Project description:Background: Transposable element 24 nucleotide small RNAs are not efficiently incorporated into the AGO1 protein, which is involved in endogenous RNAi and gene regulation through the microRNA and tasiRNA pathways. Results: The AGO1 protein incorporates large quantities of transposable element siRNAs when transposable elements are epigenetically activated and transcribed. The incorporation of transposable element siRNAs is at the expense of the most abundant microRNAs. These transposable element siRNAs can act as tasiRNAs, regulating genes that they have partial complementarity to. Conclusion: Transposable element small RNAs are more dynamic than previously thought. They can be incorporated into AGO1 and regulate genes. Three biological replicates of small RNA sequencing from two genotypes

Project description:Background: Transposable element 24 nucleotide small RNAs are not efficiently incorporated into the AGO1 protein, which is involved in endogenous RNAi and gene regulation through the microRNA and tasiRNA pathways. Results: The AGO1 protein incorporates large quantities of transposable element siRNAs when transposable elements are epigenetically activated and transcribed. The incorporation of transposable element siRNAs is at the expense of the most abundant microRNAs. These transposable element siRNAs can act as tasiRNAs, regulating genes that they have partial complementarity to. Conclusion: Transposable element small RNAs are more dynamic than previously thought. They can be incorporated into AGO1 and regulate genes.

Project description:Small RNA accumulation in Transposable Element-silent and Transposable Element-active epigenomes

Project description:This SuperSeries is composed of the following subset Series: GSE24571: Transposable elements and small RNAs contribute to gene expression divergence between Arabidopsis thaliana and Arabidopsis lyrata [RNA-Seq] GSE38109: Natural variation in Arabidopsis thaliana transcriptomes Refer to individual Series

Project description:In Arabidopsis thaliana, ARGONAUTE1 (AGO1) plays a central role[AQ1] in microRNA (miRNA) and small interfering RNA (siRNA)- mediated silencing and is a key component in antiviral responses. The polerovirus F-box P0 protein triggers AGO1 degradation as a viral counterdefense. Here, we identified a motif in AGO1 that is required for its interaction with the S phase kinase-associated protein1-cullin 1-F-box protein (SCF) P0 (SCFP0) complex and subsequent degradation. The AGO1 P0 degron is conserved and confers P0-mediated degradation to other AGO[AQ2] proteins. Interestingly, the degron motif is localized in the DUF1785 domain of AGO1, in which a single point mutation (ago1-57, obtained by forward genetic screening) compromises recognition by SCFP0. Recapitulating formation of the RNA-induced silencing complex in a cell-free system revealed that this mutation impairs RNA unwinding, leading to stalled forms of AGO1 still bound to double-stranded RNAs. In vivo, the DUF1785 is required for unwinding perfectly matched siRNA duplexes, but is mostly dispensable for unwinding imperfectly matched miRNA duplexes. Consequently, its mutation nearly abolishes phased siRNA production and sense transgene posttranscriptional gene silencing. Overall, our work sheds new light on the mode of AGO1 recognition by P0 and the in vivo function of DUF1785 in RNA silencing.

Project description:Background: The small RNAs that Transposable Elements generate are vastly different when they are transcriptionally silenced compared to when they are transcriptionally activated. We performed the deep sequencing of small RNAs in a number of small RNA biogenesis mutants in both Transposable Element-silenced and Transposable Element-active epigenome backgrounds. Results: We found that Transposable Elements generate large amounts of 21-22nt siRNAs only when they are transcriptionally active. These 21-22nt siRNAs are incorporated into the AGO6 protein. Conclusion: Ago6 is the key protein that bridges the post-transcriptional degradation of Transposable Element mRNAs and the establishment of DNA methylation. Examination of flower bud small RNAs from wild type and 5 single or double mutant combinations, many of which have biological replicates. In addition, IP purification of the AGO6 protein (and mock no-antigen controls) followed by sequencing of the incorporated small RNAs. Replicate A for Col and ddm1 are submitted in GSE41755

Project description:The Arabidopsis ARGONAUTE (AGO) protein AGO1 associates with microRNA (miRNA) and specific classes of short-interfering RNA (siRNA). AGO1-small RNA complexes recognize target RNA transcripts through base-pairing interactions and inhibit translation of target RNAs through endonucleolytic cleavage (slicing) or non-degradative mechanisms. The PIWI domain of AGO1 contains a metal-coordinating triad [Asp-Asp-His] (DDH) that is required for slicer activity. Here, we compared the activities of wild type (DDH) and slicer active-site defective (DAH) forms of AGO1 by sequencing small RNA and target transcript RNAs that co-immunoprecipitated with hemagglutinin (HA)-tagged AGO1 proteins. We found that the population of miRNA that associated with both AGO1-DDH and AGO1-DAH proteins largely overlapped, suggesting that cleavage activity does not affect miRNA maturation. In contrast, slicer-defective AGO1-miRNA complexes associated with target RNA more effectively than did wild type AGO1-miRNA. These data indicate that slicer-defective AGO proteins can be used as an approach to capture AGO-small RNA-target RNA ternary complexes more efficiently for genome-wide analyses.

Project description:The Arabidopsis ARGONAUTE (AGO) protein AGO1 associates with microRNA (miRNA) and specific classes of short-interfering RNA (siRNA). AGO1-small RNA complexes recognize target RNA transcripts through base-pairing interactions and inhibit translation of target RNAs through endonucleolytic cleavage (slicing) or non-degradative mechanisms. The PIWI domain of AGO1 contains a metal-coordinating triad [Asp-Asp-His] (DDH) that is required for slicer activity. Here, we compared the activities of wild type (DDH) and slicer active-site defective (DAH) forms of AGO1 by sequencing small RNA and target transcript RNAs that co-immunoprecipitated with hemagglutinin (HA)-tagged AGO1 proteins. We found that the population of miRNA that associated with both AGO1-DDH and AGO1-DAH proteins largely overlapped, suggesting that cleavage activity does not affect miRNA maturation. In contrast, slicer-defective AGO1-miRNA complexes associated with target RNA more effectively than did wild type AGO1-miRNA. These data indicate that slicer-defective AGO proteins can be used as an approach to capture AGO-small RNA-target RNA ternary complexes more efficiently for genome-wide analyses. AGO1-DDH (wild type) AGO1-DAH (slicer mutant) proteins were immunoprecipitated (N-terminal 3xHA) from Arabidopsis (Columbia) flower (stages 1-12) lysate. Immunoprecipitations were also done from control plants transformed with vector only. Small RNA from immunoprecipitate fractions of vector, AGO1-DDH and AGO1-DAH were sequenced.

Project description:Background: The small RNAs that Transposable Elements generate are vastly different when they are transcriptionally silenced compared to when they are transcriptionally activated. We performed the deep sequencing of small RNAs in a number of small RNA biogenesis mutants in both Transposable Element-silenced and Transposable Element-active epigenome backgrounds. Results: We found that Transposable Elements generate large amounts of 21-22nt siRNAs only when they are transcriptionally active. These 21-22nt siRNAs are incorporated into the AGO6 protein. Conclusion: Ago6 is the key protein that bridges the post-transcriptional degradation of Transposable Element mRNAs and the establishment of DNA methylation.

Project description:The Arabidopsis ARGONAUTE (AGO) protein AGO1 associates with microRNA (miRNA) and specific classes of short-interfering RNA (siRNA). AGO1-small RNA complexes recognize target RNA transcripts through base-pairing interactions and inhibit translation of target RNAs through endonucleolytic cleavage (slicing) or non-degradative mechanisms. The PIWI domain of AGO1 contains a metal-coordinating triad [Asp-Asp-His] (DDH) that is required for slicer activity. Here, we compared the activities of wild type (DDH) and slicer active-site defective (DAH) forms of AGO1 by sequencing small RNA and target transcript RNAs that co-immunoprecipitated with hemagglutinin (HA)-tagged AGO1 proteins. We found that the population of miRNA that associated with both AGO1-DDH and AGO1-DAH proteins largely overlapped, suggesting that cleavage activity does not affect miRNA maturation. In contrast, slicer-defective AGO1-miRNA complexes associated with target RNA more effectively than did wild type AGO1-miRNA. These data indicate that slicer-defective AGO proteins can be used as an approach to capture AGO-small RNA-target RNA ternary complexes more efficiently for genome-wide analyses.