Design and synthesis of RNA miniduplexes via a synthetic linker approach.

Double-stranded oligodeoxyribonucleotides or single-stranded oligoribonucleotides with specific secondary structure have been proposed as potential antagonists to target nucleic acid-binding proteins (the sense approach). A major limitation of this strategy is that these derivatives are generally considered to be too large for pharmaceutical applications. We have developed a synthetic linker approach whereby nucleic acid duplexes of a much smaller size (miniduplexes) can be generated directly from a standard oligonucleotide synthesis. In this approach, four synthetic linkers (derivatized respectively from 1,9-nonanediol, triethylene glycol, 1,3-propanediol, and hexaethylene glycol) of different length and hydrophobicity were designed and incorporated into a model RNA molecule based on the TAR stem-loop structure of HIV-1. Their thermal stabilities were evaluated by measuring denaturation profiles (Tm measurements). These linker-derivatized RNA molecules were then assessed for their ability to bind to either a full-length protein (HIV-1 Tat protein) or a short peptide (Tat-derived peptide) through RNA mobility shift assays. Results from this study indicate that such modified miniduplex structures retain full binding activity relative to that of the wild-type sequence (Kd values), while Tm values were increased by 24-31 degrees C compared to an open duplex of the same length. This system provides a new direction in the use of nucleic acid miniduplexes as a novel class of oligonucleotide analogues for both fundamental research and possible therapeutic applications.