A C-terminal silencing domain in GW182 is essential for miRNA function

Proteins of the GW182 family are essential for miRNA-mediated gene silencing in animal cells; they interact with Argonaute proteins (AGOs) and are required for both the translational repression and mRNA degradation mediated by miRNAs. To gain insight into the role of the GW182–AGO1 interaction in silencing, we generated protein mutants that do not interact and tested them in complementation assays. We show that silencing of miRNA targets requires the N-terminal domain of GW182, which interacts with AGO1 through multiple glycine–tryptophan (GW)-repeats. Indeed, a GW182 mutant that does not interact with AGO1 cannot rescue silencing in cells depleted of endogenous GW182. Conversely, silencing is impaired by mutations in AGO1 that strongly reduce the interaction with GW182 but not with miRNAs. We further show that a GW182 mutant that does not localize to P-bodies but interacts with AGO1 rescues silencing in GW182-depleted cells, even though in these cells, AGO1 also fails to localize to P-bodies. Finally, we show that in addition to the N-terminal AGO1-binding domain, the middle and C-terminal regions of GW182 (referred to as the bipartite silencing domain) are essential for silencing. Together our results indicate that miRNA silencing in animal cells is mediated by AGO1 in complex with GW182, and that P-body localization is not required for silencing.     

Temperature-dependent survival of Turnip crinkle virus-infected arabidopsis plants relies on an RNA silencing-based defense that requires dcl2, AGO2, and HEN1

While RNA silencing is a potent antiviral defense in plants, well-adapted plant viruses are known to encode suppressors of RNA silencing (VSR) that can neutralize the effectiveness of RNA silencing. As a result, most plant genes involved in antiviral silencing were identified by using debilitated viruses lacking silencing suppression capabilities. Therefore, it remains to be resolved whether RNA silencing plays a significant part in defending plants against wild-type viruses. We report here that, at a higher plant growth temperature (26°C) that permits rigorous replication of Turnip crinkle virus (TCV) in Arabidopsis, plants containing loss-of-function mutations within the Dicer-like 2 (DCL2), Argonaute 2 (AGO2), and HEN1 RNA methyltransferase genes died of TCV infection, whereas the wild-type Col-0 plants survived to produce viable seeds. To account for the critical role of DCL2 in ensuring the survival of wild-type plants, we established that higher temperature upregulates the activity of DCL2 to produce viral 22-nucleotide (nt) small interfering RNAs (vsRNAs). We further demonstrated that DCL2-produced 22-nt vsRNAs were fully capable of silencing target genes, but that this activity was suppressed by the TCV VSR. Finally, we provide additional evidence supporting the notion that TCV VSR suppresses RNA silencing through directly interacting with AGO2. Together, these results have revealed a specialized RNA silencing pathway involving DCL2, AGO2, and HEN1 that provides the host plants with a competitive edge against adapted viruses under environmental conditions that facilitates robust virus reproduction.     

Polerovirus protein P0 prevents the assembly of small RNA‐containing RISC complexes and leads to degradation of ARGONAUTE1

RNA silencing plays an important role in plants in defence against viruses. To overcome this defence, plant viruses encode suppressors of RNA silencing. The most common mode of silencing suppression is sequestration of double‐stranded RNAs involved in the antiviral silencing pathways. Viral suppressors can also overcome silencing responses through protein–protein interaction. The poleroviral P0 silencing suppressor protein targets ARGONAUTE (AGO) proteins for degradation. AGO proteins are the core component of the RNA‐induced silencing complex (RISC). We found that P0 does not interfere with the slicer activity of pre‐programmed siRNA/miRNA containing AGO1, but prevents de novo formation of siRNA/miRNA containing AGO1. We show that the AGO1 protein is part of a high‐molecular‐weight complex, suggesting the existence of a multi‐protein RISC in plants. We propose that P0 prevents RISC assembly by interacting with one of its protein components, thus inhibiting formation of siRNA/miRNA–RISC, and ultimately leading to AGO1 degradation. Our findings also suggest that siRNAs enhance the stability of co‐expressed AGO1 in both the presence and absence of P0.     

Virus-induced gene silencing of argonaute genes in Nicotiana benthamiana demonstrates that extensive systemic silencing requires Argonaute1-like and Argonaute4-like genes

Several distinct pathways of RNA silencing operate in plants with roles including the suppression of virus accumulation, control of endogenous gene expression, and direction of DNA and chromatin modifications. Proteins of the Dicer-Like and Argonaute (AGO) families have key roles within these silencing pathways and have distinct biochemical properties. We are interested in the relationships between different silencing pathways and have used Nicotiana benthamiana as a model system. While not being an amenable plant for traditional genetics, N. benthamiana is extensively used for RNA-silencing studies. Using virus-induced gene silencing technology we demonstrate that both NbAGO1- and NbAGO4-like genes are required for full systemic silencing but not for silencing directed by an inverted repeat transgene. Phenotypic differences between the virus-induced gene silencing plants indicate that NbAGO1 and NbAGO4 like act at different stages of the silencing pathways. Suppression of NbAGO1 expression recapitulated the hypomorphic mutant phenotype of certain Arabidopsis (Arabidopsis thaliana) ago1 alleles, however, suppression of NbAgo4 like resulted in phenotypes differing in some respects from those reported for Arabidopsis ago4. We suggest that the small interfering RNA amplification step required for full systemic silencing is dependent upon a nuclear event requiring the activity of NbAGO4 like.     

Roles and Programming of Arabidopsis ARGONAUTE Proteins during Turnip Mosaic Virus Infection

In eukaryotes, ARGONAUTE proteins (AGOs) associate with microRNAs (miRNAs), short interfering RNAs (siRNAs), and other classes of small RNAs to regulate target RNA or target loci. Viral infection in plants induces a potent and highly specific antiviral RNA silencing response characterized by the formation of virus-derived siRNAs. Arabidopsis thaliana has ten AGO genes of which AGO1, AGO2, and AGO7 have been shown to play roles in antiviral defense. A genetic analysis was used to identify and characterize the roles of AGO proteins in antiviral defense against Turnip mosaic virus (TuMV) in Arabidopsis. AGO1, AGO2 and AGO10 promoted anti-TuMV defense in a modular way in various organs, with AGO2 providing a prominent antiviral role in leaves. AGO5, AGO7 and AGO10 had minor effects in leaves. AGO1 and AGO10 had overlapping antiviral functions in inflorescence tissues after systemic movement of the virus, although the roles of AGO1 and AGO10 accounted for only a minor amount of the overall antiviral activity. By combining AGO protein immunoprecipitation with high-throughput sequencing of associated small RNAs, AGO2, AGO10, and to a lesser extent AGO1 were shown to associate with siRNAs derived from silencing suppressor (HC-Pro)-deficient TuMV-AS9, but not with siRNAs derived from wild-type TuMV. Co-immunoprecipitation and small RNA sequencing revealed that viral siRNAs broadly associated with wild-type HC-Pro during TuMV infection. These results support the hypothesis that suppression of antiviral silencing during TuMV infection, at least in part, occurs through sequestration of virus-derived siRNAs away from antiviral AGO proteins by HC-Pro. These findings indicate that distinct AGO proteins function as antiviral modules, and provide a molecular explanation for the silencing suppressor activity of HC-Pro.     

The novel MER transposon-derived miRNAs in human genome

MicroRNAs (miRNAs) are small RNA molecules (~ 20–30 nucleotides) that generally act in gene silencing and translational repression through the RNA interference pathway. They generally originate from intergenic genomic regions, but some are found in genomic regions that have been characterized such as introns, exons, and transposable elements (TE). To identify the miRNAs that are derived from palindromic MERs, we analyzed MER paralogs in human genome. The structures of the palindromic MERs were similar to the hairpin structure of miRNA in humans. Three miRNAs derived from MER96 located on chromosome 3, and MER91C paralogs located on chromosome 8 and chromosome 17 were identified in HeLa, HCT116, and HEK293 cell lines. The interactions between these MER-derived miRNAs and AGO1, AGO2, and AGO3 proteins were validated by immunoprecipitation assays. The data suggest that miRNAs derived from transposable elements could widely affect various target genes in the human genome.     

Diversity,expression and mRNA targeting abilities of Argonaute-targeting miRNAs among selected vascular plants

Background

Micro (mi)RNAs are important regulators of plant development. Across plant lineages, Dicer-like 1 (DCL1) proteins process long ds-like structures to produce micro (mi) RNA duplexes in a stepwise manner. These miRNAs are incorporated into Argonaute (AGO) proteins and influence expression of RNAs that have sequence complementarity with miRNAs. Expression levels of AGOs are greatly regulated by plants in order to minimize unwarranted perturbations using miRNAs to target mRNAs coding for AGOs. AGOs may also have high promoter specificity-sometimes expression of AGO can be limited to just a few cells in a plant. Viral pathogens utilize various means to counter antiviral roles of AGOs including hijacking the host encoded miRNAs to target AGOs. Two host encoded miRNAs namely miR168 and miR403 that target AGOs have been described in the model plant Arabidopsis and such a mechanism is thought to be well conserved across plants because AGO sequences are well conserved.

Results

We show that the interaction between AGO mRNAs and miRNAs is species-specific due to the diversity in sequences of two miRNAs that target AGOs, sequence diversity among corresponding target regions in AGO mRNAs and variable expression levels of these miRNAs among vascular plants. We used miRNA sequences from 68 plant species representing 31 plant families for this analysis. Sequences of miR168 and miR403 are not conserved among plant lineages, but surprisingly they differ drastically in their sequence diversity and expression levels even among closely related plants. Variation in miR168 expression among plants correlates well with secondary structures/length of loop sequences of their precursors.

Conclusions

Our data indicates a complex AGO targeting interaction among plant lineages due to miRNA sequence diversity and sequences of miRNA targeting regions among AGO mRNAs, thus leading to the assumption that the perturbations by viruses that use host miRNAs to target antiviral AGOs can only be species-specific. We also show that rapid evolution and likely loss of expression of miR168 isoforms in tobacco is related to the insertion of MITE-like transposons between miRNA and miRNA* sequences, a possible mechanism showing how miRNAs are lost in few plant lineages even though other close relatives have abundantly expressing miRNAs.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-1049) contains supplementary material, which is available to authorized users.