Studies on nucleic acids. VIII. Changes in the stability of DNA secondary structure by interaction with divalent metal ions

The melting temperature of a natural DNA is decreased in the presence of increasing amounts of copper ions, whereas other divalent metal ions stabilize the DNA secondary structure at low ionic strength. At 1.28 × 10^?4M, Cu²⁺ produces a decrease of T_m depending on base composition. At very low Cu²⁺ concentrations (0.5 Cu²⁺/2 DNA-P) a stabilization of the DNA conformation appears due to an interaction between Cu²⁺ and phosphate groups of the DNA molecule. In this case the normal trend of GC dependence of T_m exists similar to that with Na⁺ and Mg²⁺ as counterions. If copper ions are in excess, the observed destabilization is stronger for DNAs rich in guanine plus cytosine than for those rich in adenine plus thymine. A sharp decrease of T_m occurs between 0.5–0.8 Cu²⁺/2 DNA-P and 1.5 Cu²⁺/2 DNA-P. The breadth of the transition decreases at high Cu²⁺ concentration with further addition of copper ions. Denaturation and renaturation experiments indicate that Cu²⁺ ions exceeding the phosphate equivalents interact with the bases and reduce the forces of the DNA helix conformation. Evidence is presented, that the destabilization effect produced by Cu²⁺ is possibly due to an interaction with guanine sites of the DNA molecule.