Project description:The 5-methylcytosine DNA glycosylase/lyase REPRESSOR OF SILENCING 1 (ROS1)-mediated active DNA demethylation is critical for shaping the genomic DNA methylation landscape in Arabidopsis. Whether and how the stability of ROS1 may be regulated by post-translational modifications is unknown. Using a methylation-sensitive PCR (CHOP-PCR)-based forward genetic screen for Arabidopsis DNA hypermethylation mutants, we identified the SUMO E3 ligase SIZ1 as a critical regulator of active DNA demethylation. Dysfunction of SIZ1 leads to hyper-methylation at approximately one thousand genomic regions. SIZ1 physically interacts with ROS1 and mediates the SUMOylation of ROS1. The SUMOylation of ROS1 is reduced in siz1 mutant plants. Compared to that in wild type plants, the protein level of ROS1 is significantly decreased, even though there is an increased level of ROS1 transcripts in siz1 mutant plants. Our results suggest that SIZ1 positively regulates active DNA demethylation by promoting the stability of ROS1 protein through SUMOylation.

Project description:Using whole genome bisulfite sequencing to provide single-base resulution of DNA methylation status in rdm16ros1, ros1, nrpd1ros1 mutants and examine the effect of RDM16 on DNA methylation 4 samples examined: C24 wild type with RD29A-LUC transgene, rdm16ros1 double mutant, ros1 mutant, nrpd1ros1 mutant (all in C24 background with RD29A-LUC transgene)

Project description:DNA methylation is an important epigenetic modification involved in many biological processes, and active DNA demethylation plays critical roles in regulating expression of genes and anti-silencing of transgenes. In this study, we isolated mutations in one arabidopsis gene, ROS5, which causes the silencing of transgenic 35S-NPTII because of DNA hypermethylation, but no effect on transgenic RD29A-LUC. ROS5 encodes an atypical small heat shock protein. ROS5 can physically interact with IDM1 and is required for preventing DNA hypermethylation of some endogenous genes that are also regualated by IDM1 and ROS1. We propose that ROS5 may regulate active DNA demethylation by interacting with IDM1, thereby creating a friendly chromatin environment that facilitates the binding of ROS1 to erase DNA methylation.

Project description:Epigenetic regulation is important for organismal development and response to the environment. Alteration in epigenetic status has been known mostly from the perspective of enzymatic actions of DNA methylation and/or histone modifications. In a genetic screen for cellular factors involved in preventing epigenetic silencing, we isolated an Arabidopsis mutant defective in SAC3B, a component of the conserved TREX-2 complex that couples mRNA transcription with nuleo-cytoplasmic export. Arabidopsis SAC3B dysfunction causes gene silencing at transgenic and endogenous loci, accompanied by elevation in the repressive histone mark H3K9me2 and by reduction in RNA polymerase Pol II occupancy. SAC3B dysfunction does not alter promoter DNA methylation level of the transgene d35S::LUC, although the DNA demethylase ROS1 is also required for d35S::LUC anti-silencing. THP1 and NUA were identified as SAC3B-associated proteins whose mutations also caused d35S::LUC silencing. RNA-DNA hybrid exists at the repressed loci but is unrelated to gene suppression by the sac3b mutation. Genomewide analyses demonstrated minor but clear involvement of SAC3B in regulating siRNAs and DNA methylation, particularly at a group of TAS and TAS-like loci. Together our results revealed not only a critical role of mRNA-export factors in transcriptional anti-silencing but also the contribution of SAC3B in shaping plant epigenetic landscapes.

Project description:HDA6 is a RPD3-like histone deacetylase. In Arabidopsis, it mediates transgene and some endogenous target transcriptional gene silencing (TGS) via histone deacetylation and DNA methylation. Here, we characterized two hda6 mutant alleles that were recovered as second-site suppressors of the DNA demethylation mutant ros1-1. Although both alleles derepressed 35S::NPTII and RD29A::LUC in the ros1-1 background, they had distinct effects on the expression of these two transgenes. In accordance to expression profiles of two transgenes, the alleles have distinct opposite methylation profiles on two reporter gene promoters. Furthermore, both alleles could interact in vitro and in vivo with the DNA methyltransferase1 with differential interactive strength and patterns. Although these alleles accumulated different levels of repressive/active histone marks, DNA methylation but not histone modifications in the two transgene promoters was found to correlate with the level of derepression of the reporter genes between the two had6 alleles. Our study reveals that mutations in different domains of HDA6 convey different epigenetic status that in turn controls the expression of the transgenes as well as some endogenous loci.

Project description:Active DNA demethylation is an important epigenetic phenomenon in many eukaryotes. In Arabidopsis thaliana, ROS1, a 5-methylcytosine DNA glycosylase, is responsible for active DNA demethylation via a base excision repair process. Here, we found that Bromodomain and ATPase domain-containing protein 1 (BRAT1) associates with BRP1 (BRAT1 Partner 1) and forms a tight BRAT1–BRP1 complex required for DNA demethylation. To identify hypermethylated loci at the whole-genome level in brat1, brp1, and ros1, we performed whole-genome bisulfite sequencing. Compare the DNA methylation profiles of 10-day old seedlings materials of mutants (brat1, brp1, and ros1) to wild type by whole-genome bisulfite sequencing.

Project description:Arabidopsis ROS1 is the first genetically characterized DNA demethylase in eukaryotes. Dysfunction of ROS1 leads to increase in DNA methylation level at thousands of genomic loci. However, the features of ROS1 targets are not well understood. In this study, we identified and characterized ROS1 target loci in Arabidopsis Col-0 and C24 ecotypes. Most ROS1 targets are transposable elements (TEs) and intergenic regions. Compared to other TEs, ROS1-targeted TEs are closer to protein coding genes, suggesting a role for ROS1 in preventing the spreading of DNA methylation from highly methylated TEs to nearby genes. Interestingly, we found that unlike general TEs, ROS1 targets are associated with an enrichment of H3K18ac and H3K27me3, and depletion of H3K27me and H3K9me2. We investigated the antagonism between ROS1 and RNA-directed DNA methylation (RdDM) by identifying and characterizing thousands of genomic regions regulated by both ROS1 and RdDM. Unexpectedly, we uncovered thousands of previously unidentified RdDM targets by analyzing the DNA methylome of ros1/nrpd1 double mutant plants. In addition, we show that ROS1 also antagonizes RdDM-independent DNA methylation at more than a thousand genomic loci. Our results provide significant insights into the genome-wide effects of both ROS1-mediated active DNA demethylation and RNA-directed DNA methylation as well as their interaction in plants. Using small RNA-Seq(sRNA-Seq) to get small RNA profiling of WT, ros1-4, nrpd1 single mutants and ros1-4/nrpd1doubble mutant

Project description:DNA methylation is a chromatin modification that is associated with gene silencing in eukaryotic organisms. Although pathways controlling the establishment, maintenance and removal of DNA methylation have been identified, relatively little is understood about how DNA methylation influences gene expression. Using complementary genetic and biochemical approaches we identified a protein complex that antagonizes the transcriptional gene silencing of two LUCIFERASE (LUC) reporters in a manner that requires DNA methylation. At its core, this complex contains LOW IN LUCIFERASE EXPRESSION (LIL), an α-crystallin domain protein, and METHYL-CpG-BINDING DOMAIN 7 (MBD7), a protein previously associated with DNA methylation. At the LUC reporters, loss of MBD7 or LIL resulted in decreased LUC expression concomitant with modest, but reproducible increases in DNA methylation that can be phenocopied by DNA demethylase mutants. These findings are consistent with other reports and reveal a genetic connection between MBD7, LIL and DNA demethylation. However, we found that the hyper-methylation and gene expression phenotypes at a LUC reporter can be genetically uncoupled, demonstrating that changes in DNA methylation alone are not sufficient to silence LUC expression, and suggesting a role for the MBD7-LIL complex downstream of DNA methylation. Consistent with this hypothesis, our more extensive analysis of DNA methylation in mbd7 and lil mutants revealed only a small number of hyper-methylated loci genome wide. Furthermore, these loci displayed minimal overlap with demethylase targets, suggesting that, in general, the DNA demethylation machinery does not function in a manner dependent on the MBD7-LIL complex. Taken together, our findings place the MBD7-LIL complex amongst a small number of factors that regulate gene expression without causing significant changes in DNA methylation. This complex, however, is unique in that it functions to suppress, rather than enforce the silencing effects of DNA methylation, enabling gene expression of several transgene reporters despite high levels of promoter methylation.

Project description:DNA methylation is a chromatin modification that is associated with gene silencing in eukaryotic organisms. Although pathways controlling the establishment, maintenance and removal of DNA methylation have been identified, relatively little is understood about how DNA methylation influences gene expression. Using complementary genetic and biochemical approaches we identified a protein complex that antagonizes the transcriptional gene silencing of two LUCIFERASE (LUC) reporters in a manner that requires DNA methylation. At its core, this complex contains LOW IN LUCIFERASE EXPRESSION (LIL), an α-crystallin domain protein, and METHYL-CpG-BINDING DOMAIN 7 (MBD7), a protein previously associated with DNA methylation. At the LUC reporters, loss of MBD7 or LIL resulted in decreased LUC expression concomitant with modest, but reproducible increases in DNA methylation that can be phenocopied by DNA demethylase mutants. These findings are consistent with other reports and reveal a genetic connection between MBD7, LIL and DNA demethylation. However, we found that the hyper-methylation and gene expression phenotypes at a LUC reporter can be genetically uncoupled, demonstrating that changes in DNA methylation alone are not sufficient to silence LUC expression, and suggesting a role for the MBD7-LIL complex downstream of DNA methylation. Consistent with this hypothesis, our more extensive analysis of DNA methylation in mbd7 and lil mutants revealed only a small number of hyper-methylated loci genome wide. Furthermore, these loci displayed minimal overlap with demethylase targets, suggesting that, in general, the DNA demethylation machinery does not function in a manner dependent on the MBD7-LIL complex. Taken together, our findings place the MBD7-LIL complex amongst a small number of factors that regulate gene expression without causing significant changes in DNA methylation. This complex, however, is unique in that it functions to suppress, rather than enforce the silencing effects of DNA methylation, enabling gene expression of several transgene reporters despite high levels of promoter methylation.

Project description:DNA methylation is a chromatin modification that is associated with gene silencing in eukaryotic organisms. Although pathways controlling the establishment, maintenance and removal of DNA methylation have been identified, relatively little is understood about how DNA methylation influences gene expression. Using complementary genetic and biochemical approaches we identified a protein complex that antagonizes the transcriptional gene silencing of two LUCIFERASE (LUC) reporters in a manner that requires DNA methylation. At its core, this complex contains LOW IN LUCIFERASE EXPRESSION (LIL), an α-crystallin domain protein, and METHYL-CpG-BINDING DOMAIN 7 (MBD7), a protein previously associated with DNA methylation. At the LUC reporters, loss of MBD7 or LIL resulted in decreased LUC expression concomitant with modest, but reproducible increases in DNA methylation that can be phenocopied by DNA demethylase mutants. These findings are consistent with other reports and reveal a genetic connection between MBD7, LIL and DNA demethylation. However, we found that the hyper-methylation and gene expression phenotypes at a LUC reporter can be genetically uncoupled, demonstrating that changes in DNA methylation alone are not sufficient to silence LUC expression, and suggesting a role for the MBD7-LIL complex downstream of DNA methylation. Consistent with this hypothesis, our more extensive analysis of DNA methylation in mbd7 and lil mutants revealed only a small number of hyper-methylated loci genome wide. Furthermore, these loci displayed minimal overlap with demethylase targets, suggesting that, in general, the DNA demethylation machinery does not function in a manner dependent on the MBD7-LIL complex. Taken together, our findings place the MBD7-LIL complex amongst a small number of factors that regulate gene expression without causing significant changes in DNA methylation. This complex, however, is unique in that it functions to suppress, rather than enforce the silencing effects of DNA methylation, enabling gene expression of several transgene reporters despite high levels of promoter methylation.