Gene silencing by double-stranded RNA

Thanks to the Nobel Foundation for permission to publish this Lecture. We report here the Nobel Lecture delivered by Professor Andrew Z Fire. Together with the accompanying lecture by Professor Mello this lecture describes the exciting years leading to the discovery of RNA interference (RNAi) and some of the underlying molecular mechanisms. Professor Fire nicely points out his own contribution and the contribution of other research groups to the development of this field. He also presents an interesting discussion on the role of RNAi in immunity and challenges us with a number of open questions. The lecture ends presenting the great potential of exploiting RNAi for therapeutical purposes.     

Gene silencing by double-stranded RNA

Eukaryotes silence gene expression in the presence of double-stranded RNA homologous to the silenced gene. Silencing occurs by the targeted degradation of mRNA. Biochemical reactions that recapitulate this phenomenon generate RNA fragments of 21--23 nucleotides from the double-stranded RNA. These stably associate with an RNA endonuclease and probably serve as a discriminator to select mRNAs. Once selected, mRNAs are cleaved at sites 21--23 nucleotides apart. This mechanism, termed RNAi, has functional links to viral defense and silencing phenomena, such as cosuppression. It also functions to repress the hopping of transposable elements.     

Gene silencing in chick embryos with a vector-based small interfering RNA system

In this paper, the use of vector-based RNA interference (RNAi) to specifically interfere with gene expression in chick embryos is reported. In ovo electroporation was carried out to transfer a small interfering RNA (siRNA) expression vector into chick embryos. En2 was chosen for the target gene because the family gene, En1, is expressed in a similar pattern. Four sets of 19-mer sequences were designed with the En2 open reading frame region connected to a sequence of short hairpin RNA (shRNA), which exerts siRNA effects after being transcribed, and inserted into pSilencer U6-1.0 vector. En2 and En1 expression were suppressed by the siRNA whose sequence completely matched En2 and En1. Suppression occurred when the siRNA sequence differed by up to two nucleotides from the target sequence. The sequence that differed by four nucleotides from the target gene did not show siRNA effects. One set that completely matched the En2 target did not show siRNA effects, which may be due to location of the siRNA in the target gene. Thus, multiple sets of shRNA must be prepared if we are to consider. This system will greatly contribute to the analysis of function of genes of interest, because the target gene can be silenced in a locally and temporally desired manner.     

Baculovirus-mediated gene silencing in insect cells using intracellularly produced long double-stranded RNA

Double-stranded RNA-mediated interference (RNAi) has recently emerged as a powerful reverse genetics tool to silence gene expression in multiple organisms, including plants, nematodes and insects. In this study, DNA vectors capable of promoting the synthesis of long hairpin dsRNAs in vivo from a DNA template to suppress gene expression in insect cells have been successfully constructed. The inhibition of the expression of a gene encoding enhanced green fluorescent protein (eGFP) in insect cells was demonstrated by using plasmid or baculovirus vectors. Both plasmid and baculovirus vectors were able to inhibit eGFP expression in a dose dependent manner. Complete inhibition was obtained when co-transfection ratios of target plasmid to inhibition plasmid were 1:1 and 1:0.1. Eighty percent suppression was still maintained even when the ratio of eGFP plasmid to 'hairpin' plasmid was as high as 1:0.01. When the hairpin dsRNAs were encoded in a baculovirus, the suppression was about 50% when the ratio of 'target' baculovirus to 'inhibition' baculovirus reached 1:10. Therefore, the designed plasmid and baculovirus vectors are useful to induce RNAi in insect cell systems.     

Gene silencing of selected calcium-signalling molecules in a Drosophila cell line using double-stranded RNA interference

Using the Drosophila melanogaster S2 cell line, stably expressing a cloned muscarinic acetylcholine receptor (AChR), DM1, we have applied gene silencing by double-stranded RNA interference (RNAi) to knock down gene products involved in DM1-mediated calcium signalling. We have shown that RNAi knock down of either the inositol 1,4,5-trisphosphate receptor (Ins(1,4,5)P(3)R), or the SERCA calcium pump in the S2-DM1 cells blocks the increase in intracellular calcium concentration ([Ca(2+)](i)) resulting from activation of the DM1 receptor by 100 microM carbamylcholine (CCh). When RNAi designed to knock down the ryanodine receptor (RyR) was tested, there was no change in the calcium increase detected in response to CCh, consistent with a failure to detect RyRs in S2-DM1 cells using RT-PCR. A combination of RNAi and calcium imaging has provided a direct demonstration of key roles for the Ins(1,4,5)P(3)R and the SERCA pump in the response to DM1 receptor activation.Thus, we show that silencing of individual genes by RNAi in a well characterised Drosophila S2 cell line offers experimental opportunities for cell-signalling studies. Future investigations with RNAi libraries taking full advantage of the wealth of new information available from sequencing the Drosophila genome, may help identify novel components of cell-signalling pathways and functionally linked gene products.     

Gene silencing in mammals by small interfering RNAs

Among the 3 billion base pairs of the human genome, there are approximately 30,000-40,000 protein-coding genes, but the function of at least half of them remains unknown. A new tool - short interfering RNAs (siRNAs) - has now been developed for systematically deciphering the functions and interactions of these thousands of genes. siRNAs are an intermediate of RNA interference, the process by which double-stranded RNA silences homologous genes. Although the use of siRNAs to silence genes in vertebrate cells was only reported a year ago, the emerging literature indicates that most vertebrate genes can be studied with this technology.     

Heritable gene silencing in Drosophila using double-stranded RNA

RNA-mediated interference (RNAi) is a recently discovered method to determine gene function in a number of organisms, including plants, nematodes, Drosophila, zebrafish, and mice. Injection of double-stranded RNA (dsRNA) corresponding to a single gene into organisms silences expression of the specific gene. Rapid degradation of mRNA in affected cells blocks gene expression. Despite the promise of RNAi as a tool for functional genomics, injection of dsRNA interferes with gene expression transiently and is not stably inherited. Consequently, use of RNAi to study gene function in the late stages of development has been limited. It is particularly problematic for development of disease models that reply on post-natal individuals. To circumvent this problem in Drosophila, we have developed a method to express dsRNA as an extended hairpin-loop RNA. This method has recently been successful in generating RNAi in the nematode Caenorhabditis elegans. The hairpin RNA is expressed from a transgene exhibiting dyad symmetry in a controlled temporal and spatial pattern. We report that the stably inherited transgene confers specific interference of gene expression in embryos, and tissues that give rise to adult structures such as the wings, legs, eyes, and brain. Thus, RNAi can be adapted to study late-acting gene function in Drosophila. The success of this approach in Drosophila and C. elegans suggests that a similar approach may prove useful to study gene function in higher organisms for which transgenic technology is available.     

Long double-stranded RNA-mediated RNA interference and immunostimulation: long interfering double-stranded RNA as a potent anticancer therapeutics

In most applications, small interfering RNAs are designed to execute specific gene silencing via RNA interference (RNAi) without triggering nonspecific responses such as immunostimulation. However, in anticancer therapeutics, immunostimulation combined with specific oncogene silencing could be beneficial, resulting in the synergistic inhibition of cancer cell growth. In this study, we report an immunostimulatory long double-stranded RNA (dsRNA) structure with the ability to trigger RNAi-mediated specific target gene silencing, termed as long interfering dsRNA (liRNA). liRNA targeting Survivin mRNA not only efficiently and specifically triggered target gene silencing via RNAi, but also stimulated the protein kinase R pathway to induce the expression of interferon β. As a result, the ability of Survivin-targeting liRNA to inhibit cancer cell growth was superior over conventional small interfering RNA or nontargeting dsRNA structures. Our results thus provide a simple yet efficient dual function immunostimulatory RNAi-triggering structure, which is potentially applicable for the development of anticancer therapeutics.     

Photochemically induced gene silencing using small interfering RNA molecules in combination with lipid carriers

Novel strategies for efficient delivery of small interfering RNA (siRNA) molecules with a potential for targeting are required for development of RNA interference (RNAi) therapeutics. Here, we present a strategy that is based on delivery of siRNA molecules through the endocytic pathway, in order to develop a method for site-specific gene silencing. To achieve this, we combined the use of cationic lipids and photochemical internalization (PCI). Using the human S100A4 gene as a model system, we obtained potent gene silencing in four tested human cancer cell lines following PCI induction when using the cationic lipid jetSI-ENDO. Gene silencing was shown at both the RNA and protein levels, with no observed PCI toxicity when using the jetSI reagent and an optimized PCI protocol. This novel induction method opens for in vivo site-specific delivery of siRNA molecules toward a sequence of interest.     

Novel vaccination for allergy through gene silencing of CD40 using small interfering RNA

Small interfering RNA (siRNA) is a potent means of inducing gene-specific silencing. Gene silencing strategies using siRNA have demonstrated therapeutic benefits in animal models of various diseases, and are currently in clinical trials. However, the utility of gene silencing as a treatment for allergic diseases has not yet been reported. In this study, we report a novel therapy for allergy through gene silencing of CD40, a critical costimulatory molecule and a key factor in allergic immune responses. Silencing CD40 resulted in generation of immunoregulatory dendritic cells (DCs). Administration of CD40 siRNA remarkably reduced nasal allergic symptoms and local eosinophil accumulation in the OVA-induced allergic mice. The OVA-specific T cell response was inhibited after the CD40 siRNA treatment. Additionally, anti-OVA specific IgE and production of IL-4 and IL-5 of T cells stimulated by OVA were significantly decreased in CD40 siRNA-treated mice. Furthermore, we demonstrated that the therapeutic effects by CD40 siRNA were associated with impaired Ag-presenting functions of DCs and B cells, and generation of regulatory T cells. The present study highlights a therapeutic potential of siRNA-based treatment for allergic diseases.     

Analysis of double-stranded RNA-induced apoptosis pathways using interferon-response noninducible small interfering RNA expression vector library

We have developed an original vector library that allowed us to exploit the phenomenon of RNA interference but also allowed us to avoid the confounding effects of the interferon response. In the present work, we used our library of small interfering RNA expression vectors to examine the genes involved in apoptosis that was induced by double-stranded RNA. To our surprise, screening of our library revealed two novel double-stranded RNA-induced apoptotic pathways, a JNK/SAPK-mediated mitochondrial pathway and an ERK2-related pathway, both of which appeared to be independent of the serine-threonine protein kinase-dependent caspase pathway. We also found that MST2 and protein kinase Calpha both activated the pro-apoptotic signal mediated by ERK2. The results of our screening analysis suggested the utility of large scale screenings with libraries of small interfering RNA expression vectors.     

Evaluation of various polyethylenimine formulations for light-controlled gene silencing using small interfering RNA molecules

Photochemical internalization (PCI) is a technology based on a photosensitizer that photochemically destabilizes endosomal membranes after illumination, resulting in the release of endocytosed material into the cytosol. In this study, we investigated the potential of using polyethylenimine (PEI) for light-controlled delivery of small interfering RNA (siRNA) molecules via the endocytic pathway. PEI formulations with different molecular weights (MW) and chemical forms (linear [L]/branched [B]) were investigated for their capacity to deliver siRNA molecules with or without PCI at variable nitrogen/phosphorus (N/P) ratios and illumination doses. By targeting the S100A4 gene in an osteosarcoma cell model system, potent gene silencing was observed in samples treated with PCI compared with samples not treated with PCI. The effect of light-controlled gene silencing was dependent on several factors, including light-doses and MW, chemical form, as well as on the N/P ratio of the PEI formulations. This study demonstrates the first success in using PEI formulations as siRNA carriers for light-controlled gene silencing with the objective of future use in in vivo applications.     

Specific gene silencing using small interfering RNAs in fish embryos

Recently, small interfering RNAs (siRNAs) have been used for gene knockdown in mammalian cultured cells, but their utility in fish has remained unexplored. Here we demonstrate a siRNA-mediated gene silencing technique in rainbow trout embryos. We found that siRNAs effectively suppressed the transient expression of episomally located foreign GFP genes at an early developmental stage and inhibited the expression of GFP genes in stable transgenic trout embryos. Similar gene silencing was observed with an siRNA against the endogenous tyrosinase A gene. siRNAs interfered with the expression of maternally inherited mRNA. siRNAs did not affect non-relevant gene expression and siRNAs with a 4 base mismatch did not affect target gene expression. siRNA gene silencing is therefore highly sequence-specific. Our findings are the first evidence that siRNA-mediated gene silencing is effective in fish. This technique could be a powerful tool for studying gene function during embryonic development in aquacultural fish species, zebrafish, and medaka.     

Gene silencing：Double－stranded RNA mediated mRNA degradation and gene inactivation

INTRODUCTIONThe genome structure of plants can be alteredby genetic transformation. During the process ofgene transfer, Agrobacterium tumefaCJens integratepart of their genome into the genome of susceptiblespecies. Recently, genetic transfOrmation techniqueshave been used to modify significantly the organi-zation of the genome. Introducing transgenes intop1ants can both modify the number of copies of agiven sequence and affect gene expression. Becausethe expression of a transgene cannot…     

Improved silencing properties using small internally segmented interfering RNAs

RNA interference is mediated by small interfering RNAs (siRNAs) that upon incorporation into the RNA-induced silencing complex (RISC) can target complementary mRNA for degradation. Standard siRNA design usually feature a 19–27 base pair contiguous double-stranded region that is believed to be important for RISC incorporation. Here, we describe a novel siRNA design composed of an intact antisense strand complemented with two shorter 10–12 nt sense strands. This three-stranded construct, termed small internally segmented interfering RNA (sisiRNA), is highly functional demonstrating that an intact sense strand is not a prerequisite for RNA interference. Moreover, when using the sisiRNA design only the antisense strand is functional in activated RISC thereby completely eliminating unintended mRNA targeting by the sense strand. Interestingly, the sisiRNA design supports the function of chemically modified antisense strands, which are non-functional within the context of standard siRNA designs. This suggests that the sisiRNA design has a clear potential of improving the pharmacokinetic properties of siRNA in vivo.