Synthesis and DNA conformational changes of non-covalent polynuclear platinum complexes.

Polynuclear platinum compounds demonstrate many novel phenomena in their interactions with DNA and proteins as well as novel anti-cancer activities. Previous studies indicated that the high positive charge and the non-coordinated "central linker" of the polynuclear compounds could have major contributions to these features. Therefore, a series of non-covalent polynuclear platinum complexes, [[Pt(NH(3))(3)](2)-mu-Y](n+) (Y=polyamine linker or [trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]) was synthesized and the DNA interactions of these platinum complexes were investigated. The conformational changes induced by these compounds in polymer DNA were studied by circular dichroism and the reversibility of the transition was tested by subsequent titration with the DNA intercalating agent ethidium bromide (EtBr). Fluorescent quenching was also used to assess the ability of EtBr to intercalate into A and Z-DNA induced by the compounds. The non-covalent polynuclear platinum complexes induced both B-->A and B-->Z conformational changes in polymer DNA. These conformational changes were partially irreversible. The platinum compound with the spermidine linker, [[Pt(NH(3))(3)](2)-mu-spermidine-N(1),N(8)]Cl(5).2H(2)O, is more efficient in inducing the conformational changes of DNA and it is less reversible than complexes with other linkers. The melting point study showed that the non-covalent polynuclear platinum complexes stabilized the duplex DNA and the higher the electrical charge of the complexes the greater the stabilization observed.

A comparison of DNA binding profiles of dinuclear platinum compounds with polyamine linkers and the trinuclear platinum phase II clinical agent BBR3464.

The DNA binding profiles of three bis Pt(II) polyamine-linked compounds, [[ trans-PtCl(NH(3))(2)](2)[mu-spermine- N(1), N(12)]](4+), [[ trans-PtCl(NH(3))(2)](2)[mu-spermidine- N(1), N(8)]](3+), and [[ trans-PtCl(NH(3))(2)](2)[mu-BOC-spermidine]](2+), were compared with that of a novel trinuclear phase II clinical agent, [[ trans-PtCl(NH(3))(2)](2)[mu- trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]](4+). All of the compounds bind preferentially in a bifunctional manner, according to unwinding of supercoiled DNA circles. The kinetics of binding of these compounds corresponds to their relative charge (2+ to 4+). The preference for the formation of interstrand crosslinks, however, does not follow a charge-based pattern. By studying the results of DNA polymerase extension products on a DNA template modified by the compounds, and by incorporating the complementary method of RNA transcription mapping, it was possible to determine the nucleotide bases that are preferred sites of binding. The stop sites due to platinum adducts were determined, and some preliminary observations concerning the range and type of crosslinks were established. It can be concluded that dinuclear Pt compounds are similar to their trinuclear counterpart, and that charge differences do not contribute solely to the variances between the compounds.