A DNA APTAMER THAT BINDS ADENOSINE AND ATP

We have used in vitro selection to isolate adenosine/ATP-binding DNA sequences from a pool of approximate to 2 x 10(14) different random-sequence single-stranded DNA molecules. One of these aptamers has been characterized and binds adenosine in solution with a dissociation constant of 6 +/- 3 mu M. Experiments with ATP analogs indicate that functional groups on both the base and the sugar of ATP are involved in the ligand/aptamer interaction. The binding domain of this aptamer was localized to a 42 base sequence by deletion analysis. A pool of mutagenized versions of this sequence was then synthesized and screened for functional adenosine binding sequences; comparison of the selected variants revealed two highly conserved guanosine-rich regions, two invariant adenosine residues, and two regions of predominantly Watson-Crick covariation. This data led us to propose a model of the ATP-binding DNA structure which is based on a stable framework composed of two stacked G-quartets. The two highly conserved adenosine residues may stack between the top G-quartet and the two short stems, forming a pocket in which the adenosine or ATP ligand binds. Site-directed mutagenesis, base analog substitution studies, and the design of highly divergent but functional sequences provide support for this model.