Search for oligonucleotides selectively binding oncogenic miR-21

In the pathogenesis of malignancies, an active regulatory role belongs to small noncoding RNAs, miRNA (miR). miRNA expression profiles are often associated with the prognosis and therapeutic outcome of different oncological diseases. It is well known that in comparison with normal tissues cancer cells are characterized by hyperexpression of oncogenic miRNAs which leads to oncogenic transformation, carcinogenesis and metastasis progression. From this point of view, selective down-regulation of miRNA expression by specific agents, such as antisense oligonucleotides that recognize particular sequences, therefore, can be an effective tool to regulate the amount of miRNA in cancer cells and decrease tumor malignancy. In this paper, we have designed a series of antisense oligonucleotides addressed to the oncogenic miR-21 with a view to its selective binding and studied patterns of interaction of miR-21 with these oligonucleotides in vitro. The series included linear and hairpin oligonucleotides with the length of antisense fragment of 10–16 nucleotides (nt) complementary to the 5'- or the 3'-end of miRNA target. Hairpin oligonucleotides consist of a sequence complementary to miR-21 and a hairpin containing a four-nucleotide loop and stem of 6–9 bp necessary for stabilizing the complex with miR-21. It has been shown that inclusion of the hairpin with the stem of 6 bp to the oligonucleotide structure leads to a 1.6-fold increase in binding efficiency with miR-21 in comparison with a linear oligonucleotide and elongation of the stem from six to nine bp does not increase binding efficiency. Hairpin oligonucleotides with an antisense sequence of 14 nt effectively hybridize with miR-21 and are not inferior to 16-mer linear and hairpin oligonucleotides in the efficiency of complex formation. Thus, we have shown that hairpin oligonucleotides with antisense fragment of 14 nt and a hairpin, including the stem of 6 bp, are optimal for selective and effective sequestering of mature miR-21.