Interaction of the protoberberine alkaloid coralyne with t-RNA(phe) was investigated using various biophysical techniques. Results of absorption and fluorescence studies revealed that the alkaloid binds to t-RNA exhibiting positive cooperativity. Isothermal titration calorimetry results suggested that the binding of the alkaloid was predominantly enthalpy driven with a smaller favourable entropy term. A surprisingly large favourable component for non-electrostatic contribution to the binding of coralyne to t-RNA was revealed from salt dependence data and the dissection of the free energy. The alkaloid enhanced the thermal stability of t-RNA and the binding affinity values obtained from optical thermal melting data was in agreement with that from calorimetry. The heat capacity change of -125 cal mol(-1) K(-1) and the observed significant enthalpy-entropy compensation phenomenon confirmed the involvement of multiple weak noncovalent interactions. Circular dichroism studies provided evidence for significant perturbation of the t-RNA structure with concomitant induction of optical activity in the bound achiral alkaloid molecules. Binding isotherms generated from circular dichroic data confirmed the cooperative binding mode of the alkaloid as deduced from spectroscopic data. Docking studies provided further insights into the partially intercalated state of coralyne inside the t-RNA structure. This study presents a complete binding and thermodynamic profile of coralyne interaction to t-RNA.
In this paper, the interaction of rhodamine123 (R123) with calf thymus DNA has been studied using molecular modeling and other biophysical methods like UV-vis spectroscopy, fluoremetry, optical melting, isothermal titration calorimetry, and circular dichroic studies. Results showed that the binding energy is about -6 to -8 kcal/mol, and the binding process is favored by both negative enthalpy change and positive entropy change. A new method to determine different thermodynamic properties like calorimetric enthalpy and heat capacity change has been introduced in this paper. The obtained data has been crossed-checked by other methods. After dissecting the free-energy contribution, it was observed that the binding was favored by both negative hydrophobic free energy and negative molecular free energy which compensated for the positive free energies due to the conformational change loss of rotational and transitional freedom of the DNA helix.
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