Enhanced intracellular delivery and multi-target gene silencing triggered by tripodal RNA structures.

BACKGROUND: The development of gene interfering RNA (iRNA) molecules such as small interfering RNAs (siRNAs) and antagomirs provides promising therapeutic modalities for targeting specific mRNAs and microRNAs (miRNAs) involved in disease mechanisms. Therapeutic iRNA strategy against cancer or hypermutable viruses prefers targeting multiple genes simultaneously to achieve synergistic inhibition and to prevent resistance. METHODS: In the present study, we report chemically synthesized, multi-target gene interfering RNA structures based upon branched, tripodal interfering RNAs (termed T-tiRNAs). RESULTS: The T-tiRNAs could simultaneously inhibit up to three different mRNAs or miRNAs by harboring three siRNA or antagomir units. Moreover, when complexed with cationic delivery vehicles, T-tiRNAs showed enhanced gene interfering activity over conventional siRNAs or antagomirs as a result of increased intracellular delivery. CONCLUSIONS: The data obtained in the present study provide an example of synthetic multi-functional RNA structures that enable multiple gene interference in mammalian cells, which could become powerful tools for an efficient combinatorial iRNA strategy.

Asymmetric shorter-duplex siRNA structures trigger efficient gene silencing with reduced nonspecific effects.

Small interfering RNAs (siRNAs) are short, double-stranded RNAs that mediate efficient gene silencing in a sequence-specific manner by utilizing the endogenous RNA interference (RNAi) pathway. The current standard synthetic siRNA structure harbors a 19-base-pair duplex region with 3' overhangs of 2 nucleotides (the so-called 19+2 form). However, the synthetic 19+2 siRNA structure exhibits several sequence-independent, nonspecific effects, which has posed challenges to the development of RNAi therapeutics and specific silencing of genes in research. In this study, we report on the identification of truncated siRNA backbone structures with duplex regions shorter than 19 bp (referred to as asymmetric shorter-duplex siRNAs or asiRNAs) that can efficiently trigger gene silencing in human cell lines. Importantly, this asiRNA structure significantly reduces nonspecific effects triggered by conventional 19+2 siRNA scaffold, such as sense-strand-mediated off-target gene silencing and saturation of the cellular RNAi machinery. Our results suggest that this asiRNA structure is an important alternative to conventional siRNAs for both functional genomics studies and therapeutic applications.

Asymmetric RNA duplexes mediate RNA interference in mammalian cells.

RNA interference (RNAi) has become an indispensable technology for biomedical research and has demonstrated the potential to become a new class of therapeutic. Current RNAi technology in mammalian cells relies on short interfering RNA (siRNA) consisting of symmetrical duplexes of 19-21 base pairs (bp) with 3' overhangs. Here we report that asymmetric RNA duplexes with 3' and 5' antisense overhangs silence mammalian genes effectively. An asymmetric interfering RNA (aiRNA) of 15 bp was incorporated into the RNA-induced silencing complex (RISC) and mediated sequence-specific cleavage of the target mRNA between base 10 and 11 relative to the 5' end of the antisense strand. The gene silencing mediated by aiRNA was efficacious, durable and correlated with reduced off-target silencing by the sense strand. These results establish aiRNA as a scaffold structure for designing RNA duplexes to induce RNAi in mammalian cells.

Selective induction of necrotic cell death in cancer cells by beta-lapachone through activation of DNA damage response pathway.

Most efforts thus far have been devoted to develop apoptosis inducers for cancer treatment. However, apoptotic pathway deficiencies are a hallmark of cancer cells. We propose that one way to bypass defective apoptotic pathways in cancer cells is to induce necrotic cell death. Here we show that selective induction of necrotic cell death can be achieved by activation of the DNA damage response pathways. While beta-lapachone induces apoptosis through E2F1 checkpoint pathways, necrotic cell death can be selectively induced by beta-lapachone in a variety of cancer cells. We found that beta-lapachone, unlike DNA damaging chemotherapeutic agents, transiently activates PARP1, a main regulator of the DNA damage response pathway, both in vitro and in vivo. This occurs within minutes of exposure to beta-lapachone, resulting in selective necrotic cell death. Inhibition of PAR blocked beta-lapachone-induced necrosis. Furthermore, necrotic cell death induced by beta-lapachone was significantly reduced in PARP1 knockout cell lines. Our data suggest that selective necrotic cell death can be induced through activation of DNA damage response pathways, supporting the idea of selective necrotic cell death as a therapeutic strategy to eliminate cancer cells.

Selective killing of cancer cells by beta -lapachone: direct checkpoint activation as a strategy against cancer.

Most chemotherapeutic drugs kill cancer cells by indirectly activating checkpoint-mediated apoptosis after creating nonselective damage to DNA or microtubules, which accounts for their toxicity toward normal cells. We seek to target cancer cells by directly activating checkpoint regulators without creating such damage. Here, we show that beta-lapachone selectively induces apoptosis in cancer cells without causing the death of nontransformed cells in culture. This unusual selectivity against cancer cells is preceded by activation of S-phase checkpoint and selective induction of E2F1, a regulator of checkpoint-mediated apoptosis. This study suggests direct checkpoint activation as a strategy against cancer.