Author(s): Lin SL, Chang DC, Ying SY
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Abstract Computer programming has identified hundreds of genomic hairpin sequences, many with functions remain to be determined. Because direct transfection of hairpin-like miRNA precursors (pre)-miRNAs in mammalian cells is not always sufficient to trigger effective RNA-induced gene silencing complex (RISC) assembly, a key step for RNA interference (RNAi)-related gene silencing, we developed an intronic miRNA-expressing system to overcome this problem by inserting a hairpin-like pre-miRNA structure into the intron region of a gene and successfully increased the efficiency and effectiveness of miRNA-associated RNAi induction in vitro and in vivo. This intronic miRNA biogenesis has been found to depend on a coupled interaction of nascent precursor messenger RNA transcription and intron excision within a specific nuclear region proximal to genomic perichromatin fibrils. The intronic miRNA was transcribed by RNA type II polymerases, coexpressed with a primary gene transcript, and excised out of its encoding gene transcript by intracellular RNA splicing and processing mechanisms. Currently, some ribonuclease III endonucleases have been found to be involved in the processing of spliced introns and probably facilitating the intronic miRNA maturation. Using this miRNA generation system, we have shown for the first time that the intron-derived miRNAs were able to induce strong RNAi effects in not only human and mouse cells but also zebrafishes, chicken embryos, and adult mice. We have also developed an miRNA isolation protocol, based on the complementarity between the designed miRNA and its target gene sequence, to purify and identify the mature miRNAs generated by the intronic miRNA-expressing system. Several intronic miRNA identities and structures are currently confirmed to be active in vitro and in vivo. According to this proven-of-principle method, we now have full knowledge to design pre-miRNA inserts that are more efficient and effective for the intronic miRNA-expressing systems.
This article was published in Methods Mol Biol
and referenced in Molecular Biology: Open Access