Kinetics and equilibria for the formation of a new DNA metal-intercalator: the cyclic polyamine Neotrien/copper(II) complex.

A study has been performed of the kinetics and equilibria involved in complex formation between the macrocyclic polyamine 2,5,8,11-tetraaza[12]-[12](2,9)[1,10]-phenanthrolinophane (Neotrien) and Cu(II) in acidic aqueous solution and ionic strength 0.5 M (NaCl), by means of the stopped-flow method and UV spectrophotometry. Spectrophotometric titrations and kinetic experiments revealed that the binding of Cu(II) to Neotrien gives rise to several 1:1 complexes differing in their degree of protonation. Under the experimental hydrogen ion concentration range investigated, complexation occurs by two parallel paths: (a) M2+ + (H4L)4+ <==> (MH4L)6+ and (b) M2+ + (H3L)3+ <==> (MH3L)5+. The rate constants values found for complex formation, by paths (a) and (b), are much lower than the values expected from water exchange at copper(II) and other amine/Cu(II) complexation kinetic constants. Kinetic experiments at different NaCl concentrations indicated that this finding was not due to chloride ion competition in complex formation with Neotrien, but it was related to a ring rigidity effect. As the phenanthroline moiety could, in principle, interact with nucleic acids by intercalation or external binding, some preliminary measurements concerned with the possible interactions occurring between the Cu(II)/Neotrien complex and calf thymus DNA (CT-DNA) have also been carried out. The absorption spectra of the Cu(II)/Neotrien complex change upon addition of CT-DNA at pH 7.0, revealing the occurrence of complex-nucleic acid interactions. Moreover, fluorescence titrations, carried out by adding the Cu(II)/Neotrien complex to CT-DNA, previously saturated with ethidium bromide (EB), show that the Cu(II)/Neotrien complex is able to displace EB from DNA, suggesting the complex is able to intercalate into the polynucleotide and then to cleave the phosphodiester bond of DNA.