzymes, reproducing the X-ray crystal structure of Inhibitor-Thermolysin complexes in an acceptable way. The most promising candidates to act as antihypertensive agents among the series are Lig2177 and Lig3444. These compounds form the most stable ligand-Thermolysin complexes according to their binding free energy values obtained in the docking experiments as well as MM-GBSA decomposition analysis calculations. They present the lowest values of Ki, indicating that these ligands bind strongly to Thermolysin. Lig2177 was oriented in the pocket of Thermolysin in such a way that both OH of the dihydroxyl-amino groups to establish hydrogen bond interactions with Glu146 and Glu166. In the same way, Lig3444 interacts with Asp150, Glu143 and Tyr157. Additionally, Lig2177 and Lig3444 fulfill all the requirements established by Lipinski Veber and Pfizer 3/75 rules, indicating that these compounds could be safe compounds to be used as antihypertensive agents. We are confident that our computational biochemistry protocol can be used to evaluate and predict the behavior of a broad range of compounds designed in silicoagainst a protein target.
topic Ligand efficiency
ADME-Tox
Antihypertensive
Molecular dynamics
MM-GBSA
url http://www.sciencedirect.com/science/article/pii/S1319016420300657
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AT emiliolamazares evaluationofnewantihypertensivedrugsdesignedinsilicousingthermolysinasatarget
AT karelmenaulecia evaluationofnewantihypertensivedrugsdesignedinsilicousingthermolysinasatarget
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