Project description:Arabidopsis PICKLE (PKL) is a putative CHD3-type chromatin remodeling factor. Despite its importance in environmental stimulus responses and plant development, how PKL is recruited to target gene loci and its detailed regulatory role in controlling target gene chromatin states is not fully understood. Here, we report genome-wide evidence for the recruitment of PKL by specific transcription factors, establish the molecular connection between PKL and H3K4me2/3, and demonstrate PKL is essential for the space-clustering distribution of its target genes. We captured the genome-wide binding sites of PKL by ChIP-seq using endogenous antibody. Further analyses gave evidence that plant-specific transcriptional factors containing TCPs, PIFs, and HY5, play dominant role in recruiting PKL to its target gene loci in Arabidopsis thaliana. The chromatin of PKL target genes showed significantly enriched depositions of H3K4me2 and H3K4me3. PKL directly interacted with the COMPASS complex scaffold protein WDR5A. It seems that PKL acts through WDR5A to stabilize the highly accumulated levels of H3K4me2 at specific euchromatic loci. Strikingly, PKL-bound genes distributed space-contiguously, the manner of which is dependent on PKL and PKL-interacted TFs. Moreover, the working model of PKL we proposed in this study is likely conserved in liverwort and rice. PKL associates with specific gene loci by interacting with specific transcription factors and promotes H3K4me2 depositions locally. Meanwhile, PKL acts as a hub mediating its target gene loci spatial-aggregation. PKL and its homologs in rice and liverwort might display similar molecular functions

Project description:Arabidopsis PICKLE (PKL) is a putative CHD3-type chromatin remodeling factor. Despite its importance in environmental stimulus responses and plant development, how PKL is recruited to target gene loci and its detailed regulatory role in controlling target gene chromatin states is not fully understood. Here, we report genome-wide evidence for the recruitment of PKL by specific transcription factors, establish the molecular connection between PKL and H3K4me2/3, and demonstrate PKL is essential for the space-clustering distribution of its target genes. We captured the genome-wide binding sites of PKL by ChIP-seq using endogenous antibody. Further analyses gave evidence that plant-specific transcriptional factors containing TCPs, PIFs, and HY5, play dominant role in recruiting PKL to its target gene loci in Arabidopsis thaliana. The chromatin of PKL target genes showed significantly enriched depositions of H3K4me2 and H3K4me3. PKL directly interacted with the COMPASS complex scaffold protein WDR5A. It seems that PKL acts through WDR5A to stabilize the highly accumulated levels of H3K4me2 at specific euchromatic loci. Strikingly, PKL-bound genes distributed space-contiguously, the manner of which is dependent on PKL and PKL-interacted TFs. Moreover, the working model of PKL we proposed in this study is likely conserved in liverwort and rice. PKL associates with specific gene loci by interacting with specific transcription factors and promotes H3K4me2 depositions locally. Meanwhile, PKL acts as a hub mediating its target gene loci spatial-aggregation. PKL and its homologs in rice and liverwort might display similar molecular functions

Project description:Arabidopsis PICKLE (PKL) is a putative CHD3-type chromatin remodeling factor. Despite its importance in environmental stimulus responses and plant development, how PKL is recruited to target gene loci and its detailed regulatory role in controlling target gene chromatin states is not fully understood. Here, we report genome-wide evidence for the recruitment of PKL by specific transcription factors, establish the molecular connection between PKL and H3K4me2/3, and demonstrate PKL is essential for the space-clustering distribution of its target genes. We captured the genome-wide binding sites of PKL by ChIP-seq using endogenous antibody. Further analyses gave evidence that plant-specific transcriptional factors containing TCPs, PIFs, and HY5, play dominant role in recruiting PKL to its target gene loci in Arabidopsis thaliana. The chromatin of PKL target genes showed significantly enriched depositions of H3K4me2 and H3K4me3. PKL directly interacted with the COMPASS complex scaffold protein WDR5A. It seems that PKL acts through WDR5A to stabilize the highly accumulated levels of H3K4me2 at specific euchromatic loci. Strikingly, PKL-bound genes distributed space-contiguously, the manner of which is dependent on PKL and PKL-interacted TFs. Moreover, the working model of PKL we proposed in this study is likely conserved in liverwort and rice. PKL associates with specific gene loci by interacting with specific transcription factors and promotes H3K4me2 depositions locally. Meanwhile, PKL acts as a hub mediating its target gene loci spatial-aggregation. PKL and its homologs in rice and liverwort might display similar molecular functions

Project description:Arabidopsis PICKLE (PKL) is a putative CHD3-type chromatin remodeling factor. Despite its importance in environmental stimulus responses and plant development, how PKL is recruited to target gene loci and its detailed regulatory role in controlling target gene chromatin states is not fully understood. Here, we report genome-wide evidence for the recruitment of PKL by specific transcription factors, establish the molecular connection between PKL and H3K4me2/3, and demonstrate PKL is essential for the space-clustering distribution of its target genes. We captured the genome-wide binding sites of PKL by ChIP-seq using endogenous antibody. Further analyses gave evidence that plant-specific transcriptional factors containing TCPs, PIFs, and HY5, play dominant role in recruiting PKL to its target gene loci in Arabidopsis thaliana. The chromatin of PKL target genes showed significantly enriched depositions of H3K4me2 and H3K4me3. PKL directly interacted with the COMPASS complex scaffold protein WDR5A. It seems that PKL acts through WDR5A to stabilize the highly accumulated levels of H3K4me2 at specific euchromatic loci. Strikingly, PKL-bound genes distributed space-contiguously, the manner of which is dependent on PKL and PKL-interacted TFs. Moreover, the working model of PKL we proposed in this study is likely conserved in liverwort and rice. PKL associates with specific gene loci by interacting with specific transcription factors and promotes H3K4me2 depositions locally. Meanwhile, PKL acts as a hub mediating its target gene loci spatial-aggregation. PKL and its homologs in rice and liverwort might display similar molecular functions

Project description:The master transcriptional repressor DREAM (dimerization partner, RB-like, E2F and multi-vulval class B) complex regulates cell cycle in eukaryotes, but much remains unknown about how it transmits repressive signals on chromatin to the primary transcriptional machinery (e.g., Pol II). Through a genetic screen, we identified BTE1 (barrier of transcription elongation 1), a key component in the plant DREAM complex. The subsequent characterization demonstrated that the DREAM complex represses Pol II elongation. The core DREAM subunits E2F transcription factors recruit BTE1 to accumulate at the promoter-proximal regions of target genes. DREAM target genes exhibit characteristic enrichment of H2A.Z and H3K4me2 modification on chromatin. The DREAM complex BTE1 subunit interacts with WDR5a, repressing WDR5a chromatin binding and the productive elongation of transcription on BTE1-targeted genomic loci. Thus, we demonstrate a major role of DREAM complex in the control of transition from transcription initiation to productive elongation around TSSs on the open chromatin via inhibiting WDR5a function.

Project description:The master transcriptional repressor DREAM (dimerization partner, RB-like, E2F and multi-vulval class B) complex regulates cell cycle in eukaryotes, but much remains unknown about how it transmits repressive signals on chromatin to the primary transcriptional machinery (e.g., Pol II). Through a genetic screen, we identified BTE1 (barrier of transcription elongation 1), a key component in the plant DREAM complex. The subsequent characterization demonstrated that the DREAM complex represses Pol II elongation. The core DREAM subunits E2F transcription factors recruit BTE1 to accumulate at the promoter-proximal regions of target genes. DREAM target genes exhibit characteristic enrichment of H2A.Z and H3K4me2 modification on chromatin. The DREAM complex BTE1 subunit interacts with WDR5a, repressing WDR5a chromatin binding and the productive elongation of transcription on BTE1-targeted genomic loci. Thus, we demonstrate a major role of DREAM complex in the control of transition from transcription initiation to productive elongation around TSSs on the open chromatin via inhibiting WDR5a function.

Project description:The master transcriptional repressor DREAM (dimerization partner, RB-like, E2F and multi-vulval class B) complex regulates cell cycle in eukaryotes, but much remains unknown about how it transmits repressive signals on chromatin to the primary transcriptional machinery (e.g., Pol II). Through a genetic screen, we identified BTE1 (barrier of transcription elongation 1), a key component in the plant DREAM complex. The subsequent characterization demonstrated that the DREAM complex represses Pol II elongation. The core DREAM subunits E2F transcription factors recruit BTE1 to accumulate at the promoter-proximal regions of target genes. DREAM target genes exhibit characteristic enrichment of H2A.Z and H3K4me2 modification on chromatin. The DREAM complex BTE1 subunit interacts with WDR5a, repressing WDR5a chromatin binding and the productive elongation of transcription on BTE1-targeted genomic loci. Thus, we demonstrate a major role of DREAM complex in the control of transition from transcription initiation to productive elongation around TSSs on the open chromatin via inhibiting WDR5a function.

Project description:CHD3 proteins are ATP-dependent chromatin remodeling factors that are components of diverse multisubunit complexes that can either repress or activate gene expression. In plants, the CHD3 protein PICKLE (PKL) is necessary for repression of seed-specific genes during germination and promotes deposition of the repressive epigenetic mark trimethylation of histone H3 lysine 27 (H3K27me3). It is unknown, however, if PKL acts directly at H3K27me3-enriched loci. We undertook a microarray analysis of 14-day-old plants and found that PKL continues to play an important role in expression of H3K27me3-enriched genes and in specification of developmental identity after germination. We used microarray to identify genes that are differentialy expressed in 14-day-old pkl seedlings and used chormatin immunoprecipitation to identify genes that are the direct targets of PKL. Wild-type (Col-0) and pkl-1 seedlings were grown on 1/2 MS plates with constant light and harvsted after 14-day growth. Three biological replicates.

Project description:Background: The chromodomain helicase DNA-binding family of ATP-dependent chromatin remodeling factors play essential roles during eukaryote growth and development. They are recruited by specific transcription factors and regulate the expression of developmentally important genes. Here, we describe an unexpected role in noncoding RNA-directed DNA methylation in Arabidopsis thaliana. Results: Through forward genetic screens we identified PKL, a gene required for developmental regulation in plants, as a factor promoting transcriptional silencing at the transgenic RD29A promoter. Mutation of PKL results in DNA methylation changes at more than half of the loci that are targeted by RNA-directed DNA methylation (RdDM). A small number of transposable elements and genes had reduced DNA methylation correlated with derepression in the pkl mutant, though for the majority, decreases in DNA methylation are not sufficient to cause release of silencing. The changes in DNA methylation in the pkl mutant are positively correlated with changes in 24-nt siRNA levels. In addition, PKL is required for the accumulation of Pol V-dependent transcripts and for the positioning of Pol V-stabilized nucleosomes at several tested loci, indicating that RNA polymerase V-related functions are impaired in the pkl mutant. Conclusions: PKL is required for transcriptional silencing and has significant effects on RdDM in plants. The changes in DNA methylation in the pkl mutant are correlated with changes in the noncoding RNAs produced by Pol IV and Pol V. We propose that at RdDM target regions, PKL may be required to create a chromatin environment that influences noncoding RNA production, DNA methylation and transcriptional silencing.

Project description:Background: The chromodomain helicase DNA-binding family of ATP-dependent chromatin remodeling factors play essential roles during eukaryote growth and development. They are recruited by specific transcription factors and regulate the expression of developmentally important genes. Here, we describe an unexpected role in noncoding RNA-directed DNA methylation in Arabidopsis thaliana. Results: Through forward genetic screens we identified PKL, a gene required for developmental regulation in plants, as a factor promoting transcriptional silencing at the transgenic RD29A promoter. Mutation of PKL results in DNA methylation changes at more than half of the loci that are targeted by RNA-directed DNA methylation (RdDM). A small number of transposable elements and genes had reduced DNA methylation correlated with derepression in the pkl mutant, though for the majority, decreases in DNA methylation are not sufficient to cause release of silencing. The changes in DNA methylation in the pkl mutant are positively correlated with changes in 24-nt siRNA levels. In addition, PKL is required for the accumulation of Pol V-dependent transcripts and for the positioning of Pol V-stabilized nucleosomes at several tested loci, indicating that RNA polymerase V-related functions are impaired in the pkl mutant. Conclusions: PKL is required for transcriptional silencing and has significant effects on RdDM in plants. The changes in DNA methylation in the pkl mutant are correlated with changes in the noncoding RNAs produced by Pol IV and Pol V. We propose that at RdDM target regions, PKL may be required to create a chromatin environment that influences noncoding RNA production, DNA methylation and transcriptional silencing.