NMR studies and conformational analysis of a DNA four-way junction formed in a linear synthetic oligonucleotide.

Abstract

A linear DNA oligomer (M(r) 14,000, 46 nucleotides) was especially designed, chemically synthesized, and studied by means of 1H NMR spectroscopy. The design of the oligomer was guided by the idea that incorporation of three short palindromic sequences, each interspersed by 5'-CTTG-3' motifs at predetermined positions in the oligomer, would give rise to the formation of three stable minihairpin loops [Ippel, J. H., et al. (1992) J. Biomol. Struct. Dyn. 9, 1-16], which in turn were expected to encourage further folding of the strand into a stable four-way junction containing three "hairpin" arms and an open-ended duplex stem as the fourth arm. Linear DNA four-way junctions constructed according to this concept can be more compact and are therefore expected to be more suitable as model compounds for conformational studies compared to junctions that are built from two or more separate strands. A stable cruciform conformation was substantiated for the 46-mer in aqueous solution in the presence of Mg2+. Complete sequential 1H NMR assignments of the nonexchangeable protons (except H4', H5', and H5") were obtained with the aid of NOESY and HOHAHA experiments. The NMR data gave evidence for the expected existence of minihairpin-loop structures at the three 5'-CTTG-3' motifs in the sequence. The complementary stem domains adopt a regular B-DNA form. Watson-Crick type base pairing is preserved for all residues in the stem domains, including the residues at the center of the junction. A systematic investigation of the interresidual NOEs observed between the protons of the eight central residues revealed the complete stacking pattern of the residues at the branch point.