Project description:DNA methylation is a mechanism of epigenetic gene regulation and genome defense conserved in many eukaryotic organisms. In Arabidopsis, the DNA methyltransferase DRM2 controls RNA-directed DNA methylation in a pathway that also involves the plant specific RNA Polymerase V (Pol V). The Arabidopsis genome also encodes an evolutionarily conserved but catalytically inactive DNA methyltransferase DRM3. Here, we show that DRM3 has moderate effects on global RNA-directed DNA methylation and small RNA abundance throughout the genome, and DRM3 protein physically interacts with Pol V. In drm3 mutants, we observe a lower level of Pol V-dependent transcripts, even though Pol V chromatin occupancy is increased at many sites in the genome. These findings suggest that DRM3 acts to promote Pol V transcriptional elongation or assist in the stabilization of Pol V transcripts, and shed further light on the mechanism of RNA-directed DNA methylation.

Project description:The plant-specific DNA-dependent RNA polymerase V (Pol V) evolved from Pol II to function in an RNA-directed DNA methylation pathway. Here, we have identified targets of Pol V in Arabidopsis thaliana on a genome-wide scale using ChIP-seq of NRPE1, the largest catalytic subunit of Pol V. We found that Pol V is enriched at promoters and evolutionarily recent transposons. This localization pattern is highly correlated with Pol V-dependent DNA methylation and small RNA accumulation. We also show that genome-wide association of Pol V with chromatin is dependent on all members of a putative chromatin-remodeling complex termed DDR. Our study presents the first genome-wide view of Pol V occupancy and sheds light on the mechanistic basis of Pol V localization. Furthermore, these findings suggest a role for Pol V and RNA-directed DNA methylation in genome surveillance and in responding to genome evolution.

Project description:Foreign DNA is silenced in plants by small RNA-directed DNA methylation (RdDM). RNA Polymerase V (Pol V) is the key protein required to recruit DNA methyltransferases to a RdDM target region. However, the mechanism required for the initial recruitment of Pol V to a targeted locus remains a mystery. In this study, we used first generation (T1) transgene transformations to elucidate a novel mechanism by which Pol V is recruited to both new transgenic and endogenous loci. This study is heavily dependent on analyzing the DNA methylation pattern and small RNAs produced from specific loci. All small RNA sequences (sRNA-seq) and bisulfite converted amplicon sequencing data (BSAS) used in this study are submitted as part of this data series.

Project description:Foreign DNA is silenced in plants by small RNA-directed DNA methylation (RdDM). RNA Polymerase V (Pol V) is the key protein required to recruit DNA methyltransferases to a RdDM target region. However, the mechanism required for the initial recruitment of Pol V to a targeted locus remains a mystery. In this study, we used first generation (T1) transgene transformations to elucidate a novel mechanism by which Pol V is recruited to both new transgenic and endogenous loci. This study is heavily dependent on analyzing the DNA methylation pattern and small RNAs produced from specific loci. All small RNA sequences (sRNA-seq) and bisulfite converted amplicon sequencing data (BSAS) used in this study are submitted as part of this data series.

Project description:The plant-specific DNA-dependent RNA polymerase V (Pol V) evolved from Pol II to function in an RNA-directed DNA methylation pathway. Here, we have identified targets of Pol V in Arabidopsis thaliana on a genome-wide scale using ChIP-seq of NRPE1, the largest catalytic subunit of Pol V. We found that Pol V is enriched at promoters and evolutionarily recent transposons. This localization pattern is highly correlated with Pol V-dependent DNA methylation and small RNA accumulation. We also show that genome-wide association of Pol V with chromatin is dependent on all members of a putative chromatin-remodeling complex termed DDR. Our study presents the first genome-wide view of Pol V occupancy and sheds light on the mechanistic basis of Pol V localization. Furthermore, these findings suggest a role for Pol V and RNA-directed DNA methylation in genome surveillance and in responding to genome evolution. For wild type plants (ecotype Columbia) and nrpe1 mutants whole-genome small RNA (sRNA-seq) and bisulfite sequencing (BS-seq) was performed. In addition whole genome chromatin immunoprecipitation (ChIP-seq) was performed on wild type (ecotype Columbia) plants as a negative control with experimentals consiting of wild type plants carrying a C-terminally epitope tagged (2XFLAG) NRPE1, as well as the NRPE1-FLAG construct in drd1, dms3, and rdm1 mutant backgrounds.

Project description:DNA methylation is a mechanism of epigenetic gene regulation and genome defense conserved in many eukaryotic organisms. In Arabidopsis, the DNA methyltransferase DRM2 controls RNA-directed DNA methylation in a pathway that also involves the plant specific RNA Polymerase V (Pol V). The Arabidopsis genome also encodes an evolutionarily conserved but catalytically inactive DNA methyltransferase DRM3. Here, we show that DRM3 has moderate effects on global RNA-directed DNA methylation and small RNA abundance throughout the genome, and DRM3 protein physically interacts with Pol V. In drm3 mutants, we observe a lower level of Pol V-dependent transcripts, even though Pol V chromatin occupancy is increased at many sites in the genome. These findings suggest that DRM3 acts to promote Pol V transcriptional elongation or assist in the stabilization of Pol V transcripts, and shed further light on the mechanism of RNA-directed DNA methylation. For wildtype plants as well as drm3, drm2, and nrpe1 mutants ChIP-seq was carried out using an endogenous NRPE1 antibody given to us by the Craig Pikaard lab. Two biological replicates of ChIP-seq were also carried out using anti-Flag resin on wildtype and drm3 plants carrying a Flag epitope tagged version of NRPE1. Small RNA sequencing was carried out on Col, drm3, drm2, and nrpe1 plants. Finally, whole-genome bisulfite sequencing analysis was carried out on previously published datasets (as detailed below) which were realigned using a newer genome version and mapping protocol. As such the updated processed files are part of this submission. Please note that the drm2, drm3, and nrpe1 mutant libraries used in this study were previously published (GSE39901), as were the 2 other Col replicates used (GSE36129) as below and thus duplicated sample records were created for the convenient retrieval of the complete raw data from SRA; Bisulfite_seq-Col_1 - GSM881756 Bisulfite_seq-Col_2 - GSM1193638 Bisulfite_seq-drm3 - GSM981017 Bisulfite_seq-drm2 - GSM981015 Bisulfite_seq-nrpe1- GSM981040

Project description:Eukaryotic DNA methylation is found in silent transposable elements and active genes. Nucleosome remodelers of the DDM1/Lsh family are thought to be specifically required to maintain transposon methylation, but the reason for this is unknown. Here, we find that a chromatin gradient that extends from the most heterochromatic transposons to euchromatic genes determines the requirement of DDM1 for methylation maintenance in all sequence contexts. We also show that small RNA-directed DNA methylation (RdDM) is inhibited by heterochromatin and absolutely requires the nucleosome remodeler DRD1. DDM1 and RdDM independently mediate nearly all transposon methylation, which is catalyzed by the methyltransferases MET1 (CG), CMT3 (CHG), DRM2 (CHH) and CMT2 (CHH), and collaborate to repress transposition and regulate the methylation and expression of genes. Our results indicate that the Arabidopsis genome is defined by a heterochromatic continuum that governs the access of DNA methyltransferases and potentially all DNA binding proteins. Examination of DNA methylation, transcription and nucleosomes in Arabidopsis wild-type and/or ddm1, RdDM and DNA methylase mutants.

Project description:FVE promotes RNA-directed DNA methylation by facilitating the association of RNA polymerase V with chromatin

Project description:Small RNAs target their complementary chromatin regions for gene silencing through nascent long non-coding RNAs (lncRNAs). In programmed DNA elimination of the ciliated protozoan Tetrahymena, the interaction between Piwi-associated small RNA (scnRNAs) and the lncRNA transcripts from the somatic genome has been proposed to induce target-directed scnRNA degradation (TDSD) and scnRNAs not targeted for TDSD later target the germline-limited sequences for DNA elimination. In this study, we show that the SUMO E3 ligase Ema2 is required for the accumulation of lncRNAs from somatic genome, and thus for TDSD and completing DNA elimination to make viable sexual progeny. Ema2 interacts with the SUMO E2 conjugating enzyme Ubc9 and enhances SUMOylation of the transcription regulator Spt6. We further show that Ema2 promotes the association of Spt6 and RNA polymerase II to chromatin. These results suggest that Ema2-directed SUMOylation actively promotes the lncRNA transcription that is a prerequisite for communication between the genome and small RNAs.

Project description:Non-coding transcription is an important determinant of heterochromatin formation. In Arabidopsis thaliana a specialized RNA polymerase V (Pol V) transcribes pervasively and produces long non-coding RNA. This facilitates locus-specific establishment of RNA-directed DNA methylation (RdDM). Subsequent maintenance of RdDM is associated with elevated levels of Pol V transcription, which is consistent with a mutual reinforcement of DNA methylation and non-coding transcription. However, the impact of DNA methylation on Pol V transcription remained unresolved. We found that loss of DNA methylation leads to a strong reduction of Pol V transcription. This occurs when DNA methylation is lost in all sequence contexts, which may happen not only in mutants defective in RdDM but also in mutants lacking maintenance DNA methyltransferases. Our results support a model where RdDM is maintained by a mutual reinforcement of DNA methylation and Pol V transcription with a strong crosstalk with other silencing pathways.