Project description:Organization of the genome in 3D nuclear-space is known to play a crucial role in regulation of gene expression. However, the chromatin architecture that impinges on the B cell-fate choice of multi-potent progenitors remains unclear. By employing in situ Hi-C, we have identified distinct sets of genomic loci that undergo a developmental switch between permissive and repressive compartments during B-cell fate commitment. Intriguingly, we show that topologically associating domains (TADs) represent co-regulated subunits of chromatin and display considerable structural alterations as a result of changes in the cis-regulatory interaction landscape. The extensive rewiring of cis-regulatory interactions is closely associated with differential gene expression programs. Further, we demonstrate the regulatory role of Ebf1 and its downstream factor, Pax5, in chromatin reorganization and transcription regulation. Together, our studies reveal that alterations in promoter and cis-regulatory interactions underlie changes in higher-order chromatin architecture, which in turn determines cell-identity and cell-type specific gene expression patterns.

Project description:Developmentally regulated higher-order chromatin interactions orchestrate B cell fate commitment

Project description:Spatiotemporal gene expression programs are orchestrated by transcriptional enhancers which interact with target-gene promoters to regulate gene expression. In this study, we identified cis regulatory modules (CRMs) within the Fmn1/Grem1 cis-regulatory landscape that participate in controlling spatiotemporal expression of Grem1. We generated different Grem1 alleles lacking either individual CRMs, combinations or entire enhancer clusters (EC1 and EC2) using CRISPR/Cas genome editing. To study potential interactions of these CRMs with the Grem1 promoter, we generated 4C-seq profiles of different alleles. Our analysis of 4C-seq shows that the overall structure of the Grem1 TAD is maintained in CRM2-/- and EC1-/- forelimb buds. Similar to EC1, the chromatin architecture of the Grem1 TAD is not disrupted outside the EC2 and EC1EC2 deletions. In all the genotypes, the contacts of the promoter with the remainder of the Grem1 TAD are rather increased. Thus, our results revealed that the spatio-temporal changes in Grem1 expression are caused by cis-regulatory alterations due to the deletions of EC1 and EC2 and not global changes in chromatin architecture.

Project description:Spatiotemporal gene expression programs are orchestrated by transcriptional enhancers which interact with target-gene promoters to regulate gene expression. The BMP antagonist Gremlin1 (Grem1) is an important node in the gene regulatory network that controls vertebrate limb development. In this study, we used a combination of open chromatin profiling (ATAC-seq) and chromatin immunoprecipitation sequencing (ChIP-seq) in mouse and chick to identify putative cis-regulatory modules (CRMs) that regulate Grem1 in limb buds. Using CRISPR/Cas genome editing we generated different Grem1 regulatory alleles lacking either individual CRMs, combinations or entire enhancer clusters. To study potential interactions of these CRMs with the Grem1 promoter, we generated 4C-seq profiles of specific regulatory alleles. Taken together our results revealed that the spatio-temporal changes in Grem1 expression are caused by cis-regulatory alterations due to the deletions of enhancer clusters rather than global changes in chromatin architecture.

Project description:Spatiotemporal gene expression programs are orchestrated by transcriptional enhancers which interact with target-gene promoters to regulate gene expression. The BMP antagonist Gremlin1 (Grem1) is an important node in the gene regulatory network that controls vertebrate limb development. In this study, we used a combination of open chromatin profiling (ATAC-seq) and chromatin immunoprecipitation sequencing (ChIP-seq) in mouse and chick to identify putative cis-regulatory modules (CRMs) that regulate Grem1 in limb buds. Using CRISPR/Cas genome editing we generated different Grem1 regulatory alleles lacking either individual CRMs, combinations or entire enhancer clusters. To study potential interactions of these CRMs with the Grem1 promoter, we generated 4C-seq profiles of specific regulatory alleles. Taken together our results revealed that the spatio-temporal changes in Grem1 expression are caused by cis-regulatory alterations due to the deletions of enhancer clusters rather than global changes in chromatin architecture.

Project description:Spatiotemporal gene expression programs are orchestrated by transcriptional enhancers which interact with target-gene promoters to regulate gene expression. The BMP antagonist Gremlin1 (Grem1) is an important node in the gene regulatory network that controls vertebrate limb development. In this study, we used a combination of open chromatin profiling (ATAC-seq) and chromatin immunoprecipitation sequencing (ChIP-seq) in mouse and chick to identify putative cis-regulatory modules (CRMs) that regulate Grem1 in limb buds. Using CRISPR/Cas genome editing we generated different Grem1 regulatory alleles lacking either individual CRMs, combinations or entire enhancer clusters. To study potential interactions of these CRMs with the Grem1 promoter, we generated 4C-seq profiles of specific regulatory alleles. Taken together our results revealed that the spatio-temporal changes in Grem1 expression are caused by cis-regulatory alterations due to the deletions of enhancer clusters rather than global changes in chromatin architecture.

Project description:Spatiotemporal gene expression programs are orchestrated by transcriptional enhancers which interact with target-gene promoters to regulate gene expression. The BMP antagonist Gremlin1 (Grem1) is an important node in the gene regulatory network that controls vertebrate limb development. In this study, we used a combination of open chromatin profiling (ATAC-seq) and chromatin immunoprecipitation sequencing (ChIP-seq) in mouse and chick to identify putative cis-regulatory modules (CRMs) that regulate Grem1 in limb buds. Using CRISPR/Cas genome editing we generated different Grem1 regulatory alleles lacking either individual CRMs, combinations or entire enhancer clusters. To study potential interactions of these CRMs with the Grem1 promoter, we generated 4C-seq profiles of specific regulatory alleles. Taken together our results revealed that the spatio-temporal changes in Grem1 expression are caused by cis-regulatory alterations due to the deletions of enhancer clusters rather than global changes in chromatin architecture.

Project description:Interactions between cis-regulatory elements such as promoters and enhancers are important for transcription but global identification of these interactions remains a major challenge. Leveraging the chromatin accessiblity of regulatory elements, we developed ARC-C (accessible region chromosome conformation capture), which profiles chromatin regulatory interactions genome-wide at high resolution. Applying ARC-C to C. elegans, we identify ~15,000 significant interactions at 500bp resolution. Regions bound by transcription factors and chromatin regulators such as cohesin and condensin II are enriched for interactions, and we use ARC-C to show that the BLMP-1 transcription factor mediates interactions between its targets. Investigating domain level architecture, we find that C. elegans chromatin domains defined by either active or repressive modifications form topologically associating domains (TADs) and that these domains interact to form A/B (active/inactive) compartment structure. ARC-C is a powerful new tool to interrogate genome architecture and regulatory interactions at high resolution.

Project description:Interactions between cis-regulatory elements such as promoters and enhancers are important for transcription but global identification of these interactions remains a major challenge. Leveraging the chromatin accessiblity of regulatory elements, we developed ARC-C (accessible region chromosome conformation capture), which profiles chromatin regulatory interactions genome-wide at high resolution. Applying ARC-C to C. elegans, we identify ~15,000 significant interactions at 500bp resolution. Regions bound by transcription factors and chromatin regulators such as cohesin and condensin II are enriched for interactions, and we use ARC-C to show that the BLMP-1 transcription factor mediates interactions between its targets. Investigating domain level architecture, we find that C. elegans chromatin domains defined by either active or repressive modifications form topologically associating domains (TADs) and that these domains interact to form A/B (active/inactive) compartment structure. ARC-C is a powerful new tool to interrogate genome architecture and regulatory interactions at high resolution.

Project description:Interactions between cis-regulatory elements such as promoters and enhancers are important for transcription but global identification of these interactions remains a major challenge. Leveraging the chromatin accessiblity of regulatory elements, we developed ARC-C (accessible region chromosome conformation capture), which profiles chromatin regulatory interactions genome-wide at high resolution. Applying ARC-C to C. elegans, we identify ~15,000 significant interactions at 500bp resolution. Regions bound by transcription factors and chromatin regulators such as cohesin and condensin II are enriched for interactions, and we use ARC-C to show that the BLMP-1 transcription factor mediates interactions between its targets. Investigating domain level architecture, we find that C. elegans chromatin domains defined by either active or repressive modifications form topologically associating domains (TADs) and that these domains interact to form A/B (active/inactive) compartment structure. ARC-C is a powerful new tool to interrogate genome architecture and regulatory interactions at high resolution.