Vector systems of RNA interference

RNA interference is a mechanism of posttranslational (at the level of mRNA) gene silencing. Sequence-specific mRNA degradation is realized with the help of small interfering RNAs produced by processing of a precursor using Dicer, an enzyme from the RNAse III family. This mechanism is now widely used in vitro on cultures of mammalian cells in order to elucidate functions of individual genes by gene specific knockdown. Analogs of small interference RNAs are intensely expressed during embryogenesis. The mechanism of RNA interference plays an especially important role in embryogenesis of invertebrates. Identification of the functions of small noncoding RNAs is essential for understanding the genetic mechanisms underlying individual developmental stages. In order to integrate small interference RNAs in mammalian cells, various systems have been developed that allow both transient (for 48 h) and stable expression in vitro. These systems are considered in the present review.     

Interfering with disease: opportunities and roadblocks to harnessing RNA interference

RNA interference (RNAi) is an evolutionarily conserved mechanism for silencing gene expression by targeted degradation of mRNA. Short double-stranded RNAs, known as small interfering RNAs (siRNA), are incorporated into an RNA-induced silencing complex that directs degradation of RNA containing a homologous sequence. RNAi has been shown to work in mammalian cells, and can inhibit viral infection and control tumor cell growth in vitro. Recently, it has been shown that intravenous injection of siRNA or of plasmids expressing sequences processed to siRNA can protect mice from autoimmune and viral hepatitis. RNAi could provide an exciting new therapeutic modality for treating infection, cancer, neurodegenerative disease and other illnesses.     

Analysis of gene function in somatic mammalian cells using small interfering RNAs

RNA interference (RNAi) is a highly conserved gene silencing mechanism that uses double-stranded RNA (dsRNA) as a signal to trigger the degradation of homologous mRNA. The mediators of sequence-specific mRNA degradation are 21- to 23-nt small interfering RNAs (siRNAs) generated by ribonuclease III cleavage from longer dsRNAs. Twenty-one-nucleotide siRNA duplexes trigger specific gene silencing in mammalian somatic cells without activation of the unspecific interferon response. Here we provide a collection of protocols for siRNA-mediated knockdown of mammalian gene expression. Because of the robustness of the siRNA knockdown technology, genomewide analysis of human gene function in cultured cells has now become possible.     

A virus-encoded inhibitor that blocks RNA interference in mammalian cells

Nodamura virus (NoV) is a small RNA virus that is infectious for insect and mammalian hosts. We have developed a highly sensitive assay of RNA interference (RNAi) in mammalian cells that shows that the NoV B2 protein functions as an inhibitor of RNAi triggered by either short hairpin RNAs or small interfering RNAs. In the cell, NoV B2 binds to pre-Dicer substrate RNA and RNA-induced silencing complex (RISC)-processed RNAs and inhibits the Dicer cleavage reaction and, potentially, one or more post-Dicer activities. In vitro, NoV B2 inhibits Dicer-mediated RNA cleavage in the absence of any other host factors and specifically binds double-stranded RNAs corresponding in structure to Dicer substrates and products. Its abilities to bind to Dicer precursor and post-Dicer RISC-processed RNAs suggest a mechanism of inhibition that is unique among known viral inhibitors of RNAi.     

两种高效 RNA 干涉载体系统的构建及应用

在真核细胞基因功能研究中, RNA 干涉 (RNAi) 已成为一种强有力的选择性沉默基因表达的实验工具. 建立一套可在哺乳动物培养细胞中高效、经济地表达 siRNA 的载体系统是 RNA 干涉研究的必要前提之一. 从 HepG2 细胞基因组 DNA 中克隆得到 H1 全长启动子 (374 bp),以之为基础构建了两套 RNA 干涉载体系统, pSL 和带有绿色荧光蛋白 (EGFP) 标签的 pESL ,并对 p53 基因进行了相应的 RNA 干涉研究. 干涉质粒瞬时转染 HepG2 细胞后,分别利用半定量 RT-PCR 和蛋白质印迹检测 p53 表达水平. 与商品化载体 pSilencer^TM 3.1-H1 hygro 相比, pSL 和 pESL 对 p53 基因表达具有更高的干涉效率. 结果显示：干涉载体 pSL 和 pESL 能高效特异地下调目的基因表达,可作为哺乳动物中基因功能分析的有效工具.     

RNA interference in mammalian cells using siRNAs synthesized with T7 RNA polymerase

Methods that allow the specific silencing of a desired gene are invaluable tools for research. One of these is based on RNA interference (RNAi), a process by which double-stranded RNA (dsRNA) specifically suppresses the expression of a target mRNA. Recently, it has been reported that RNAi also works in mammalian cells if small interfering RNAs (siRNAs) are used to avoid activation of the interferon system by long dsRNA. Thus, RNAi could become a major tool for reverse genetics in mammalian systems. However, the high cost and the limited availability of the short synthetic RNAs and the lack of certainty that a designed siRNA will work present major drawbacks of the siRNA technology. Here we present an alternative method to obtain cheap and large amounts of siRNAs using T7 RNA polymerase. With multiple transfection procedures, including calcium phosphate co-precipitation, we demonstrate silencing of both exogenous and endogenous genes.     

Determination of the Role of DDX3 a Factor Involved in Mammalian RNAi Pathway Using an shRNA-Expression Library

RNA interference (RNAi) is an endogenous RNA-destruction phenomenon induced by certain double-stranded RNAs (dsRNAs). In RNAi, dsRNAs are processed into small interfering RNAs (siRNAs) which in turn trigger the cleavage of the target mRNA. Here, using a short hairpin RNA-expression library, we identified a DEAD-box helicase 3, DDX3, as an essential factor involved in RNAi pathway and revealed that DDX3 is colocalized with Ago2, an essential factor in RNAi pathway that cleaves target mRNA. Results of experiments with a dominant negative mutant of DDX3 further confirmed that this factor affects the RNAi activity. Together, DDX3 functions to assure mammalian RNAi pathway. Together, our results indicate that DDX3 is a new key molecule to understand the molecular mechanism underlying RNAi pathway in mammals.     

Mammalian RNAi for the masses

Just a couple of years ago, only biologists working with plants or Caenorhabditis elegans could use RNA-mediated interference (RNAi) technology to gain insight into gene function. However, the recent groundbreaking discovery that in vitro synthesized, 21- to 23-nucleotide, double-stranded RNAs can act as small interfering RNAs (siRNAs) to elicit gene-specific inhibition in mammalian cells has made RNAi possible in mammalian systems too. Reported only a year ago, mammalian RNAi is already changing our way of studying gene function in higher eukaryotes. And, a recent exciting advance allows delivery of siRNAs into mammalian cells by a DNA vector. In addition to providing a low-cost alternative to the chemically synthesized siRNAs, this DNA-vector-based strategy is capable of mediating stable target gene inhibition, thus allowing gene function analysis over an extended period of time.     

Knockdown stands up

In the past year, the genetic research of mammalian cells in vitro has gained the advantages of RNA interference (RNAi), a process found in worms and plants by which double stranded RNAs mediate selective gene inactivation through mRNA destruction. Recently, two papers have shown that genes could be suppressed in vivo in mammals by RNAi, which has potential implications for both therapeutics and research.     

Deep sequencing of virus-infected cells reveals HIV-encoded small RNAs

Small virus-derived interfering RNAs (viRNAs) play an important role in antiviral defence in plants, insects and nematodes by triggering the RNA interference (RNAi) pathway. The role of RNAi as an antiviral defence mechanism in mammalian cells has been obscure due to the lack of viRNA detection. Although viRNAs from different mammalian viruses have recently been identified, their functions and possible impact on viral replication remain unknown. To identify viRNAs derived from HIV-1, we used the extremely sensitive SOLiD(TM) 3 Plus System to analyse viRNA accumulation in HIV-1-infected T lymphocytes. We detected numerous small RNAs that correspond to the HIV-1 RNA genome. The majority of these sequences have a positive polarity (98.1%) and could be derived from miRNAs encoded by structured segments of the HIV-1 RNA genome (vmiRNAs). A small portion of the viRNAs is of negative polarity and most of them are encoded within the 3'-UTR, which may represent viral siRNAs (vsiRNAs). The identified vsiRNAs can potently repress HIV-1 production, whereas suppression of the vsiRNAs by antagomirs stimulate virus production. These results suggest that HIV-1 triggers the production of vsiRNAs and vmiRNAs to modulate cellular and/or viral gene expression.     

Small interfering RNA-mediated gene silencing in T lymphocytes

Introduction of small interfering RNAs (siRNAs) into a cell can cause a specific interference of gene expression known as RNA interference (RNAi). However, RNAi activity in lymphocytes and in normal primary mammalian cells has not been thoroughly demonstrated. In this report, we show that siRNAs complementary to CD4 and CD8alpha specifically reduce surface expression of these coreceptors and their respective mRNA in a thymoma cell line model. We show that RNAi activity is only caused by a subset of siRNAs complementary to the mRNA target and that ineffective siRNAs can compete with effective siRNAs. Using primary differentiated T lymphocytes, we provide the first evidence of siRNA-mediated RNAi gene silencing in normal nontransformed somatic mammalian lymphocytes.     

Inhibitory effect of naked neural BC1 RNA or BC200 RNA on eukaryotic in vitro translation systems is reversed by poly(A)-binding protein (PABP)

Regulated protein biosynthesis in dendrites of neurons might be a key mechanism underlying learning and memory. Neuronal dendritic BC1 RNA and BC200 RNA and similar small untranslated RNAs inhibit protein translation in vitro systems, such as rabbit reticulocyte lysate. Likewise, co-transfection of these RNAs with reporter mRNA suppressed translation levels in HeLa cells. The oligo(A)-rich region of all active small RNAs were identified as the RNA domains chiefly responsible for the inhibitory effects. Addition of recombinant human poly(A)-binding protein (PABP) significantly compensated the inhibitory effect of the small oligo(A)-rich RNA. In vivo, all BC1 RNA appears to be complexed with PABP. Nevertheless, in the micro-environment of dendritic spines of neuronal cells, BC1 RNPs or BC200 RNPs might mediate regulatory functions by differential interactions with locally limited PABP and/or directly or indirectly, with other translation initiation factors.     

Small RNAs with imperfect match to endogenous mRNA repress translation. Implications for off-target activity of small inhibitory RNA in mammalian cells

A 21-base pair RNA duplex that perfectly matches an endogenous target mRNA selectively degrades the mRNA and suppresses gene expression in mammalian tissue culture cells. A single base mismatch with the target is believed to protect the mRNA from degradation, making this type of interference highly specific to the targeted gene. A short RNA with mismatches to a target sequence present in multiple copies in the 3'-untranslated region of an exogenously expressed gene can, however, silence it by translational repression. Here we report that a mismatched RNA, targeted to a single site in the coding sequence of an endogenous gene, can efficiently silence gene expression by repressing translation. The antisense strand of such a mismatched RNA requires a 5'-phosphate but not a 3'-hydroxyl group. G.U wobble base pairing is tolerated as a match for both RNA degradation and translation repression. Together, these findings suggest that a small inhibitory RNA duplex can suppress expression of off-target cellular proteins by RNA degradation or translation repression. Proper design of experimental small inhibitory RNAs or a search for targets of endogenous micro-RNAs must therefore take into account that these short RNAs can affect expression of cellular genes with as many as 3-4 base mismatches and additional G.U mismatches.     

The silent treatment: RNAi as a defense against virus infection in mammals

RNA interference (RNAi) is a mechanism for sequence-specific gene silencing guided by double-stranded RNA. In plants and insects it is well established that RNAi is instrumental in the response to viral infections; whether RNAi has a similar function in mammals is under intense investigation. Recent studies to address this question have identified some unanticipated interactions between the RNAi machinery and mammalian viruses. Furthermore, introduction of virus-specific small interfering RNAs (siRNAs) into cells, thus programming the RNAi machinery to target viruses, is an effective therapeutic approach to inhibit virus replication in vitro and in animal models. Although several issues remain to be addressed, such as delivery and viral escape, these findings hold tremendous potential for the development of RNAi-based antiviral therapeutics.