The C-terminal domains of human TNRC6A,TNRC6B,and TNRC6C silence bound transcripts independently of Argonaute proteins

Proteins of the GW182 family are essential components of the miRNA pathway in animal cells. Vertebrate genomes encode three GW182 paralogs (TNRC6A, TNRC6B, and TNRC6C), which may be functionally redundant. Here, we show that the N-terminal GW-repeat-containing regions of all three TNRC6s interact with the four human Argonaute proteins (AGO1–AGO4). We also show that TNRC6A, TNRC6B, and TNRC6C silence the expression of bound mRNAs. This activity is mediated by their C-terminal silencing domains, and thus, is independent of the interaction with AGO1–AGO4. Silencing by TNRC6A, TNRC6B, and TNRC6C is effected by changes in protein expression and mRNA stability that can, in part, be attributed to deadenylation. Our findings indicate that TNRC6A, TNRC6B, and TNRC6C are recruited to miRNA targets through an interaction between their N-terminal domain and an Argonaute protein; the TNRC6s then promote translational repression and/or degradation of miRNA targets through a C-terminal silencing domain.     

Multiple independent domains of dGW182 function in miRNA-mediated repression in Drosophila

miRNA-mediated repression affects a wide range of biological processes including development and human pathologies. The GW182 protein is a key component of miRNA repression complex, recruited by Argonaute and functioning downstream to repress translation and accelerate mRNA degradation, but little is known about how GW182 proteins act. Using both tethered function and complementation assays, we identify three independent domains of the Drosophila GW182 protein (also termed Gawky) that are sufficient to repress mRNA. Each of these domains also functions independently of poly(A) tails. These results indicate that miRNA-mediated repression is facilitated by multiple domains of GW182.     

The GW/WG repeats of Drosophila GW182 function as effector motifs for miRNA-mediated repression

The control of messenger RNA (mRNA) function by micro RNAs (miRNAs) in animal cells requires the GW182 protein. GW182 is recruited to the miRNA repression complex via interaction with Argonaute protein, and functions downstream to repress protein synthesis. Interaction with Argonaute is mediated by GW/WG repeats, which are conserved in many Argonaute-binding proteins involved in RNA interference and miRNA silencing, from fission yeast to mammals. GW182 contains at least three effector domains that function to repress target mRNA. Here, we analyze the functions of the N-terminal GW182 domain in repression and Argonaute1 binding, using tethering and immunoprecipitation assays in Drosophila cultured cells. We demonstrate that its function in repression requires intact GW/WG repeats, but does not involve interaction with the Argonaute1 protein, and is independent of the mRNA polyadenylation status. These results demonstrate a novel role for the GW/WG repeats as effector motifs in miRNA-mediated repression.     

Human TNRC6A is an Argonaute-navigator protein for microRNA-mediated gene silencing in the nucleus

GW182 family proteins play important roles in microRNA (miRNA)-mediated gene silencing. They interact with Argonaute (Ago) proteins and localize in processing bodies, which are cytoplasmic foci involved in mRNA degradation and storage. Here, we demonstrated that human GW182 paralog, TNRC6A, is a nuclear–cytoplasmic shuttling protein, and its subcellular localization is conducted by a nuclear export signal (NES) and a nuclear localization signal (NLS) identified in this study. TNRC6A with mutations in its NES region was predominantly localized in the nucleus in an Ago-independent manner. However, it was found that TNRC6A could bring Ago protein into the nucleus via its Ago-interacting motif(s). Furthermore, miRNAs were also colocalized with nuclear TNRC6A-Ago and exhibited gene silencing activity. These results proposed the possibility that TNRC6A plays an important role in navigating Ago protein into the nucleus to lead miRNA-mediated gene silencing.     

The interactions of GW182 proteins with PABP and deadenylases are required for both translational repression and degradation of miRNA targets

Animal miRNAs silence the expression of mRNA targets through translational repression, deadenylation and subsequent mRNA degradation. Silencing requires association of miRNAs with an Argonaute protein and a GW182 family protein. In turn, GW182 proteins interact with poly(A)-binding protein (PABP) and the PAN2–PAN3 and CCR4–NOT deadenylase complexes. These interactions are required for the deadenylation and decay of miRNA targets. Recent studies have indicated that miRNAs repress translation before inducing target deadenylation and decay; however, whether translational repression and deadenylation are coupled or represent independent repressive mechanisms is unclear. Another remaining question is whether translational repression also requires GW182 proteins to interact with both PABP and deadenylases. To address these questions, we characterized the interaction of Drosophila melanogaster GW182 with deadenylases and defined the minimal requirements for a functional GW182 protein. Functional assays in D. melanogaster and human cells indicate that miRNA-mediated translational repression and degradation are mechanistically linked and are triggered through the interactions of GW182 proteins with PABP and deadenylases.     

Control of the localization and function of a miRNA silencing component TNRC6A by Argonaute protein

GW182 family proteins play important roles in microRNA (miRNA)-mediated RNA silencing. They directly interact with Argonaute (Ago) proteins in processing bodies (P bodies), cytoplasmic foci involved in mRNA degradation and storage. Recently, we revealed that a human GW182 family protein, TNRC6A, is a nuclear-cytoplasmic shuttling protein, and its subcellular localization is regulated by its own nuclear localization signal and nuclear export signal. Regarding the further controlling mechanism of TNRC6A subcellular localization, we found that TNRC6A protein is tethered in P bodies by direct interaction with Ago2 under Ago2 overexpression condition in HeLa cells. Furthermore, it was revealed that such Ago proteins might be strongly tethered in the P bodies through Ago-bound small RNAs. Thus, our results indicate that TNRC6A subcellular localization is substantially controlled by the interaction with Ago proteins. Furthermore, it was also revealed that the TNRC6A subcellular localization affects the RNA silencing activity.     

Two PABPC1-binding sites in GW182 proteins promote miRNA-mediated gene silencing

miRNA-mediated gene silencing requires the GW182 proteins, which are characterized by an N-terminal domain that interacts with Argonaute proteins (AGOs), and a C-terminal silencing domain (SD). In Drosophila melanogaster (Dm) GW182 and a human (Hs) orthologue, TNRC6C, the SD was previously shown to interact with the cytoplasmic poly(A)-binding protein (PABPC1). Here, we show that two regions of GW182 proteins interact with PABPC1: the first contains a PABP-interacting motif 2 (PAM2; as shown before for TNRC6C) and the second contains the M2 and C-terminal sequences in the SD. The latter mediates indirect binding to the PABPC1 N-terminal domain. In D. melanogaster cells, the second binding site dominates; however, in HsTNRC6A-C the PAM2 motif is essential for binding to both Hs and DmPABPC1. Accordingly, a single amino acid substitution in the TNRC6A-C PAM2 motif abolishes the interaction with PABPC1. This mutation also impairs TNRC6s silencing activity. Our findings reveal that despite species-specific differences in the relative strength of the PABPC1-binding sites, the interaction between GW182 proteins and PABPC1 is critical for miRNA-mediated silencing in animal cells.     

Divergent GW182 functional domains in the regulation of translational silencing

MicroRNA (miRNA)-mediated gene regulation has become a major focus in many biological processes. GW182 and its long isoform TNGW1 are marker proteins of GW/P bodies and bind to Argonaute proteins of the RNA induced silencing complex. The goal of this study is to further define and distinguish the repression domain(s) in human GW182/TNGW1. Two non-overlapping regions, Δ12 (amino acids 896-1219) containing the Ago hook and Δ5 (amino acids 1670-1962) containing the RRM, both induced comparable silencing in a tethering assay. Mapping data showed that the RRM and its flanking sequences in Δ5, but not the Ago hook in Δ12, were important for silencing. Repression mediated by Δ5 or Δ12 was not differentially affected when known endogenous repressors RCK/p54, GW182/TNGW1, TNRC6B were depleted. Transfected Δ5, but not Δ12, enhanced Ago2-mediated repression in a tethering assay. Transfected Δ12, but not Δ5, released endogenous miRNA reporter silencing without affecting siRNA function. Alanine substitution showed that GW/WG motifs in Δ12 (Δ12a, amino acids 896-1045) were important for silencing activity. Although Δ12 appeared to bind PABPC1 more efficiently than Δ5, neither Δ5 nor Δ12 significantly enhanced reporter mRNA degradation. These different functional characteristics of Δ5 and Δ12 suggest that their roles are distinct, and possibly dynamic, in human GW182-mediated silencing.     

Importin-β facilitates nuclear import of human GW proteins and balances cytoplasmic gene silencing protein levels

MicroRNAs (miRNAs) guide Argonaute (Ago) proteins to distinct target mRNAs leading to translational repression and mRNA decay. Ago proteins interact with a member of the GW protein family, referred to as TNRC6A-C in mammals, which coordinate downstream gene-silencing processes. The cytoplasmic functions of TNRC6 and Ago proteins are reasonably well established. Both protein families are found in the nucleus as well. Their detailed nuclear functions, however, remain elusive. Furthermore, it is not clear which import routes Ago and TNRC6 proteins take into the nucleus. Using different nuclear transport assays, we find that Ago as well as TNRC6 proteins shuttle between the cytoplasm and the nucleus. While import receptors might function redundantly to transport Ago2, we demonstrate that TNRC6 proteins are imported by the Importin-β pathway. Finally, we show that nuclear localization of both Ago2 and TNRC6 proteins can depend on each other suggesting actively balanced cytoplasmic Ago – TNRC6 levels.     

GW182 proteins cause PABP dissociation from silenced miRNA targets in the absence of deadenylation

GW182 family proteins interact with Argonaute proteins and are required for the translational repression, deadenylation and decay of miRNA targets. To elicit these effects, GW182 proteins interact with poly(A)‐binding protein (PABP) and the CCR4–NOT deadenylase complex. Although the mechanism of miRNA target deadenylation is relatively well understood, how GW182 proteins repress translation is not known. Here, we demonstrate that GW182 proteins decrease the association of eIF4E, eIF4G and PABP with miRNA targets. eIF4E association is restored in cells in which miRNA targets are deadenylated, but decapping is inhibited. In these cells, eIF4G binding is not restored, indicating that eIF4G dissociates as a consequence of deadenylation. In contrast, PABP dissociates from silenced targets in the absence of deadenylation. PABP dissociation requires the interaction of GW182 proteins with the CCR4–NOT complex. Accordingly, NOT1 and POP2 cause dissociation of PABP from bound mRNAs in the absence of deadenylation. Our findings indicate that the recruitment of the CCR4–NOT complex by GW182 proteins releases PABP from the mRNA poly(A) tail, thereby disrupting mRNA circularization and facilitating translational repression and deadenylation.     

Defining a new role of GW182 in maintaining miRNA stability

GW182 binds to Argonaute (AGO) proteins and has a central role in miRNA‐mediated gene silencing. Using lentiviral shRNA‐induced GW182 knockdown in HEK293 cells, this study identifies a new role of GW182 in regulating miRNA stability. Stably knocking down GW182 or its paralogue TNRC6B reduces transfected miRNA‐mimic half‐lives. Replenishment of GW182 family proteins, as well as one of its domain Δ12, significantly restores the stability of transfected miRNA‐mimic. GW182 knockdown reduces miRNA secretion via secretory exosomes. Targeted siRNA screening identifies a 3′–5′ exoribonuclease complex responsible for the miRNA degradation only when GW182 is knocked down. Immunoprecipitation further confirms that the presence of GW182 in the RISC complex is critical in protecting Argonaute‐bound miRNA.     

Mechanism of allele-selective inhibition of huntingtin expression by duplex RNAs that target CAG repeats: function through the RNAi pathway

Huntington’s disease is an incurable neurodegenerative disorder caused by expansion of a CAG trinucleotide repeat within one allele of the huntingtin (HTT) gene. Agents that block expression of mutant HTT and preserve expression of wild-type HTT target the cause of the disease and are an alternative for therapy. We have previously demonstrated that mismatch-containing duplex RNAs complementary to the expanded trinucleotide repeat are potent and allele-selective inhibitors of mutant HTT expression, but the mechanism of allele selectivity was not explored. We now report that anti-CAG duplex RNA preferentially recruits argonaute 2 (AGO2) to mutant rather than wild-type HTT mRNA. Efficient inhibition of mutant HTT protein expression requires less AGO2 than needed for inhibiting wild-type expression. In contrast, inhibiting the expression of mutant HTT protein is highly sensitive to reduced expression of GW182 (TNRC6A) and its two paralogs, a protein family associated with miRNA action. Allele-selective inhibition may involve cooperative binding of multiple protein–RNA complexes to the expanded repeat. These data suggest that allele-selective inhibition proceeds through an RNA interference pathway similar to that used by miRNAs and that discrimination between mutant and wild-type alleles of HTT mRNA is highly sensitive to the pool of AGO2 and GW182 family proteins inside cells.     

miRISC and the CCR4–NOT complex silence mRNA targets independently of 43S ribosomal scanning

miRNAs associate with Argonaute (AGO) proteins to silence the expression of mRNA targets by inhibiting translation and promoting deadenylation, decapping, and mRNA degradation. A current model for silencing suggests that AGOs mediate these effects through the sequential recruitment of GW182 proteins, the CCR4–NOT deadenylase complex and the translational repressor and decapping activator DDX6. An alternative model posits that AGOs repress translation by interfering with eIF4A function during 43S ribosomal scanning and that this mechanism is independent of GW182 and the CCR4–NOT complex in Drosophila melanogaster. Here, we show that miRNAs, AGOs, GW182, the CCR4–NOT complex, and DDX6/Me31B repress and degrade polyadenylated mRNA targets that are translated via scanning‐independent mechanisms in both human and Dm cells. This and additional observations indicate a common mechanism used by these proteins and miRNAs to mediate silencing. This mechanism does not require eIF4A function during ribosomal scanning.     

The Silencing Domain of GW182 Interacts with PABPC1 To Promote Translational Repression and Degradation of MicroRNA Targets and Is Required for Target Release

GW182 family proteins are essential in animal cells for microRNA (miRNA)-mediated gene silencing, yet the molecular mechanism that allows GW182 to promote translational repression and mRNA decay remains largely unknown. Previous studies showed that while the GW182 N-terminal domain interacts with Argonaute proteins, translational repression and degradation of miRNA targets are promoted by a bipartite silencing domain comprising the GW182 middle and C-terminal regions. Here we show that the GW182 C-terminal region is required for GW182 to release silenced mRNPs; moreover, GW182 dissociates from miRNA targets at a step of silencing downstream of deadenylation, indicating that GW182 is required to initiate but not to maintain silencing. In addition, we show that the GW182 bipartite silencing domain competes with eukaryotic initiation factor 4G for binding to PABPC1. The GW182-PABPC1 interaction is also required for miRNA target degradation; accordingly, we observed that PABPC1 associates with components of the CCR4-NOT deadenylase complex. Finally, we show that PABPC1 overexpression suppresses the silencing of miRNA targets. We propose a model in which the GW182 silencing domain promotes translational repression, at least in part, by interfering with mRNA circularization and also recruits the deadenylase complex through the interaction with PABPC1.In multicellular eukaryotes, the regulation of gene expression by microRNAs (miRNAs) is critical for biological processes as diverse as cell differentiation and proliferation, apoptosis, metabolism, and development (4). To exert a regulatory function, miRNAs associate with Argonaute proteins to form RNA-induced silencing complexes, which repress translation and trigger the degradation of target mRNAs (4, 10, 16). The extent to which translational repression and degradation contribute to silencing depends on the specific target-miRNA combination; some targets are regulated predominantly at the translational level, whereas others can be regulated mainly at the mRNA level (3). A large-scale proteomic analysis performed in parallel with measurements of mRNA levels showed that for the vast majority of miRNA targets, silencing correlates with changes at both the protein and mRNA levels (1, 27).In animal cells, the degradation of miRNA targets is initiated by deadenylation and decapping, which are followed by the exonucleolytic decay of the mRNA body (2, 3, 9, 11, 12, 17, 19, 24, 30, 31). miRNA-dependent mRNA degradation requires a variety of proteins: an Argonaute and a GW182 protein, the CCR4-NOT deadenylase complex, the decapping enzyme DCP2, and several decapping activators including DCP1, Ge-1, HPat, EDC3, and Me31B (also known as RCK/p54) (3, 6, 9, 12, 19). Several studies previously demonstrated that miRNAs trigger deadenylation and decapping even when the mRNA target is not translated (9, 12, 19, 24, 30, 31), indicating that mRNA decay is not merely a consequence of a primary effect of miRNAs on translation but rather is an independent mechanism by which miRNAs silence gene expression.Although how miRNAs trigger mRNA degradation is well established, the mechanisms driving the inhibition of translation are unclear. Multiple mechanisms have been proposed: the displacement of eukaryotic initiation factor 4E (eIF4E) from the mRNA cap structure, interference with the function of the eIF4F complex, a block of 60S ribosomal subunit joining, or an inhibition of translation elongation (4, 10, 16). Regardless of the precise mechanism, the translational repression of miRNA targets also requires GW182 family proteins (11, 13).GW182 proteins are essential components of the miRNA pathway in animal cells, as their depletion suppresses miRNA-mediated gene silencing (reviewed in references 8 and 13). Recent studies have revealed that the silencing activity of these proteins resides predominantly in a bipartite silencing domain containing the middle and C-terminal regions (14, 22, 33). The precise molecular function of the GW182 silencing domain is not fully understood, yet it is known that the domain is not required for GW182 proteins to interact with Argonaute proteins or to localize to P bodies (3, 14, 22). Furthermore, when the silencing domains of GW182 proteins are artificially tethered to mRNAs, their expression is silenced; therefore, tethering bypasses the requirement for Argonaute proteins and miRNAs (5, 22, 33). These observations suggest that the silencing domains of GW182 proteins exhibit intrinsic silencing activity and therefore likely play a role at the effector step of silencing (13, 14, 22, 33).Here we investigate what role the Drosophila melanogaster GW182 silencing domain plays in the miRNA pathway. Overall, our results reveal that the very C-terminal region of this domain is required for the release of GW182 from silenced mRNPs. Indeed, we unexpectedly found that we could detect D. melanogaster GW182 bound to miRNA targets only in cells depleted of components of the deadenylase complex. These results suggest that GW182 dissociates from Argonaute-1 (AGO1) and miRNA targets at a step of silencing downstream of deadenylation. In contrast, GW182 mutants lacking the C-terminal region remain stably bound to miRNA targets, even in wild-type cells, indicating that this region plays a role in the dissociation of GW182 from effector complexes. We further show that the bipartite silencing domain of GW182 interacts with PABPC1 and interferes with the binding of PABPC1 to eIF4G. The interaction of GW182 with PABPC1 is also required for the degradation of miRNA targets, most likely because the interaction facilitates the recruitment of the CCR4-NOT deadenylase complex. Accordingly, overexpressing PABPC1 suppresses the silencing of miRNA targets. Our findings uncover an unexpected role for PABPC1 in the miRNA pathway.