MISSION esiRNA for RNAi Screening in Mammalian Cells

RNA interference (RNAi) is a basic cellular mechanism for the control of gene expression. RNAi is induced by short double-stranded RNAs also known as small interfering RNAs (siRNAs). The short double-stranded RNAs originate from longer double stranded precursors by the activity of Dicer, a protein of the RNase III family of endonucleases. The resulting fragments are components of the RNA-induced silencing complex (RISC), directing it to the cognate target mRNA. RISC cleaves the target mRNA thereby reducing the expression of the encoded protein^1,2,3. RNAi has become a powerful and widely used experimental method for loss of gene function studies in mammalian cells utilizing small interfering RNAs.Currently two main methods are available for the production of small interfering RNAs. One method involves chemical synthesis, whereas an alternative method employs endonucleolytic cleavage of target specific long double-stranded RNAs by RNase III in vitro. Thereby, a diverse pool of siRNA-like oligonucleotides is produced which is also known as endoribonuclease-prepared siRNA or esiRNA. A comparison of efficacy of chemically derived siRNAs and esiRNAs shows that both triggers are potent in target-gene silencing. Differences can, however, be seen when comparing specificity. Many single chemically synthesized siRNAs produce prominent off-target effects, whereas the complex mixture inherent in esiRNAs leads to a more specific knockdown¹⁰.In this study, we present the design of genome-scale MISSION esiRNA libraries and its utilization for RNAi screening exemplified by a DNA-content screen for the identification of genes involved in cell cycle progression. We show how to optimize the transfection protocol and the assay for screening in high throughput. We also demonstrate how large data-sets can be evaluated statistically and present methods to validate primary hits. Finally, we give potential starting points for further functional characterizations of validated hits.Download video file.^{(167M, mp4)}     

Alternative approaches for efficient inhibition of hepatitis C virus RNA replication by small interfering RNAs

Persistent infection with hepatitis C virus (HCV) is a leading cause of chronic hepatitis, liver cirrhosis, and hepatocellular carcinoma. It has recently been shown that HCV RNA replication is susceptible to small interfering RNAs (siRNAs), but the antiviral activity of siRNAs depends very much on their complementarity to the target sequence. Thus, the high degree of sequence diversity between different HCV genotypes and the rapid evolution of new quasispecies is a major problem in the development of siRNA-based gene therapies. For this study, we developed two alternative strategies to overcome these obstacles. In one approach, we used endoribonuclease-prepared siRNAs (esiRNAs) to simultaneously target multiple sites of the viral genome. We show that esiRNAs directed against various regions of the HCV coding sequence as well as the 5' nontranslated region (5' NTR) efficiently block the replication of subgenomic and genomic HCV replicons. In an alternative approach, we generated pseudotyped retroviruses encoding short hairpin RNAs (shRNAs). A total of 12 shRNAs, most of them targeting highly conserved sequence motifs within the 5' NTR or the early core coding region, were analyzed for their antiviral activities. After the transduction of Huh-7 cells containing a subgenomic HCV replicon, we found that all shRNAs targeting sequences in domain IV or nearby coding sequences blocked viral replication. In contrast, only one of seven shRNAs targeting sequences in domain II or III had a similar degree of antiviral activity, indicating that large sections of the NTRs are resistant to RNA interference. Moreover, we show that naive Huh-7 cells that stably expressed certain 5' NTR-specific shRNAs were largely resistant to a challenge with HCV replicons. These results demonstrate that the retroviral transduction of HCV-specific shRNAs provides a new possibility for antiviral intervention.     

Enhanced gene silencing by the application of multiple specific small interfering RNAs

Small interfering RNA duplexes (siRNA) induce gene silencing in various eukaryotic cells, although usually in an incomplete manner. Using chemically synthesized siRNAs targeting the HIV-1 co-receptor CXCR4 or the apoptosis-inducing Fas-ligand (FasL), co-transfection of cells with two or more siRNA duplexes targeting different sites on the same mRNA resulted in an enhanced gene silencing compared with each single siRNA. This was shown in the down-regulation of protein and mRNA expression, and functionally in the inhibition of CXCR4-mediated HIV infection and of FasL-mediated cell apoptosis. Transfection efficiency determined for the FasL-specific siRNAs was dose-dependent and varied among the siRNAs tested, but was not the main reason for the enhanced gene silencing.     

Molecular mechanisms that funnel RNA precursors into endogenous small-interfering RNA and microRNA biogenesis pathways in Drosophila

In Drosophila, three types of endogenous small RNAs—microRNAs (miRNAs), PIWI-interacting RNAs (piRNAs), and endogenous small-interfering RNAs (endo-siRNAs or esiRNAs)—function as triggers in RNA silencing. Although piRNAs are produced independently of Dicer, miRNA and esiRNA biogenesis pathways require Dicer1 and Dicer2, respectively. Recent studies have shown that among the four isoforms of Loquacious (Loqs), Loqs-PB and Loqs-PD are involved in miRNA and esiRNA processing pathways, respectively. However, how these Loqs isoforms function in their respective small RNA biogenesis pathways remains elusive. Here, we show that Loqs-PD associates specifically with Dicer2 through its C-terminal domain. The Dicer2–Loqs-PD complex contains R2D2, another known Dicer2 partner, and excises both exogenous siRNAs and esiRNAs from their corresponding precursors in vitro. However, Loqs-PD, but not R2D2, enhanced Dicer2 activity. The Dicer2–Loqs-PD complex processes esiRNA precursor hairpins with long stems, which results in the production of AGO2-associated small RNAs. Interestingly, however, small RNAs derived from terminal hairpins of esiRNA precursors are loaded onto AGO1; thus, they are classified as a new subset of miRNAs. These results suggest that the precursor RNA structure determines the biogenesis mechanism of esiRNAs and miRNAs, thereby implicating hairpin structures with long stems as intermediates in the evolution of Drosophila miRNA.     

用Rnase Ⅲ制备的小干涉RNA降解SARS冠状病毒基因的细胞内转录物

SARS冠状病毒是引起重症急性呼吸综合症的主要原因,目前尚没有特效药物或疫苗对抗这种新病毒。RNA干涉是指双链RNA可以特异地降解细胞内同源基因的Mrna。在哺乳动物细胞中,<30bp的小双链RNA能引起RNA干涉,又可以避免干扰素反应。通过体外转录得到SARS病毒3种基因RNA依赖的RNA聚合酶、刺突蛋白及核衣壳蛋白部分片段的长双链RNA,然后用Rnase Ⅲ有限切割成长度<30bp的小干涉RNA。同时把上述3种基因片段分别连接到质粒Pgl3-Control中,得到的3个质粒Pgl-R、Pgl-S和Pgl-N可以分别在细胞内转录出荧光素酶RNA依赖的RNA聚合酶、刺突蛋白、核衣壳蛋白的杂合Mrna。上述质粒分别和相应的小干涉RNA共转染HEK293F细胞,测定荧光素酶活性,结果小干涉RNA使相应质粒表达荧光素酶的活性显著下降;用逆转录定量PCR反应测量Mrna丰度,结果表明上述小干涉RNA可以特异地降解相应的病毒基因转录物。     

Design of bifunctional siRNAs: combining immunostimulation and gene-silencing in one single siRNA molecule

Active suppression of T lymphocyte activation can limit the efficacy of immune surveillance and immunotherapy. Here we have explored the possibility of designing bifunctional small interfering RNAs (siRNAs) capable of inducing innate immunity through Toll-like receptors and simultaneously inhibiting the expression of immunosuppressive factors. Using interleukin (IL) 10 as a model, we found that liposomal delivery of IL10 siRNAs could efficiently activate the expression of cytokines (e.g. TNF-alpha, IL6, and IL12) and interferons (e.g. IFN-alpha) in peripheral blood mononuclear cells (PBMCs) and immature monocyte-derived dendritic cells (iMoDCs). Moreover, the designed siRNAs inhibited IL10 gene expression. Transfection of iMoDCs with either chemically or in vitro transcribed IL10 siRNAs induced their differentiation into mature MoDCs (mMoDCs) characterized by the expression of costimulatory molecules CD80/CD86 and the chemokine receptor CCR7. Lipid delivery of either chemically synthesized or T7-transcribed immunostimulatory siRNAs induced cytokine production. However, in contrast to chemically synthesized siRNAs, electroporation of in vitro transcribed siRNAs also induced cytokine production in iMoDCs. Interestingly, IL10 siRNA-transfected iMoDCs were capable for enhancing the response of allogeneic T cells, providing support for the rational design of bifunctional siRNAs as immune modulating therapy.     

In vivo screening of modified siRNAs for non-specific antiviral effect in a small fish model: number and localization in the strands are important

Small interfering RNAs (siRNAs) are promising new active compounds in gene medicine but the induction of non-specific immune responses following their delivery continues to be a serious problem. With the purpose of avoiding such effects chemically modified siRNAs are tested in screening assay but often only examining the expression of specific immunologically relevant genes in selected cell populations typically blood cells from treated animals or humans. Assays using a relevant physiological state in biological models as read-out are not common. Here we use a fish model where the innate antiviral effect of siRNAs is functionally monitored as reduced mortality in challenge studies involving an interferon sensitive virus. Modifications with locked nucleic acid (LNA), altritol nucleic acid (ANA) and hexitol nucleic acid (HNA) reduced the antiviral protection in this model indicative of altered immunogenicity. For LNA modified siRNAs, the number and localization of modifications in the single strands was found to be important and a correlation between antiviral protection and the thermal stability of siRNAs was found. The previously published sisiRNA will in some sequences, but not all, increase the antiviral effect of siRNAs. The applied fish model represents a potent tool for conducting fast but statistically and scientifically relevant evaluations of chemically optimized siRNAs with respect to non-specific antiviral effects in vivo.     

Purification of recombinant ribonuclease T1 expressed in Escherichia coli

A protocol for the rapid purification of ribonuclease T1 expressed from a chemically synthesized gene cloned into Escherichia coli is described. QAE ion-exchange and Sephadex G-50 chromatography are used to give over 300 mg (88% yield) of pure ribonuclease T1 from 61 of liquid culture in 3 days. We also report a new absorption coefficient for RNase T1: E1%278 nm = 15.4.     

RNA interference: implications for cancer treatment

RNA interference (RNAi) has emerged as one of the most important discoveries of the last years in the field of molecular biology. Following clarification of this highly conserved endogenous gene silencing mechanism, RNAi has largely been exploited as a powerful tool to uncover the function of specific genes and to understand the effects of selective gene silencing in mammalian cells both in vitro and in vivo. RNAi can be induced by direct introduction of chemically synthesized siRNAs into the cell or by the use of plasmid and viral vectors encoding for siRNA allowing a more stable RNA knockdown. Potential application of this technique both as a research tool and for therapeutic purposes has led to an extensive effort to overcome some critical constraints which may limit its successful application in vivo, including off-target and non-specific effects, as well as the relatively poor stability of siRNA. This review provides a brief overview of the RNAi mechanism and of its application in preclinical animal models of cancer.     

Solid-phase synthesis,characterization and RNAi activity of branch and hyperbranch siRNAs

Linear, branch and hyperbranch siRNAs were effectively prepared for down-regulating GRP78 expression and inducing cell death in HepG2 liver cancer cells. Branch and hyperbranch GRP78 siRNAs were synthesized by automated solid-phase synthesis in good yields (44–78%) and isolated in excellent purities (>99%) following HPLC purification. Moreover, siRNAs adopted stable intramolecular hybrids as discerned by native PAGE and thermal denaturation studies. These sequences also exhibited the pre-requisite A-type helical trajectory for triggering RNAi activity as determined by CD spectroscopy. Biological studies confirmed potent suppression of GRP78 expression (50–60%) while compromising cancer cell viability by ～20%. Thus, branch and hyperbranch siRNAs may serve as potent siRNA candidates in cancer gene therapy applications.     

Automated solid-phase synthesis of high capacity oligo-dT cellulose for affinity purification of poly-A tagged biomolecules

Affinity purification of poly-adenylated biomolecules using solid supports that are derivatized with poly-thymidine oligonucleotides provides a powerful method for isolating cellular mRNA. These systems have also been used to purify mRNA–peptide fusions generated by RNA-display. However, the commercial source for high capacity oligo-dT cellulose was recently discontinued. To overcome this problem, we have developed a low cost solid-phase synthesis protocol to generate oligo-dT cellulose. Comparative binding studies indicate that chemically synthesized oligo-dT cellulose functions with superior loading capacity when compared to the discontinued product. We suggest that this method could be used to synthesize oligo-dT resin for routine purification of poly-adenylated biomolecules.     

抗HIV融合多肽CP32M的制备工艺研究

目的:研究抗HIV融合多肽CP32M的制备工艺,为其临床前试验奠定基础。方法:采用固-液相混合策略规模合成目标肽,用离子交换色谱、反相高效液相色谱对粗肽进行纯化。结果:获得了利于提高合成及片段缩合效率的3条优选片段,CP32M粗品经DEAE离子交换色谱及C18反相纯化后纯度高于98%。结论:CP32M按3条片段(Ac-1-9-OH、Fmoc-10-21-OH、H-22-32-NH2)划分,可显著提高片段合成及缩合效率,DEAE阴离子交换色谱能除去大部分杂质,提高了第二步C18反相色谱纯化效率。