Selective reduction of dormant maternal mRNAs in mouse oocytes by RNA interference

Specific mRNA degradation mediated by double-stranded RNA (dsRNA), which is termed RNA interference (RNAi), is a useful tool with which to study gene function in several systems. We report here that in mouse oocytes, RNAi provides a suitable and robust approach to study the function of dormant maternal mRNAs. Mos (originally known as c-mos) and tissue plasminogen activator (tPA, Plat) mRNAs are dormant maternal mRNAs that are recruited during oocyte maturation; translation of Mos mRNA results in the activation of MAP kinase. dsRNA directed towards Mos or Plat mRNAs in mouse oocytes effectively results in the specific reduction of the targeted mRNA in both a time- and concentration-dependent manner. Moreover, dsRNA is more potent than either sense or antisense RNAs. Targeting the Mos mRNA results in inhibiting the appearance of MAP kinase activity and can result in parthenogenetic activation. Mos dsRNA, therefore, faithfully phenocopies the Mos null mutant. Targeting the Plat mRNA with Plat dsRNA results in inhibiting production of tPA activity. Finally, effective reduction of the Mos and Plat mRNA is observed with stoichiometric amounts of Mos and Plat dsRNA, respectively.     

Transgenic RNAi in mouse oocytes: The first decade

RNA interference (RNAi), a sequence-specific mRNA degradation induced by double-stranded RNA (dsRNA), is a common approach employed to specifically silence genes. Experimental RNAi in plant and invertebrate models is frequently induced by long dsRNA. However, in mammals, short RNA molecules are used preferentially since long dsRNA can provoke sequence-independent type I interferon response. A notable exception are mammalian oocytes where the interferon response is suppressed and long dsRNA is a potent and specific trigger of RNAi. Transgenic RNAi is an adaptation of RNAi allowing for inducing sequence-specific silencing upon expression of dsRNA. A decade ago, we have developed a vector for oocyte-specific expression of dsRNA, which has been used to study gene function in mouse oocytes on numerous occasions. This review provides an overview and discusses benefits and drawbacks encountered by us and our colleagues while working with the oocytes-specific transgenic RNAi system.     

RNA干扰及其在动物繁殖研究中的应用

RNA干扰(RNAi)是指小分子双链RNA通过特异性降解与其同源的mRNA,而在mRNA水平上高效阻断体内特异性基因表达的现象,属于转录后水平基因沉默。利用该技术进行基因功能研究,经济有效,通用性好,已成为反向遗传学研究中最重要的工具之一。在动物繁殖领域,RNAi技术主要应用于体外研究哺乳类和禽类卵母细胞发育、胚胎发育和精子形成中重要基因的功能及其作用机制。随着该技术不断发展完善,RNAi必将在动物繁殖生产实践中发挥巨大的作用。     

RNAi-mediated inhibition of gene function in the follicle cell layer of the Drosophila ovary

RNA-mediated interference (RNAi) has been reported to be an effective reverse genetic approach for studying gene function in various organisms. To assess RNAi as a means of examining genes expressed in ovarian follicle cells for their involvement in embryonic dorsal-ventral patterning, we tested the ability of transgenically expressed double-stranded RNA (dsRNA) directed against the dorsal group gene windbeutel to generate phenotypic effects in the progeny of expressing females. We observed that expression in follicle cells under the control of Gal4 transcribed from the strong and widely expressed alphaTub84B or Actin5C promoters led to efficient dorsalization of progeny embryos. Surprisingly, a variety of strongly expressed follicle cell-specific Gal4 enhancer trap lines failed to elicit an RNAi phenotype in combination with the windbeutel-specific dsRNA. These results stress the importance of careful choice of expression system and of conditions for use in transgenic RNAi-mediated studies of gene function.     

RNA interference as a tool to study gene function in bovine oocytes

RNA interference (RNAi) has become a well-established technique to study gene function in several species. Our objective was to develop a RNAi approach to study gene function in bovine oocytes. In the first experiment, three different treatments including a 20 min exposure to cytochalasin B, a 6 hr maturation in cycloheximide, and a combination of these two treatments were tested to improve oocyte survival following microinjection. The cycloheximide/cytochalasin B treatment greatly increased (P<0.02) the survival rate of the microinjected oocytes. In the second experiment, we assessed the effect of both cyclin B1 and GFP dsRNA on cyclin B1 mRNA and protein expression. The injection of cyclin B1 dsRNA resulted in a decrease in cyclin B1 mRNA and protein, while the cyclin B2 mRNA remained unaffected. Furthermore, the injection of GFP dsRNA did not interfere with cyclin B1 mRNA or protein nor with the ability of the oocyte to mature properly. In addition, the lack of cyclin B1 in the oocyte led to activation in 10% of the oocytes as evidenced by the presence of a pronucleus. However, the use of an additional 10 hr of maturation in the presence of 6-dimethylaminopurine (6-DMAP) prevented germinal vesicle breakdown and allowed a longer exposure to dsRNA. This procedure increased the percentage of activated oocytes to 33% and is likely to result from an increased length of time for dsRNA processing and for degradation of the cyclin B1 mRNA to occur. In conclusion, RNAi represents a useful technique to study gene function in the bovine oocyte.     

Genetic interference in Trypanosoma brucei by heritable and inducible double-stranded RNA

The use of double-stranded RNA (dsRNA) to disrupt gene expression has become a powerful method of achieving RNA interference (RNAi) in a wide variety of organisms. However, in Trypanosoma brucei this tool is restricted to transient interference, because the dsRNA is not stably maintained and its effects are diminished and eventually lost during cellular division. Here, we show that genetic interference by dsRNA can be achieved in a heritable and inducible fashion. To show this, we established stable cell lines expressing dsRNA in the form of stem-loop structures under the control of a tetracycline-inducible promoter. Targeting a-tubulin and actin mRNA resulted in potent and specific mRNA degradation as previously observed in transient interference. Surprisingly, 10-fold down regulation of actin mRNA was not fatal to trypanosomes. This type of approach could be applied to study RNAi in other organisms that are difficult to microinject or electroporate. Furthermore, to quickly probe the consequences of RNAi for a given gene we established a highly efficient in vivo T7 RNA polymerase system for expression of dsRNA. Using the alpha-tubulin test system we obtained greater than 98% transfection efficiency and the RNAi response lasted at least two to three cell generations. These new developments make it possible to initiate the molecular dissection of RNAi both biochemically and genetically.     

A transient transgenic RNAi strategy for rapid characterization of gene function during embryonic development

RNA interference (RNAi) is a powerful strategy for studying the phenotypic consequences of reduced gene expression levels in model systems. To develop a method for the rapid characterization of the developmental consequences of gene dysregulation, we tested the use of RNAi for "transient transgenic" knockdown of mRNA in mouse embryos. These methods included lentiviral infection as well as transposition using the Sleeping Beauty (SB) and PiggyBac (PB) transposable element systems. This approach can be useful for phenotypic validation of putative mutant loci, as we demonstrate by confirming that knockdown of Prdm16 phenocopies the ENU-induced cleft palate (CP) mutant, csp1. This strategy is attractive as an alternative to gene targeting in embryonic stem cells, as it is simple and yields phenotypic information in a matter of weeks. Of the three methodologies tested, the PB transposon system produced high numbers of transgenic embryos with the expected phenotype, demonstrating its utility as a screening method.     

Oocyte-selective expression of MT transposon-like element, clone MTi7 and its role in oocyte maturation and embryo development

Previously, we found MT transposon-like element, clone MTi7 (MTi7) is highly expressed in the mouse ovary. Here, we show that the MTi7 is expressed in the oocyte from the primordial to the preovulatory follicles. For RNA interference (RNAi), double stranded RNAs (dsRNAs) were prepared for MTi7 and c-mos, a control gene with known functions. Each dsRNA was microinjected into germinal vesicle (GV) stage oocytes or zygotes with pronuclei (PN), after which developmental changes, mRNA expression, and nuclear and microtubular organization were analyzed. We found a 43.4-53% GV arrest in the microinjected oocytes with a concomitant decrease in targeted mRNA expression. In MTi7 dsRNA-injected early and late PN zygotes, a 92.9% 1-cell arrest and 76.9% 2-cell arrest were observed, respectively. This is the first report of an oocyte-selective expression of MTi7 mRNA, and our results strongly suggest that MTi7 involved in the nuclear membrane breakdown during oocyte maturation and embryo development.     

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.     

A transient RNA interference assay system using Arabidopsis protoplasts

Double-stranded RNA (dsRNA) induces sequence-specific gene silencing in eukaryotes through a process known as RNA interference (RNAi). RNAi is now used as a powerful tool for functional genomics in many eukaryotes, including plants. We herein report a dsRNA-mediated transient RNAi assay system using protoplasts from Arabidopsis mesophyll cells and suspension-cultured cells (cell line T87). Introduction of dsRNA into protoplasts led to marked silencing of target transgenes. Our assay system would provide a convenient and efficient way to induce RNAi in protoplasts of the model plant Arabidopsis thaliana.     

Rapid construction of Drosophila RNAi transgenes using pRISE, a P-element-mediated transformation vector exploiting an in vitro recombination system

RNAi is a gene-silencing phenomenon mediated by double-stranded RNA (dsRNA) and has become a powerful tool to elucidate gene function. To accomplish rapid construction of transgenes expressing dsRNA in Drosophila, we developed a novel transformation vector, pRISE, which contains an inverted repeat of the attR1-ccdB-attR2 cassette for in vitro recombination and a pentameric GAL4 binding site for conditional expression. These features enabled us to construct RNAi transgenes without a complicated cloning scheme. In cultured cells and transgenic flies, pRISE constructs carrying dsRNA transgenes induced effective RNAi against an EGFP transgene and the endogenous white gene, respectively. These results indicate that pRISE is a convenient transformation vector for studies of multiple Drosophila genes for which functional information is lacking.