UV Photolysis of a Re(I) Macromolecule, [(4-vinylpyridine)2(4-vinylpyridineRe(C0)3(1,10-phenanthroline)+]200: Addition of C-centered Radicals to Coordinated CO

Abstract

Proteins that bind preferentially to specific recognition sites on DNA also bind more weakly to nonspecific DNA. We have studied both specific and non-specific binding of the EcoRI and BamHI restriction endonucleases, and determined enthalpic and entropic contributions to binding free energy (ΔG°_bind) using both the van't Hoff method and isothermal titration calorimetry. Specific binding is characterized by a strongly negative ΔC°_p and can be either enthalpy-driven or entropy-driven, depending on temperature. Nonspecific binding has ΔC°_p ≈ 0 and is enthalpy-driven. A strongly negative ΔC°_p is the ?thermodynamic signature’ of site-specific binding, because it reflects the characteristics of a tight complementary recognition interface: the burial of previously hydrated nonpolar surface and restriction of configurational-vibrational freedoms of protein, DNA, and water molecules trapped at the protein-DNA interface. These factors are absent in nonspecific complexes. We probed the contributions to ΔC°_p by varying the sequence context surrounding the recognition site. As ΔG°_bind improves, ΔC°_p' ΔH° and ΔS° all become more negative, and there is a linear correlation between ΔH° and ΔS° (enthalpy-entropy compensation). Because these context variations do not change the protein-base or protein-phosphate contacts, the hydrophobic contribution or the number of trapped water molecules at the interface, we conclude that a better sequence context improves the ?goodness of fit’ in the interface and and thus increases the magnitude of the negative configurational-vibrational contribution to ΔC°_p.