Schistosoma mansoni U6 gene promoter-driven short hairpin RNA induces RNA interference in human fibrosarcoma cells and schistosomules

RNA interference (RNAi) mediated by short hairpin-RNA (shRNA) expressing plasmids can induce specific and long-term knockdown of specific mRNAs in eukaryotic cells. To develop a vector-based RNAi model for Schistosoma mansoni, the schistosome U6 gene promoter was employed to drive expression of shRNA targeting reporter firefly luciferase. An upstream region of a U6 gene predicted to contain the promoter was amplified from genomic DNA of S. mansoni. A shRNA construct driven by the predicted U6 promoter targeting luciferase was assembled and cloned into plasmid pXL-Bac II, the construct termed pXL-BacII_SmU6-shLuc. Luciferase expression in transgenic fibrosarcoma HT-1080 cells was significantly reduced 96 h following transduction with plasmid pXL-BacII_SmU6-shLuc, which encodes luciferase mRNA-specific shRNA. In a similar fashion, schistosomules of S. mansoni were transformed with the SmU6-shLuc or control constructs. Firefly luciferase mRNA was introduced into transformed schistosomules after which luciferase activity was analyzed. Significantly less activity was present in schistosomules transfected with pXL-BacII_SmU6-shLuc compared with controls. The findings revealed that the putative S. mansoni U6 gene promoter of 270 bp in length was active in human cells and schistosomes. Given that the U6 gene promoter drove expression of shRNA from an episome, the findings also indicate the potential of this putative RNA polymerase III dependent promoter as a component regulatory element in vector-based RNAi for functional genomics of schistosomes.     

Characterisation and comparison of the chicken H1 RNA polymerase III promoter for short hairpin RNA expression

The U6 and 7SK RNA polymerase III promoters are widely used in RNAi research for the expression of shRNAs. However, with their increasing use in vitro and in vivo, issues associated with cytotoxicity have become apparent with their use. Therefore, alternative promoters such as the weaker H1 promoter are becoming a popular choice. With interest in the chicken as a model organism, we aimed to identify and characterise the chicken H1 promoter for the expression of shRNAs for the purpose of RNAi. The chicken H1 promoter was isolated and sequence analysis identified conserved RNA polymerase III promoter elements. A shRNA expression cassette containing the chicken H1 promoter and shRNA targeting enhanced green fluorescent protein (EGFP) was developed. An RNAse protection assay confirmed activity of the promoter determined by the detection of expressed shRNAs. Comparison of the H1 promoter to the chicken RNA polymerase III 7SK and U6 promoters demonstrated that expressed shRNAs from the H1 promoter induced gene specific silencing, albeit to lower levels in comparison to both 7SK and U6 promoters. Here we have identified a new tool for RNAi research with specific applications to the chicken. The availability of a RNA polymerase III promoter that drives shRNA expression to reduced levels will greatly benefit in ovo/in vivo applications where there are concerns of cytotoxicity resulting from overexpression of an shRNA.     

Metalloproteases with EGF, CUB, and thrombospondin-1 domains function in molting of Caenorhabditis elegans

Functional analysis using RNAi was performed on eleven genes for metalloproteases of the M12A family in Caenorhabditis elegans and the interference of the C17G1.6 gene (nas-37) was found to cause incomplete molting. The RNAi of the C26C6.3 gene (nas-36) also caused a similar molting defect but not so severely as that of the nas-37 gene. Both the genes encode an astacin-like metalloprotease with an epidermal growth factor (EGF)-like domain, a CUB domain, and a thrombospondin-1 domain, in this order. The promoter-driven green fluorescent protein (GFP) expression analysis suggested that they are expressed in hypodermal cells throughout the larval stages and in the vulva of adult animals. In the genetic background of rde-1(ne219), where RNAi does not work, the molting defect caused by the nas-37 interference was observed when the transgenic wild-type rde-1 gene was expressed under the control of the dpy-7 promoter, known to be active in the hypodermal cells, but not under the control of the myo-3 promoter, active in the muscular cells. Therefore these proteases are thought to be secreted by the hypodermal cells and to participate in shedding of old cuticles.     

Knockdown of human p53 gene expression in 293-T cells by retroviral vector-mediated short hairpin RNA

RNA interference （RNAi） is an evolutionarily conserved process of gene silencing in multiple organisms, which has become a powerful tool for investigating gene function by reverse genetics. Recently, many groups have reported to use synthesized oligonucleotides or siRNA encoding plasmids to induce RNAi in mammalian cells by transfection, but this is still limited in its application, especially when it is necessary to generate long-term gene silencing in vivo. To circumvent this problem, retrovirus- or lentivirus-delivered RNAi has been developed. Here, we described two retroviral systems for delivering short hairpin RNA （shRNA） transcribed from the H1 promoter. The results showed that retroviral vector-mediated RNAi can substantially downregulate the expression of human p53 in 293-T cells. Furthermore, the retroviral vectormediated RNAi in our transduction system can stably inactivate the p53 gene for a long time. Compared to shRNAs transcribed from the U6 promoter, HI-driven shRNA also dramatically reduced the expression of p53. The p53 downregulation efficiencies of H1- and U6-driven shRNAs were almost identical. The results indicate that retroviral vector-delivered RNAi would be a useful tool in functional genomics and gene therapy.     

应用载体介导的RNAi技术抑制HCMV的UL49基因表达

为了研究RNA干涉抑制HCMV UL49基因的作用,以pLXSN(U6启动子)为模板通过两步PCR的方法扩增含U6启动子的siRNA表达片段,并通过TA克隆将siRNA表达片段克隆到pMD18-T载体构建成siRNA表达质粒,同时以人巨细胞病毒AD169病毒株基因组为模板PCR扩增UL49基因,将其克隆到pEGFP-N1构建融合质粒pEGFP-UL49。通过脂质体介导将siRNA表达质粒和pEGFP-UL49质粒共转染人宫颈癌细胞系HeLa,在荧光显微镜下观察RNA干涉结果。通过这种方法得到具有介导RNA干涉的siRNA片段,为UL49基因沉默研究提供技术基础。     

Control of siRNA expression using the Cre-loxP recombination system

Gene silencing mediated by RNA interference (RNAi) was first discovered in Caenorhabditis elegans, and was subsequently recognized in various other organisms. In mammalian cells, RNAi can be induced by small interfering RNAs (siRNAs). In earlier studies, our group developed a vector-based system for expression of siRNA under control of a polymerase III promoter, the U6 promoter, which can induce RNAi in living cells. We here describe a system for controlling the U6 promoter-driven expression of siRNA using the Cre-loxP recombination system. We constructed a 'Cre-On' siRNA expression vector which could be switched on upon excision catalyzed by Cre recombinase, which was delivered to cells directly from the medium as a fusion protein. An examination of the effectiveness of RNAi against a reporter gene revealed that addition of TAT-NLS-Cre (where NLS is a nuclear localization signal and TAT is a peptide of 11 amino acids derived from HIV) to the medium resulted in plasmid recombination, generation of siRNA and suppression of reporter activity. This system should allow us to induce RNAi in a spatially, temporally, cell type-specifically or tissue-specifically controlled manner and potentiate the improved application of RNAi in both an experimental and a therapeutic context.     

Control of siRNA expression using the Cre–loxP recombination system

Gene silencing mediated by RNA interference (RNAi) was first discovered in Caenorhabditis elegans, and was subsequently recognized in various other organisms. In mammalian cells, RNAi can be induced by small interfering RNAs (siRNAs). In earlier studies, our group developed a vector-based system for expression of siRNA under control of a polymerase III promoter, the U6 promoter, which can induce RNAi in living cells. We here describe a system for controlling the U6 promoter-driven expression of siRNA using the Cre–loxP recombination system. We constructed a ‘Cre-On’ siRNA expression vector which could be switched on upon excision catalyzed by Cre recombinase, which was delivered to cells directly from the medium as a fusion protein. An examination of the effectiveness of RNAi against a reporter gene revealed that addition of TAT-NLS-Cre (where NLS is a nuclear localization signal and TAT is a peptide of 11 amino acids derived from HIV) to the medium resulted in plasmid recombination, generation of siRNA and suppression of reporter activity. This system should allow us to induce RNAi in a spatially, temporally, cell type-specifically or tissue-specifically controlled manner and potentiate the improved application of RNAi in both an experimental and a therapeutic context.     

Gene silencing in Xenopus laevis by DNA vector-based RNA interference and transgenesis

A vector-based RNAi expression system was developed using the Xenopus tropicalis U6 promoter, which transcribes small RNA genes by RNA polymerase Ⅲ. The system was first validated in a Xenopus laevis cell line, designing a short hairpin DNA specific for the GFP gene. Co-transfection of the vector-based RNAi and the GFP gene into Xenopus XR1 cells significantly decreased the number of GFP-expressing cells and overall GFP fluorescence. Vector-based RNAi was subsequently validated in GFP transgenic Xenopus embryos. Sperm nuclei from GFP transgenic males and RNAi construct-incubated-sperm nuclei were used for fertilization, respectively. GFP mRNA and protein were reduced by -60% by RNAi in these transgenic embryos compared with the control. This transgene-driven RNAi is specific and stable in inhibiting GFP expression in the Xenopus laevis transgenic line. Gene silencing by vector-based RNAi and Xenopus transgenesis may provide an alternative for ＇repression of gene function＇ studies in vertebrate model systems.     

Short-hairpin RNA-mediated gene expression interference in Trichoplusia ni cells

RNA interference (RNAi) is rapidly becoming a valuable tool in biological studies, as it allows the selective and transient knockdown of protein expression. The short-interfering RNAs (siRNAs) transiently silence gene expression. By contrast, the expressed short-hairpin RNAs induce long-term, stable knockdown of their target gene. Trichoplusia ni (T. ni) cells are widely used for mammalian cell-derived glycoprotein expression using the baculovirus system. However, a suitable shRNA expression system has not been developed yet. We investigated the potency of shRNA-mediated gene expression inhibition using human and Drosophila U6 promoters in T. ni cells. Luciferase, EGFP, and beta-N-acetylglucosaminidase (GlcNAcase) were employed as targets to investigate knockdown of specific genes in T. ni cells. Introduction of the shRNA expression vector under the control of human U6 or Drosophila U6 promoter into T. ni cells exhibited the reduced level of luciferase, EGFP, and beta-N-acetylglucosaminidase compared with that of untransfected cells. The shRNA was expressed and processed to siRNA in our vector-transfected T. ni cells. GlcNAcase mRNA levels were down-regulated in T. ni cells transfected with shRNA vectors-targeted GlcNAcase as compared with the control vector-treated cells. It implied that our shRNA expression vectors using human and Drosophila U6 promoters were applied in T. ni cells for the specific gene knockdown.     

Silencing of the Pink1 gene expression by conditional RNAi does not induce dopaminergic neuron death in mice

Transgenic RNAi, an alternative to the gene knockout approach, can induce hypomorphic phenotypes that resemble those of the gene knockout in mice. Conditional transgenic RNAi is an attractive choice of method for reverse genetics in vivo because it can achieve temporal and spatial silencing of targeted genes. Pol III promoters such as U6 are widely used to drive the expression of RNAi transgenes in animals. Tested in transgenic mice, a Cre-loxP inducible U6 promoter drove the broad expression of an shRNA against the Pink1 gene whose loss-of-functional mutations cause one form of familial Parkinson's disease. The expression of the shRNA was tightly regulated and, when induced, silenced the Pink1 gene product by more than 95% in mouse brain. However, these mice did not develop dopaminergic neurodegeneration, suggesting that silencing of the Pink1 gene expression from embryo in mice is insufficient to cause similar biochemical or morphological changes that are observed in Parkinson's disease. The results demonstrate that silencing of the PINK1 gene does not induce a reliable mouse model for Parkinson's disease, but that technically the inducible U6 promoter is useful for conditional RNAi in vivo.     

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.