Biophysical and biological characterization of hairpin and molecular beacon RNase H active antisense oligonucleotides.

Antisense oligonucleotides (ASOs) are single stranded, backbone modified nucleic acids, which mediate cleavage of complementary RNA by directing RNase H cleavage in cell culture and in animals. It has generally been accepted that the single stranded state in conjunction with the phosphorothioate modified backbone is necessary for cellular uptake and transport to the active compartment. Herein, we examine the effect of using hairpin structured ASOs to (1) determine if an ASO agent requires a single stranded conformation for efficient RNA knock down, (2) use a fluorophore-quencher labeled ASO to evaluate which moieties the ASO interacts with in cells and examine if cellular distribution can be determined with such probes, and (3) evaluate if self-structured ASOs can improve allele selective silencing between closely related huntingtin alleles. We show that hairpin shaped ASOs can efficiently down-regulate RNA in vitro, but potency correlates strongly negatively with increasing stability of the hairpin structure. Furthermore, self-structured ASOs can efficiently reduce huntingtin mRNA in the central nervous system of mice.