Double-stranded (ds) RNA can induce sequence-specific inhibition of gene function in several organisms. However, both the mechanism and the physiological role of the interference process remain mysterious. In order to study the interference process, we have selected C. elegans mutants resistant to dsRNA-mediated interference (RNAi). Two loci, rde-1 and rde-4, are defined by mutants strongly resistant to RNAi but with no obvious defects in growth or development. We show that rde-1 is a member of the piwi/sting/argonaute/zwille/eIF2C gene family conserved from plants to vertebrates. Interestingly, several, but not all, RNAi-deficient strains exhibit mobilization of the endogenous transposons. We discuss implications for the mechanism of RNAi and the possibility that one natural function of RNAi is transposon silencing.
Double-stranded (ds) RNA induces potent gene silencing, termed RNA interference (RNAi). At an early step in RNAi, an RNaseIII-related enzyme, Dicer (DCR-1), processes long-trigger dsRNA into small interfering RNAs (siRNAs). DCR-1 is also required for processing endogenous regulatory RNAs called miRNAs, but how DCR-1 recognizes its endogenous and foreign substrates is not yet understood. Here we show that the C. elegans RNAi pathway gene, rde-4, encodes a dsRNA binding protein that interacts during RNAi with RNA identical to the trigger dsRNA. RDE-4 protein also interacts in vivo with DCR-1, RDE-1, and a conserved DExH-box helicase. Our findings suggest a model in which RDE-4 and RDE-1 function together to detect and retain foreign dsRNA and to present this dsRNA to DCR-1 for processing.
perhaps silencing tr&scriPtion at the &us. The alternative is that interference may prevent the processing or translation of the endogenous transcript. Several observations are most consistent with interference at a posttranscriptional step. First, only the sequences present in the mature transcript apDear to be effective at inducing interference. u e completion of the Caenorhabditis terference, two other remarkable features of Promoter and intron sequences appear to be elegans genome sequence represents a RNAi deserve comment. First is the obser-entirely ineffective (2). Second, some C. ele-T" major milestone in a journey initiated vation that the interfering activity can be guns genes exist in operons that are spliced by Sydney Brenner some 30 years ago. The transported across cell boundaries. Studies from a single transcript. If RNAi blocks goal then as now was to with dilute RNAs sug-transcription, then interfering with the 5' discover how genetic gest that the ideal tar-cistron would be expected to cause a polar information specifies get tissue for injec-effect that blocks the activity of all downthe development, anatotions is the intestine, stream cistrons. This does not appear to be my, and behavior of a even when the gene of the case. Several multicistronic genes have simple animal. Bringinterest is expressed in been analyzed (M), and in all cases, intering the full potential i f another tissue such as fering with the 5' cistrons can be accomthe genome sequence to bear on this goal will require facile new reverse genetic tools for converting sequence information into functional information. Here, we briefly describe progress toward understanding and using one such tool termed "RNA interference" or "RNAi." RNA interference was discovered by Guo and Kemphues (1) in the course of attempts to use antisense RNA to block gene expression in the maternal germ line. To their surprise, they found that both antisense and sense RNA preparations induced remarkably precise phenocopies of the targeted gene. Since then, both the efficacy and apparent lack of strand specificity associated with this interference process have been borne out in many subsequent studthe germ line or muscle (Fig. 1). Indeed, Lisa Timmons and Andrew Fire (4) have recently shown that feeding the worms Escherichia coli expressing the target gene dsRNA is sufficient to induce some interference. Thus, RNA uptake in the gut and distribution fiom the intestine to the somatic tissues and germ line can occur. Second, the RNAi effect is remarkably long lived. Potent plished without disturbing the expression of the downstream cistrons.Experiments with several maternal mRNAs suggest that RNAi does not destabilize or block the translation of the mature message. After RNAi injection into an adult hermaphrodite, we found that the first postinjection segment of the brood includes individuals that received both a functional interference is routinely observed not only maternal mRNA and the interfering RNA in the injected animal but also in all of the (5). In suc...
In Caenorhabditis elegans, the introduction of double-stranded RNA triggers sequence-specific genetic interference (RNAi) that is transmitted to offspring. The inheritance properties associated with this phenomenon were examined. Transmission of the interference effect occurred through a dominant extragenic agent. The wild-type activities of the RNAi pathway genes rde-1 and rde-4 were required for the formation of this interfering agent but were not needed for interference thereafter. In contrast, the rde-2 and mut-7 genes were required downstream for interference. These findings provide evidence for germ line transmission of an extragenic sequence-specific silencing factor and implicate rde-1 and rde-4 in the formation of the inherited agent.
In the RNA interference (RNAi) pathway, small interfering RNAs (siRNAs) play important roles as intermediates. Primary siRNAs are produced from trigger dsRNAs by an RNaseIII-related enzyme called Dicer; in some organisms, secondary siRNAs are also produced by processes involving RNA-dependent RNA polymerases (RdRPs), which act on target mRNAs. Using a cell-free assay system prepared from Caenorhabditis elegans, we analyzed the production and activity of secondary siRNAs. In this cell-free system, RdRP activity acts on mRNA-derived templates to produce small RNAs. The RRF-1 complex is predominantly responsible for the RdRP activity, and synthesizes secondary-type siRNA molecules in a Dicerindependent manner. Notably, secondary-type siRNAs induce a prominent Slicer activity to cleave target mRNAs far more effectively than primary-type siRNAs. An Argonaute protein, CSR-1, is responsible for the Slicer activity induced by secondary-type siRNAs. Secondary rather than primary siRNAs may play a major role in the destabilization of target transcripts during RNAi in C. elegans.
Introduction of double-stranded RNA (dsRNA) can elicit a gene-specific RNA interference response in a variety of organisms and cell types. In many cases, this response has a systemic character in that silencing of gene expression is observed in cells distal from the site of dsRNA delivery. The molecular mechanisms underlying the mobile nature of RNA silencing are unknown. For example, although cellular entry of dsRNA is possible, cellular exit of dsRNA from normal animal cells has not been directly observed. We provide evidence that transgenic strains of Caenorhabditis elegans transcribing dsRNA from a tissue-specific promoter do not exhibit comprehensive systemic RNA interference phenotypes. In these same animals, modifications of environmental conditions can result in more robust systemic RNA silencing. Additionally, we find that genetic mutations can influence the systemic character of RNA silencing in C. elegans and can separate mechanisms underlying systemic RNA silencing into tissue-specific components. These data suggest that trafficking of RNA silencing signals in C. elegans is regulated by specific physiological and genetic factors.
RNA interference (RNAi) is an ancient, highly conserved mechanism in which small RNA molecules (siRNAs) guide the sequence-specific silencing of gene expression . Several silencing machinery protein components have been identified, including helicases, RNase-related proteins, double- and single-stranded RNA binding proteins, and RNA-dependent RNA polymerase-related proteins . Work on these factors has led to the revelation that RNAi mechanisms intersect with cellular pathways required for development and fertility . Despite rapid progress in understanding key steps in the RNAi pathway, it is clear that many factors required for both RNAi and related developmental mechanisms have not yet been identified. Here, we report the characterization of the C. elegans gene rde-3. Genetic analysis of presumptive null alleles indicates that rde-3 is required for siRNA accumulation and for efficient RNAi in all tissues, and it is essential for fertility and viability at high temperatures. RDE-3 contains conserved domains found in the polymerase beta nucleotidyltransferase superfamily, which includes conventional poly(A) polymerases, 2'-5' oligoadenylate synthetase (OAS), and yeast Trf4p . These findings implicate a new enzymatic modality in RNAi and suggest possible models for the role of RDE-3 in the RNAi mechanism.
In Caenorhabditis elegans, the activity of transposable elements is repressed in the germline. One of the mechanisms involved in this repression is RNA interference (RNAi), a process in which dsRNA targets cleavage of mRNAs in a sequence-specific manner. The first gene found to be involved in RNAi and transposon silencing in C.elegans is mut-7, a gene encoding a putative exoribonuclease. Here, we show that the MUT-7 protein resides in complexes of ∼250 kDa in the nucleus and in the cytosol. In addition, we find that upon triggering of RNAi the cytosolic MUT-7 complex increases in size. This increase is independent of the presence of target RNA, but does depend on the presence of RDE-1 and RDE-4, two proteins involved in small interfering RNA (siRNA) production. Finally, using a yeast two-hybrid screen, we identified RDE-2/MUT-8 as one of the other components of this complex. This protein is encoded by the rde-2/mut-8 locus, previously implicated in RNAi and transposon silencing. Using genetic complementation analysis, we show that the interaction between these two proteins is required for efficient RNAi in vivo. Together these data support a role for the MUT-7/RDE-2 complex downstream of siRNA formation, but upstream of siRNA mediated target RNA recognition, possibly indicating a role in the siRNA amplification step.
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