Abstract
Over the years, various computational methodologies have been developed to understand and quantify receptor–ligand interactions. Protein–ligand interactions can also be explained in the form of a network and its properties. The ligand binding at the protein-active site is stabilized by formation of new interactions like hydrogen bond, hydrophobic and ionic. These non-covalent interactions when considered as links cause non-isomorphic sub-graphs in the residue interaction network. This study aims to investigate the relationship between these induced sub-graphs and ligand activity. Graphlet signature-based analysis of networks has been applied in various biological problems; the focus of this work is to analyse protein–ligand interactions in terms of neighbourhood connectivity and to develop a method in which the information from residue interaction networks, i.e. graphlet signatures, can be applied to quantify ligand affinity. A scoring method was developed, which depicts the variability in signatures adopted by different amino acids during inhibitor binding, and was termed as GSUS (graphlet signature uniqueness score). The score is specific for every individual inhibitor. Two well-known drug targets, COX-2 and CA-II and their inhibitors, were considered to assess the method. Residue interaction networks of COX-2 and CA-II with their respective inhibitors were used. Only hydrogen bond network was considered to calculate GSUS and quantify protein–ligand interaction in terms of graphlet signatures. The correlation of the GSUS with pIC50 was consistent in both proteins and better in comparison to the Autodock results. The GSUS scoring method was better in activity prediction of molecules with similar structure and diverse activity and vice versa. This study can be a major platform in developing approaches that can be used alone or together with existing methods to predict ligand affinity from protein–ligand complexes.
Highlights
Understanding and quantifying receptor–ligand interactions forms the core of computer-aided drug discovery methods [1]
The purpose of this study was to analyse the changes in local connectivity of each node present in protein-active site after ligand binding in the residue interaction networks and to relate these changes to compound activity
This study focuses on the identification of induced sub-graphs in the protein-active site after ligand binding employing graphlet signature-based analysis of residue interaction networks and their application to estimate binding affinity of various ligands
Summary
Understanding and quantifying receptor–ligand interactions forms the core of computer-aided drug discovery methods [1]. One such method, molecular docking, has been widely used owing to its high speed and performance. To improve the performance of virtual screening experiments, approaches like free energy perturbation methods, pharmacophore modelling, post docking consensus scoring/tuned scoring, etc. There is a need for development of more such methods that can improve the authenticity of virtual screening findings when used alone or together with the existing methods. Especially residue interaction networks, have been extensively used to analyse protein structure and dynamics [4]. Reports suggest that the protein–ligand interactions can be explained in the form of network. The impact of a ligand binding on protein network can be measured in terms of its network properties and it has substantial effects on the closeness centrality of network [5]
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