A new approach to overcome potassium-mediated inhibition of triplex formation.

G,A-containing purine oligonucleotides of various lengths form extremely stable and specific triplexes with the purine-pyrimidine stretch of the vpx gene [Svinarchuk,F., Monnot,M., Merle,A., Malvy,C. and Fermandjian,S. (1995) Nucleic Acids Res., 22, 3742--3747]. The potential application of triple-helix-forming oligonucleotides (TFO) in gene-targeted therapy has prompted us to study triplex formation mimicking potassium concentrations and temperatures in cells. Triplex formation was tested by dimethyl sulphate (DMS) footprinting, gel-retardation, UV melting studies and electron microscopy. In the presence of 10 mM MgCl2, KCl concentrations up to 150 mM significantly lowered both efficiency (triplex : initial duplex) and rate constants of triplex formation. The KCl effect was more pronounced for 11mer and 20mer TFOs than for 14mer TFO. Since the dissociation half-life for the 11mer TFO decreases from 420 min in the absence of monovalent cations to 40 min in the presence of 150 mM KCI, we suggest that the negative effect could be explained by a decrease in triplex stability. In contrast, for the 20mer TFO no dissociation of the triplex was observed during 24 h of incubation either in the absence of monovalent cations or in the presence of 150 mM KCl. We suppose that in the case of the 20mer TFO the negative effect of KCI on triplex formation is probably due to the self-association of the oligonucleotide in competitive structures such as parallel duplexes and/or tetraplexes. This negative effect may be overcome by the prior formation of a short duplex either on the 3'- or 5'-end of the 20mer TFO. We refer to these partial duplexes as 'zipper' TFOs. It was demonstrated that a 'zipper' TFO can form a triplex over the full length of the target, thus unzipping the short complementary strand. The minimal single-stranded part of the 'zipper' oligonucleotide which is sufficient to initiate triplex formation can be as short as three nucleotides at the 3'-end and six nucleotides at the 5'-end. We suggest that this type of structure may prove useful for in vivo applications.