Development of a Multipurpose GATEWAY-Based Lentiviral Tetracycline-Regulated Conditional RNAi System (GLTR)

RNA interference (RNAi) has become an essential technology for functional gene analysis. Its success, however, depends on the effective expression of RNAi-inducing small double-stranded interfering RNA molecules (siRNAs) in target cells. In many cell types, RNAi can be achieved by transfection of chemically synthesised siRNAs, which results in transient knockdown of protein expression. Expression of double-stranded short hairpin RNA (shRNA) provides another means to induce RNAi in cells that are hard to transfect. To facilitate the generation of stable, conditional RNAi cell lines, we have developed novel one- and two-component vector GATEWAY-compatible lentiviral tetracycline-regulated RNAi (GLTR) systems. The combination of a modified RNA-polymerase-III-dependent H1 RNA promoter (designated ‘THT’) for conditional shRNA expression with different lentiviral delivery vectors allows (1) the use of fluorescent proteins for colour-coded combinatorial RNAi or for monitoring RNAi induction (pGLTR-FP), (2) selection of transduced cells (pGLTR-S), and (3) the generation of conditional cell lines using a one vector system (pGLTR-X). All three systems were found to be suitable for the analysis of essential genes, such as CDC27, a component of the mitotic ubiquitin ligase APC/C, in cell lines and primary human cells.     

An inducible system for expression and validation of the specificity of short hairpin RNA in mammalian cells

RNA interference (RNAi) by means of short hairpin RNA (shRNA) has developed into a powerful tool for loss-of-function analysis in mammalian cells. The principal problem in RNAi experiments is off-target effects, and the most vigorous demonstration of the specificity of shRNA is the rescue of the RNAi effects with a shRNA-resistant target gene. This presents its own problems, including the unpredictable relative expression of shRNA and rescue cDNA in individual cells, and the difficulty in generating stable cell lines. In this report, we evaluated the plausibility of combining the expression of shRNA and rescue cDNA in the same vector. In addition to facilitate the validation of shRNA specificity, this system also considerably simplifies the generation of shRNA-expressing cell lines. Since the compensatory cDNA is under the control of an inducible promoter, stable shRNA-expressing cells can be generated before the knockdown phenotypes are studied by conditionally turning off the rescue protein. Conversely, the rescue protein can be activated after the endogenous protein is completely repressed. This approach is particularly suitable when prolonged expression of either the shRNA or the compensatory cDNA is detrimental to cell growth. This system allows a convenient one-step validation of shRNA and generation of stable shRNA-expressing cells.     

Silencing of antiapoptotic survivin gene by multiple approaches of RNA interference technology

Silencing of mammalian gene expression by RNA interference (RNAi) technology can be achieved using small interfering RNA (siRNA) or short hairpin RNA (shRNA). However, the relative effectiveness of these two approaches is not known. It is also not clear whether gene-specific shRNA transcribed from an RNA polymerase II (Pol II)-directed promoter in a fusion form can disrupt the targeted gene expression. Here, we report that using both luciferase and antiapoptotic survivin genes as targets, both siRNA and shRNA approaches significantly silenced the targeted gene expression in cancer cells. We further demonstrated that shRNAs transcribed from an RNA Pol II-mediated promoter in a green fluorescent protein (GFP) fusion form at the 3'-untranslated region silenced luciferase and survivin expression as well, suggesting that the extra RNA sequence outside of the shRNA hairpin does not disrupt shRNA function. We also showed that silencing of survivin expression selectively induces apoptosis in transfected cells. Together, we have validated multiple approaches of RNAi technology using both survivin and luciferase genes as targets and demonstrated for the first time that GFP-shRNAs transcribed from an RNA Pol II-mediated promoter could mediate gene silencing, which may lead to new directions for the application of RNAi technology.     

The anti-genomic (negative) strand of Hepatitis C Virus is not targetable by shRNA

Hepatitis C Virus (HCV) and other plus-strand RNA viruses typically require the generation of a small number of negative genomes (20–100× lower than the positive genomes) for replication, making the less-abundant antigenome an attractive target for RNA interference(RNAi)-based therapy. Because of the complementarity of duplex short hairpin RNA/small interfering RNA (shRNA/siRNAs) with both genomic and anti-genomic viral RNA strands, and the potential of both shRNA strands to become part of the targeting complexes, preclinical RNAi studies cannot distinguish which viral strand is actually targeted in infected cells. Here, we addressed the question whether the negative HCV genome was bioaccessible to RNAi. We first screened for the most active shRNA molecules against the most conserved regions in the HCV genome, which were then used to generate asymmetric anti-HCV shRNAs that produce biologically active RNAi specifically directed against the genomic or antigenomic HCV sequences. Using this simple but powerful and effective method to screen for shRNA strand selectivity, we demonstrate that the antigenomic strand of HCV is not a viable RNAi target during HCV replication. These findings provide new insights into HCV biology and have important implications for the design of more effective and safer antiviral RNAi strategies seeking to target HCV and other viruses with similar replicative strategies.     

Transgenic RNA interference in ES cell-derived embryos recapitulates a genetic null phenotype

Gene targeting via homologous recombination in murine embryonic stem (ES) cells has been the method of choice for deciphering mammalian gene function in vivo. Despite improvements in this technology, it still remains a laborious method. Recent advances in RNA interference (RNAi) technology have provided a rapid loss-of-function method for assessing gene function in a number of organisms. Studies in mammalian cell lines have shown that introduction of small interfering RNA (siRNA) molecules mediates effective RNA silencing. Plasmid-based systems using RNA polymerase III (RNA pol III) promoters to drive short hairpin RNA (shRNA) molecules were established to stably produce siRNA. Here we report the generation of knockdown ES cell lines with transgenic shRNA. Because of the dominant nature of the knockdown, embryonic phenotypes could be directly assessed in embryos completely derived from ES cells by the tetraploid aggregation method. Such embryos, in which endogenous p120-Ras GTPase-activating protein (RasGAP), encoded by Rasa1 (also known as RasGAP), was silenced, had the same phenotype as did the previously reported Rasa1 null mutation.     

shRNA target prediction informed by comprehensive enquiry (SPICE): a supporting system for high-throughput screening of shRNA library

RNA interference (RNAi) screening is extensively used in the field of reverse genetics. RNAi libraries constructed using random oligonucleotides have made this technology affordable. However, the new methodology requires exploration of the RNAi target gene information after screening because the RNAi library includes non-natural sequences that are not found in genes. Here, we developed a web-based tool to support RNAi screening. The system performs short hairpin RNA (shRNA) target prediction that is informed by comprehensive enquiry (SPICE). SPICE automates several tasks that are laborious but indispensable to evaluate the shRNAs obtained by RNAi screening. SPICE has four main functions: (i) sequence identification of shRNA in the input sequence (the sequence might be obtained by sequencing clones in the RNAi library), (ii) searching the target genes in the database, (iii) demonstrating biological information obtained from the database, and (iv) preparation of search result files that can be utilized in a local personal computer (PC). Using this system, we demonstrated that genes targeted by random oligonucleotide-derived shRNAs were not different from those targeted by organism-specific shRNA. The system facilitates RNAi screening, which requires sequence analysis after screening. The SPICE web application is available at http://www.spice.sugysun.org/.     

Application of RNAi technology to the inhibition of zebrafish GtHalpha, FSHbeta, and LHbeta expression and to functional analyses

Zebrafish (Danio rerio) were used as a model fish, and the technique of RNA interference (RNAi) was employed to knockdown three subunits of the gonadotropin alpha (GtHalpha, common alpha), follicle-stimulating hormone beta (FSHbeta), and luteinizing hormone beta (LHbeta) genes. Three short-hairpin RNA (shRNA) expression vectors and three mismatched shRNA expression vectors as controls for each subunit gene were constructed, and the depression efficiency was tested in vivo by microinjection; the RNA or protein expression levels of the GtH genes were monitored by RT-PCR, Southern blotting, and green fluorescent protein (GFP) analyses. Expression of GtH mRNA was obviously and more efficiently depressed by GtHalpha RNAi expression compared with the other two subunits. A GtHalpha morpholino analysis showed that the GtHalpha morpholino led to suppression of embryonic development and the production of embryonic mutants as a result of an injection of GtHalpha -shRNA. Taken together, these results show that GtHalpha-shRNA, which more efficiently targets RNAi, may have an essential role in the further development of sterility technology of transgenic fish for biosafety purposes.     

DNA vector-based RNA interference to study gene function in cancer

RNA interference (RNAi) inhibits gene expression by specifically degrading target mRNAs. Since the discovery of double-stranded small interference RNA (siRNA) in gene silencing, RNAi has become a powerful research tool in gene function studies. Compared to genetic deletion, RNAi-mediated gene silencing possesses many advantages, such as the ease with which it is carried out and its suitability to most cell lines. Multiple studies have demonstrated the applications of RNAi technology in cancer research. In particular, the development of the DNA vector-based technology to produce small hairpin RNA (shRNA) driven by the U6 or H1 promoter has made long term and inducible gene silencing possible. Its use in combination with genetically engineered viral vectors, such as lentivirus, facilitates high efficiencies of shRNA delivery and/or integration into genomic DNA for stable shRNA expression. We describe a detailed procedure using the DNA vector-based RNAi technology to determine gene function, including construction of lentiviral vectors expressing shRNA, lentivirus production and cell infection, and functional studies using a mouse xenograft model. Various strategies have been reported in generating shRNA constructs. The protocol described here employing PCR amplification and a 3-fragment ligation can be used to directly and efficiently generate shRNA-containing lentiviral constructs without leaving any extra nucleotide adjacent to a shRNA coding sequence. Since the shRNA-expression cassettes created by this strategy can be cut out by restriction enzymes, they can be easily moved to other vectors with different fluorescent or antibiotic markers. Most commercial transfection reagents can be used in lentivirus production. However, in this report, we provide an economic method using calcium phosphate precipitation that can achieve over 90% transfection efficiency in 293T cells. Compared to constitutive shRNA expression vectors, an inducible shRNA system is particularly suitable to knocking down a gene essential to cell proliferation. We demonstrate the gene silencing of Yin Yang 1 (YY1), a potential oncogene in breast cancer, by a Tet-On inducible shRNA system and its effects on tumor formation. Research using lentivirus requires review and approval of a biosafety protocol by the Biosafety Committee of a researcher's institution. Research using animal models requires review and approval of an animal protocol by the Animal Care and Use Committee (ACUC) of a researcher's institution.     

Dicer-independent processing of short hairpin RNAs

Short hairpin RNAs (shRNAs) are widely used to induce RNA interference (RNAi). We tested a variety of shRNAs that differed in stem length and terminal loop size and revealed strikingly different RNAi activities and shRNA-processing patterns. Interestingly, we identified a specific shRNA design that uses an alternative Dicer-independent processing pathway. Detailed analyses indicated that a short shRNA stem length is critical for avoiding Dicer processing and activation of the alternative processing route, in which the shRNA is incorporated into RISC and processed by the AGO2-mediated slicer activity. Such alternatively processed shRNAs (AgoshRNAs) yield only a single RNA strand that effectively induces RNAi, whereas conventional shRNA processing results in an siRNA duplex of which both strands can trigger RNAi. Both the processing and subsequent RNAi activity of these AgoshRNAs are thus mediated by the RISC-component AGO2. These results have important implications for the future design of more specific RNAi therapeutics.     

RNAi in mice: a promising approach to decipher gene functions in vivo

RNA interference (RNAi) is a simple and powerful tool widely used to study gene functions in many species. Vector-based systems using RNA polymerase III promoters have been developed to achieve stable expression of small interfering RNA (siRNA) or small hairpin RNA (shRNA) in mammalian cells. Recent investigations demonstrated that when, combined with the Cre-loxP system, the vector-based RNAi can be used to achieve conditional or tissue specific knockdown of endogenous genes with high efficiency in mice. Here, we review these recent progresses and discuss the advantages, limitations and future development of this emerging technology.     

Comparison of bovine RNA polymerase III promoters for short hairpin RNA expression

RNA interference (RNAi) mediated by DNA-based expression of short hairpin RNA (shRNA) is a powerful method of sequence-specific gene knockdown. A number of vectors for expression of shRNA have been developed that feature promoters from RNA polymerase III (pol III)-transcribed genes of mouse or human origin. To advance the use of RNAi as a tool for functional genomic research and for future development of specific therapeutics in the bovine species, we have developed shRNA expression vectors that feature novel bovine RNA pol III promoters. We characterized two bovine U6 small nuclear RNA (snRNA) promoters (bU6-2 and bU6-3) and a bovine 7SK snRNA promoter (b7SK). We compared the efficiency of each of these promoters to express shRNA molecules. Promoter activity was measured in the context of RNAi by targeting and suppressing the reporter gene encoding enhanced green fluorescent protein. Results show that the b7SK promoter induced the greatest level of suppression in a range of cell lines. The comparison of these bovine promoters in shRNA expression is an important component for the future development of bovine-specific RNAi-based research.     

Photosensitizing carrier proteins for photoinducible RNA interference

RNA interference (RNAi) is being widely explored as a tool in functional genomics and tissue engineering, and in the therapy of intractable diseases, including cancer and neurodegenerative diseases. Recently, we developed a photoinducible RNAi method using photosensitizing carrier proteins, named CLIP-RNAi (CPP-linked RBP-mediated RNA internalization and photoinduced RNAi). Novel carrier proteins were designed for this study to establish a highly efficient delivery system for small interfering RNA (siRNA) or short hairpin RNA (shRNA) and to demonstrate light-dependent gene silencing. In addition, the results suggested that the dissociation of the siRNA (or shRNA) from carrier proteins in the cytoplasm is a critical event in CLIP-RNAi-mediated gene silencing.     

A primer on using pooled shRNA libraries for functional genomic screens

The discovery of RNA interference (RNAi) has revolutionized genetic analysis in mammalian cells. Loss-of-function RNAi screens enable rapid, functional annotation of the genome. Of the various RNAi approaches, pooled shRNA libraries have received considerable attention because of their versatility. A number of genome-wide shRNA libraries have been constructed against the human and mouse genomes, and these libraries can be readily applied to a variety of screens to interrogate the function of human and mouse genes in an unbiased fashion. We provide an introduction to the technical aspects of using pooled shRNA libraries for genetic screens.     

Silencing of mammalian genes by tetracycline-inducible shRNA expression

Conditional gene silencing in mammalian cells, via the controlled expression of short hairpin RNAs (shRNAs), is an effective method for studying gene function, particularly if the gene is essential for cell survival or development. Here we describe a simple and rapid protocol for the generation of tetracycline (Tet)-inducible vectors that express shRNAs in a time- and dosage-dependent manner. Tet-operator (TetO) sequences responsive to occupation by the Tet-repressor (TetR) were inserted at alternative positions within the wild-type H1 promoter and cloned into a eukaryotic expression vector. Additional cloning sites downstream of the promoter enable the insertion of shRNA sequences. This Tet-inducible shRNA expression system can be used for both transient and stable RNA interference (RNAi) approaches to control gene function in a spatiotemporal fashion. The entire protocol (preparation of constructs, generation of stable cell lines and functional analysis) can be completed in 3 months.     

Transiently expressed short hairpin RNA targeting 126 kDa protein of tobacco mosaic virus interferes with virus infection

RNA-interference (RNAi) silences gene expression by'guiding mRNA degradation in asequence-specific fashion.Small interfering RNA (siRNA),an intermediate of the RNAi pathway,has beenshown to be very effective in inhibiting virus infection in mammalian cells and cultured plant cells.Here,wereport that Agrobacterium tumefaciens-mediated transient expression of short hairpin RNA (shRNA) couldinhibit tobacco mosaic virus (TMV) RNA accumulation by targeting the gene encoding the replication-asso-ciated 126 kDa protein in intact plant tissue.Our results indicate that transiently expressed shRNA efficientlyinterfered with TMV infection.The interference observed is sequence-specific,and time-and site-dependent.Transiently expressed shRNA corresponding to the TMV 126 kDa protein gene did not inhibit cucumbermosaic virus (CMV),an unrelated tobamovirus.In order to interfere with TMV accumulation in tobaccoleaves,it is essential for the shRNA constructs to be infiltrated into the same leaves as TMV inoculation.Ourresults support the view that RNAi opens the door for novel therapeutic procedures against virus diseases.We propose that a combination of the RNAi technique and Agrobacterium-mediated transient expressioncould be employed as a potent antiviral treatment in plants.