| Abstract: | The enthalpy ΔH for the intercalation of the ethidium cation (EC) into DNA minihelices can be decomposed into (1) an energy of conformational adjustment (i.e., the energy of minihelix extension and unwinding from the B-form to the intercalated form) and (2) EC minihelix intermolecular interactions. In the present study, we have focused our attention mainly on a decomposition of the energetic factors of the EC minihelix intermolecular interactions, while the essential features of the energy of conformational adjustment have been discussed in detail elsewhere by us. The structural features of the various resulting energy-minimized EC-intercalated complexes are compared with each other and the initial x-ray model structure. ΔH is estimated to be in the range of ?12.3 to ?24.0 kcal/mol. This theoretical estimate is qualitatively and quantitatively in agreement with a variety of available experimental data. The energy of conformational adjustment is an energetically unfavorable step, while the energetically favorable contribution of the EC minihelix intermolecular interactions is responsible for the overall favorable nature of the intercalation process involving the EC. On the other hand, the observed preference for intercalation into Pyr(3′–5′)Pur DNA sequences over their isomeric Pur(3′–5′)Pyr sequences is controlled by the energy of conformational adjustment and not by the EC minihelix intermolecular interaction contribution. No base-composition effect is expected at EC concentrations normally found at cellular conditions. Moreover, the structural features of the various EC-intercalated complexes are very similar regardless of minihelix base sequence or composition. These results compare favorably with available evidence. The nature of biologically preferred sites of EC binding with the minihelices is discussed. |
