Influence of DNA on the rate of ligand substitution in platinum(II) terpyridine complexes.

Abstract

The kinetics of substitution of pyridine or 2-methylpyridine, by iodide or thiourea, in the complexes [Pt(4'-R'terpy)(2-Rpy)](BF4)2 (R' = o-tolyl or H; R = H or CH3) has been studied, at 25 degrees C, pH 7, and various ionic strength values, in the presence of and without calf thymus DNA. The reactions occur in one observable step, and plots of kobsd against nucleophile concentration give straight lines with zero intercepts. DNA inhibits all the reactions studied without altering the rate law; the second-order rate constants k2 decrease systematically on increasing DNA concentration and are larger at higher ionic strength values. Partitioning of the ionic reactants in solution on electrostatic grounds can account for this kinetic effect in the reaction with iodide. Iodide is kept off the double helix proximity while the dicationic complexes concentrate on it. The inhibiting effect observed for the uncharged reagent thiourea can be related to the specific binding mode of the complexes to DNA. The complexes studied are effective intercalators to double helix, and this type of interaction, which prevents attack of thiourea at platinum, decreases their actual concentration in solution. The inhibiting effect is larger for [Pt(terpy)(py)]2+ that is a better intercalator. Likewise, the decrease in the rate of substitution of 2-Rpy, at a given [DNA] on decreasing ionic strength, is due to the influence of ionic strength on the complex-DNA interactions.