In vitro selection was performed in a DNA library, made of oligonucleotides with a 30-nucleotide random sequence, to identify ligands of the human immunodeficiency virus type-1 trans-activation-responsive (TAR) RNA element. Aptamers, extracted after 15 rounds of selection-amplification, either from a classical library of sequences or from virtual combinatorial libraries, displayed an imperfect stem-loop structure and presented a consensus motif 5ACTCCCAT in the apical loop. The six central bases of the consensus were complementary to the TAR apical region, giving rise to the formation of RNA-DNA kissing complexes, without disrupting the secondary structure of TAR. The RNA-DNA kissing complex was a poor substrate for Escherichia coli RNase H, likely due to steric and conformational constraints of the DNA/RNA heteroduplex. 2-O-Methyl derivatives of a selected aptamer were binders of lower efficiency than the parent aptamer in contrast to regular sense/antisense hybrids, indicating that the RNA/DNA loop-loop region adopted a non-canonical heteroduplex structure. These results, which allowed the identification of a new type of complex, DNA-RNA kissing complex, demonstrate the interest of in vitro selection for identifying non-antisense oligonucleotide ligands of RNA structures that are of potential value for artificially modulating gene expression.In the antisense strategy, a DNA oligonucleotide is designed to hybridize to an RNA sequence, in order to inhibit specifically the reading of the encoded genetic information (1). Although RNA is a single chain nucleic acid, it adopts secondary and tertiary structures, which can prevent the hybridization of the antisense sequence. This is one of the likely explanations of the poor inhibition efficiency, if any, induced by some antisense oligonucleotides. The aptamer strategy has been successfully used for the selection of ligands against a large range of targets, such as proteins and small molecules (nucleotides, amino acids, dyes) (see Ref. 2 for a review). This methodology offers an alternative way for designing nucleic acid ligands against an RNA structure. Indeed, we previously demonstrated that in vitro selection of DNA ligands (aptamers) against DNA secondary structures led to the identification of sequences able to recognize the DNA targets through base pair formation and additional unidentified interactions (3, 4). This might be of high potential interest, as numerous RNA structures display a regulatory function through interaction either with proteins (such as the iron-responsive element interacting with the ironresponsive element-binding protein (5), the HIV trans-activation-responsive (TAR) 1 element binding to the viral protein Tat (6), or the HIV Rev-responsive element promoting the export of retroviral RNA from the nucleus due to the binding with the viral protein Rev (6)) or with nucleic acids (like the dimerization-initiating sequence of HIV (7)). The binding of an oligonucleotide to such structures could prevent the interaction of the RNA with the regulator...
