Potassium-induced loop conformational transition of a potent anti-HIV oligonucleotide

Spectroscopic, thermal denaturation and kinetic studies have revealed that DNA oligonucleotides 5'-d(GGGTGGGTGGGTGGGT) (T30695) and 5'-d(GTGGTGGGTGGGTGGGT) (T30177) form extremely stable intramolecular G-terrads via a two-step process that involves the binding of one K+ ion to a central pair of G-quartets and two additional K+ ions, presumably, to the loops (Jing et al., (1997) Biochemistry in press). In that these oligonucleotides are potent HIV-1 inhibitors and among the most active HIV-1 integrase inhibitors yet identified, we have sought to further characterize the K+-induced folding process for the purpose of rational chemical modification of these anti-HIV agents. Our NMR investigation demonstrates that in the presence of Li+ ions, T30695 forms an unimolecular tetrad fold, stabilized by a pair of syn-anti-syn-anti G-quartets comprising a central core. The NMR spectrum of T30695 as a function of K+ titration reveals a well-defined transition that saturates upon addition of three K+ ions per oligomer. During this process, the initial Li+-dependent G-quartet structure converts into a highly symmetrical, stable form (the NMR detected melting transition temperature is increased by similar to 20 degrees C). The conformation of the G-quartet core remains unchanged, while the loosely structured loop residues become organized, in a fashion which is stabilized by K+ ion binding and by interactions with the core. To explain these data, we propose a model wherein K+ binding to the loops induces structural rearrangement, to yield a planar array of loop bases in proximity to the underlying C-quartets. By reference to closely related homologues, which lack activity as an HIV-I or integrase inhibitor, the possibility is discussed that this ion-coordinated loop structure is crucial to the biological activity of T30695.