This study examines the characteristics of binding of berberine to the human telomeric d[AG3(T2AG3)3] quadruplex. By employing UV‐visible spectroscopy, fluorescence spectroscopy and isothermal titration calorimetry, we found that the binding affinity of berberine to the human telomeric quadruplex is 106. The complete thermodynamic profile for berberine binding to the quadruplex, at 25 °C, shows a small negative enthalpy (ΔH) of −1.7 kcal·mol−1, an entropy change with TΔS of +6.5 kcal·mol−1, and an overall favorable free energy (ΔG) of −8.2 kcal·mol−1 .Through the temperature dependence of ΔH, we obtained a heat capacity (ΔCp) of −94 (± 5) cal·mol−1·K−1. The osmotic stress method revealed that there is an uptake of 13 water molecules in the complex relative to the free reactants. Furthermore, the molecular modeling studies on different quadruplex–berberine complexes show that berberine stacking at the external G‐quartet is mainly aided by the π–π interaction and the stabilization of the high negative charge density of O6 of guanines by the positively charged N7 of berberine. The theoretical heat capacity (ΔCp) values for quadruplex–berberine models are −89 and −156 cal·mol−1·K−1.
The formation and stabilization of telomeric quadruplexes has been shown to inhibit the activity of telomerase, thus establishing telomeric DNA quadruplex as an attractive target for cancer therapeutic intervention. In this context, telomestatin, a G-quadruplex-specific ligand known to bind and stabilize G-quadruplex, is of great interest. Knowledge of the three-dimensional structure of telomeric quadruplex and its complex with telomestatin in solution is a prerequisite for structure-based rational drug design. Here, we report the relative stabilities of human telomeric quadruplex (AG3[T2AG3]3) structures under K+ ion conditions and their binding interaction with telomestatin, as determined by molecular dynamics simulations followed by energy calculations. The energetics study shows that, in the presence of K+ ions, mixed hybrid-type Tel-22 quadruplex conformations are more stable than other conformations. The binding free energy for quadruplex-telomestatin interactions suggests that 1:2 binding is favored over 1:1 binding. To further substantiate our results, we also calculated the change in solvent-accessible surface area (DeltaSASA) and heat capacity (DeltaCp) associated with 1:1 and 1:2 binding modes. The extensive investigation performed for quadruplex-telomestatin interaction will assist in understanding the parameters influencing the quadruplex-ligand interaction and will serve as a platform for rational drug design.
Computational techniques are one of the most emerging topics in structural and molecular biology. Molecular dynamics (MD) simulations are used not only to explore the conformational aspects of biological systems but also to have significant scope in protein-ligand interactions. Then the binding free energy calculations are readily applied to the simulated systems in order to predict the binding affinities. The thermodynamic properties are directly related to protein-ligand interactions which are dependent upon a few specific parameters. In the present review, we highlight some facts related to protein-ligand complexes, by starting with a survey of MD simulations and binding free energy calculations and ending with some successful implementations of these computational techniques.
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