High-Throughput Analysis Reveals Rules for Target RNA Binding and Cleavage by AGO2 (original) (raw)
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Small RNA molecules have been known and utilized to suppress gene expression for more than a decade. The discovery that these small RNA molecules are endogenously expressed in many organisms and have a critical role in controlling gene expression have led to the arising of a whole new field of research. Termed small interfering RNA (siRNA) or microRNA (miRNA) these ~22 nt RNA molecules have the capability to suppress gene expression through various mechanisms once they are incorporated in the multi-protein RNA-Induced Silencing Complex (RISC) and interact with their target mRNA. This review introduces siRNAs and microRNAs in a historical perspective and focuses on the key molecules in RISC, structural properties and mechanisms underlying the process of small RNA regulated post-transcriptional suppression of gene expression.
C3PO, an Endoribonuclease That Promotes RNAi by Facilitating RISC Activation
Science, 2009
The catalytic engine of RNAi is the RNA-induced silencing complex (RISC), wherein the endoribonuclease Argonaute and single-stranded siRNA direct target mRNA cleavage. Here we have reconstituted long dsRNA-and duplex siRNAinitiated RISC activities using recombinant Drosophila Dicer-2, R2D2 and Ago2 proteins. We employ this core reconstitution system to purify an RNAi regulator-component 3 promoter of RISC (C3PO), a complex of Translin and Trax.
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Nature Structural & Molecular Biology, 2010
Small RNAs, including microRNAs (miRNAs) and small interfering RNAs (siRNAs), regulate various biological functions by downregulating the expression of the target genes. Small RNAs do not work alone, but rather function as the specificity determinants of the effector ribonucleoprotein complexes, called RNA-induced silencing complexes (RISCs) . Although a number of proteins have been identified as candidates for RISC components 5-8 , exactly which proteins compose RISC is not well defined. One established exception is a member of the Argonaute (Ago) family of proteins, the very core component of RISC. Ago family proteins can be divided into ubiquitously expressed AGO subfamily proteins and gonadally expressed P-element-induced wimpy testis (PIWI) subfamily proteins 1-4 . Drosophila has two AGO proteins, Ago1 and Ago2, whereas humans have four, Ago1-4.
Analysis of AgoshRNA maturation and loading into Ago2
PLOS ONE
The RNA interference (RNAi) pathway was recently expanded by the discovery of multiple alternative pathways for processing of natural microRNA (miRNA) and man-made short hairpin RNA (shRNA) molecules. One non-canonical pathway bypasses Dicer cleavage and requires instead processing by Argonaute2 (Ago2), which also executes the subsequent silencing step. We named these molecules AgoshRNA, which generate only a single active RNA strand and thus avoid off-target effects that can be induced by the passenger strand of a regular shRNA. Previously, we characterized AgoshRNA processing by deep sequencing and demonstrated that-after Ago2 cleavage-AgoshRNAs acquire a short 3' tail of 1-3 A-nucleotides and are subsequently trimmed, likely by the poly(A)-specific ribonuclease (PARN). As a result, the mature single-stranded AgoshRNA may dock more stably into Ago2. Here we set out to analyze the activity of different synthetic AgoshRNA processing intermediates. Ago2 was found to bind preferentially to partially single-stranded AgoshRNA in vitro. In contrast, only the double-stranded AgoshRNA precursor associated with Ago2 in cells, correlating with efficient intracellular processing and reporter knockdown activity. These results suggest the presence of a cellular co-factor involved in AgoshRNA loading into Ago2 in vivo. We also demonstrate specific AgoshRNA loading in Ago2, but not Ago1/3/ 4, thus further reducing unwanted side effects.
Mechanistic insights on the Dicer-independent AGO2-mediated processing of AgoshRNAs
RNA biology, 2015
Short hairpin RNAs (shRNAs) are widely used for gene knockdown by inducing the RNA interference (RNAi) mechanism, both for research and therapeutic purposes. The shRNA precursor is processed by the RNase III-like enzyme Dicer into biologically active small interfering RNA (siRNA). This effector molecule subsequently targets a complementary mRNA for destruction via the Argonaute 2 (AGO2) complex. The cellular role of Dicer concerns the processing of pre-miRNAs into mature microRNA (miRNA). Recently, a non-canonical pathway was reported for the biogenesis of miR-451, which bypasses Dicer and is processed instead by the slicer activity of AGO2, followed by the regular AGO2-mediated mRNA targeting step. Interestingly, shRNA designs that are characterized by a relatively short basepaired stem also bypass Dicer to be processed by AGO2. We named this design AgoshRNA as these molecules depend on AGO2 both for processing and silencing activity. In this study, we investigated diverse mechanis...
RNA biology, 2015
Short hairpin RNAs (shRNAs) are widely used for gene knockdown by inducing the RNA interference (RNAi) mechanism. The shRNA precursor is processed by Dicer into small interfering RNAs (siRNAs) and subsequently programs the RNAi-induced silencing complex (RISC) to find a complementary target messenger RNA (mRNA) for post-transcriptional gene silencing. Recent evidence indicates that shRNAs with a relatively short basepaired stem bypass Dicer to be processed directly by the Ago2 nuclease of the RISC complex. We named this design AgoshRNA as these molecules depend on Ago2 both for processing and subsequent silencing activity. This alternative AgoshRNA processing route yields only a single active RNA strand, an important feature to restrict off-target effects induced by the passenger strand of regular shRNAs. It is therefore important to understand this novel AgoshRNA processing route in mechanistic detail such that one can design the most effective and selective RNA reagents. We perfor...
Passenger-Strand Cleavage Facilitates Assembly of siRNA into Ago2-Containing RNAi Enzyme Complexes
Cell, 2005
In the Drosophila and mammalian RNA interference pathways, siRNAs direct the protein Argonaute2 (Ago2) to cleave corresponding mRNA targets, silencing their expression. Ago2 is the catalytic component of the RNAi enzyme complex, RISC. For each siRNA duplex, only one strand, the guide, is assembled into the active RISC; the other strand, the passenger, is destroyed. An ATP-dependent helicase has been proposed first to separate the two siRNA strands, then the resulting single-stranded guide is thought to bind Ago2. Here, we show that Ago2 instead directly receives the double-stranded siRNA from the RISC assembly machinery. Ago2 then cleaves the siRNA passenger strand, thereby liberating the single-stranded guide. For siRNAs, virtually all RISC is assembled through this cleavage-assisted mechanism. In contrast, passenger-strand cleavage is not important for the incorporation of miRNAs that derive from mismatched duplexes.
Effect of target secondary structure on RNAi efficiency
RNA, 2007
RNA interference (RNAi) mediated by small interfering RNAs (siRNAs) or short hairpin RNAs (shRNAs) has become a powerful tool for gene knockdown studies. However, the levels of knockdown vary greatly. Here, we examine the effect of target disruption energy, a novel measure of target accessibility, along with other parameters that may affect RNAi efficiency. Based on target secondary structures predicted by the Sfold program, the target disruption energy represents the free energy cost for local alteration of the target structure to allow target binding by the siRNA guide strand. In analyses of 100 siRNAs and 101 shRNAs targeted to 103 endogenous human genes, we find that the disruption energy is an important determinant of RNAi activity and the asymmetry of siRNA duplex asymmetry is important for facilitating the assembly of the RNA-induced silencing complex (RISC). We estimate that target accessibility and duplex asymmetry can improve the target knockdown level significantly by nea...