Distamycin A Complexation with a Nucleic Acid Triple Helix

Abstract

The interaction of the minor groove binding drug distamycin with the T-A-T triple helix and the A-T double helix was studied using circular dichroism spectroscopy and thermal denaturation. The triple helix was made by the oligonucleotide (dA)₁₂-x-(dT)₁₂-x-(dT)₁₂, where x is a hexaethylene glycol chain bridged between the 3‘-phosphate of one strand and the 5‘-phosphate of the following strand. This oligonucleotide is able to fold back on itself to form a very stable triplex. Changing the conditions allows the same oligonucleotide to be in a duplex form with a dangling arm. Circular dichroism spectroscopy demonstrates that the distamycin A molecule can bind to the triple-stranded form of this oligonucleotide. Spectral analysis shows that the bound distamycin exhibits a conformation and an environment slightly different from those which are observed when the drug is bound to the corresponding double-stranded structure. Furthermore, a second type of complex which is observed in the double-strand binding (two stacked distamycins in the minor groove) is not observed with the triple-stranded host. When distamycin is added to the triplex made of unbridged chains (dA)₁₂ + 2(dT)₁₂, the triplex dissociates to give a double-stranded structure. Thermal denaturation experiments demonstrate that distamycin binding destabilizes the triplex whereas it stabilizes the duplex. These results are compared with those obtained by the same experimental approaches on other minor groove binding drugs.