Computational design of novel cyclic urea as HIV-1 protease inhibitor

Manga, Vijjulatha; Kanth, Sivan Sree

doi:10.2478/s11532-007-0040-x

Cited by 4 publications

(1 citation statement)

References 23 publications

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“…These observations are reflected in the interaction energy contributions of our present analysis. The protein-ligand interaction energies obtained using PEARLS server has been used in other studies on inhibitor discovery such as HIV-1 protease [ 39 ] and ribonuclease A inhibitors [ 40 ] to predict the binding affinity values using regression analysis. Log P, remains the main deterministic factor for the ligand’s affinity for the protein active site with reference to the surrounding solvent environment [ 41 ].…”

Section: Discussionmentioning

confidence: 99%

Prediction of kinase-inhibitor binding affinity using energetic parameters

Usha

Selvaraj

2016

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The combination of physicochemical properties and energetic parameters derived from protein-ligand complexes play a vital role in determining the biological activity of a molecule. In the present work, protein-ligand interaction energy along with logP values was used to predict the experimental log (IC50) values of 25 different kinase-inhibitors using multiple regressions which gave a correlation coefficient of 0.93. The regression equation obtained was tested on 93 kinase-inhibitor complexes and an average deviation of 0.92 from the experimental log IC50 values was shown. The same set of descriptors was used to predict binding affinities for a test set of five individual kinase families, with correlation values > 0.9. We show that the protein-ligand interaction energies and partition coefficient values form the major deterministic factors for binding affinity of the ligand for its receptor.

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Section: Discussionmentioning

confidence: 99%

Prediction of kinase-inhibitor binding affinity using energetic parameters

Usha

Selvaraj

2016

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Case Study 1: Peptidomimetic HIV Protease Inhibitors

Trabocchi

Guarna

2014

Peptidomimetics in Organic and Medicinal Chemistry

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Binding dynamics and energetic insight into the molecular forces driving nucleotide binding by guanylate kinase

Kandeel

Kitade

2010

J of Molecular Recognition

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Plasmodium deoxyguanylate pathways are an attractive area of investigation for future metabolic and drug discovery studies due to their unique substrate specificities. We investigated the energetic contribution to guanylate kinase substrate binding and the forces underlying ligand recognition. In the range from 20 to 35°C, the thermodynamic profiles displayed marked decrease in binding enthalpy, while the free energy of binding showed little changes. GMP produced a large binding heat capacity change of -356 cal mol(-1) K(-1), indicating considerable conformational changes upon ligand binding. Interestingly, the calculated ΔCp was -32 cal mol(-1) K(-1), indicating that the accessible surface area is not the central change in substrate binding, and that other entropic forces, including conformational changes, are more predominant. The thermodynamic signature for GMP is inconsistent with rigid-body association, while dGMP showed more or less rigid-body association. These binding profiles explain the poor catalytic efficiency and low affinity for dGMP compared with GMP. At low temperature, the ligands bind to the receptor site under the effect of hydrophobic forces. Interestingly, by increasing the temperature, the entropic forces gradually vanish and proceed to a nonfavorable contribution, and the interaction occurs mainly through bonding, electrostatic forces, and van der Waals interactions.

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Computational design of novel cyclic urea as HIV-1 protease inhibitor

Cited by 4 publications

References 23 publications

Prediction of kinase-inhibitor binding affinity using energetic parameters

Prediction of kinase-inhibitor binding affinity using energetic parameters

Case Study 1: Peptidomimetic HIV Protease Inhibitors

Binding dynamics and energetic insight into the molecular forces driving nucleotide binding by guanylate kinase

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