Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:During tetrapod limb development, the HOXA13 and HOXD13 transcription factors are critical for the emergence and organization of the autopods, the most distal aspect where digits will develop. Since previous work had suggested that the Dbx2 gene is a target of these factors, we set up to analyze in detail this potential regulatory interaction. We used a chromatin conformation capture approach (4Cseq) to characterize the regulatory domain and interactions of the transcription factor Dbx2 and of its neighboring genes Nell2 and Ano6 in distal and/ or proximal forelimbs of E12 mouse embryos. In particular, we analyzed their interaction with distal limb specific regulatory elements (DLE1 and DLE2) by the analysis of H2K27ac coverages (Beccari et al 2016) and Hoxa13/Hoxd13 binding (Sheth R et al 2016). We report that Dbx2, Nell2 and Ano6 are expressed in distal limb buds and are controlled by the same enhancers located close to Dbx2. As the Nell2 and Ano6 genes are localized into two different topologically associating domains (TADs) flanking the Dbx2 locus, we conclude that these enhancers can overcome TAD boundaries in either direction, to co-regulate a set of genes located in distinct chromatin domains.

Project description:During tetrapod limb development, the HOXA13 and HOXD13 transcription factors are critical for the emergence and organization of the autopods, the most distal aspect where digits will develop. Since previous work had suggested that the Dbx2 gene is a target of these factors, we set up to analyze in detail this potential regulatory interaction. We used a chromatin conformation capture approach (4Cseq) to characterize the regulatory domain and interactions of the transcription factor Dbx2 and of its neighboring genes Nell2 and Ano6 in distal and/ or proximal forelimbs of E12 mouse embryos. In particular, we analyzed their interaction with distal limb specific regulatory elements (DLE1 and DLE2) by the analysis of H2K27ac coverages (Beccari et al 2016) and Hoxa13/Hoxd13 binding (Sheth R et al 2016). We report that Dbx2, Nell2 and Ano6 are expressed in distal limb buds and are controlled by the same enhancers located close to Dbx2. As the Nell2 and Ano6 genes are localized into two different topologically associating domains (TADs) flanking the Dbx2 locus, we conclude that these enhancers can overcome TAD boundaries in either direction, to co-regulate a set of genes located in distinct chromatin domains.

Project description:During tetrapod limb development, the HOXA13 and HOXD13 transcription factors are critical for the emergence and organization of the autopods, the most distal aspect where digits will develop. Since previous work had suggested that the Dbx2 gene is a target of these factors, we set up to analyze in detail this potential regulatory interaction. We used a chromatin conformation capture approach (4Cseq) to characterize the regulatory domain and interactions of the transcription factor Dbx2 and of its neighboring genes Nell2 and Ano6 in distal and/ or proximal forelimbs of E12 mouse embryos. In particular, we analyzed their interaction with distal limb specific regulatory elements (DLE1 and DLE2) by the analysis of H2K27ac coverages (Beccari et al 2016) and Hoxa13/Hoxd13 binding (Sheth R et al 2016). We report that Dbx2, Nell2 and Ano6 are expressed in distal limb buds and are controlled by the same enhancers located close to Dbx2. As the Nell2 and Ano6 genes are localized into two different topologically associating domains (TADs) flanking the Dbx2 locus, we conclude that these enhancers can overcome TAD boundaries in either direction, to co-regulate a set of genes located in distinct chromatin domains.

Project description:DBX2 REGULATION IN LIMBS SUGGESTS INTER-TAD SHARING OF ENHANCERS

Project description:DBX2 REGULATION IN LIMBS SUGGESTS INTER-TAD SHARING OF ENHANCERS [4C-Seq]

Project description:The human genome encodes an order of magnitude more gene expression enhancers than promoters, suggesting that most genes are regulated by the combined action of multiple enhancers. We have previously shown that neighboring estrogen-responsive enhancers exhibit complex synergistic contributions to the production of an estrogenic transcriptional response. Here we sought to determine the molecular underpinnings of this enhancer cooperativity. We generated genetic deletions of four estrogen receptor ? (ER) bound enhancers that regulate two genes and found that enhancers containing full estrogen response element (ERE) motifs control ER binding at neighboring sites, while enhancers with pre-existing histone acetylation/accessibility confer a permissible chromatin environment to the neighboring enhancers. Genome engineering revealed that two enhancers with half EREs could not compensate for the lack of a full ERE site within the cluster. In contrast, two enhancers with full EREs produced a transcriptional response greater than the wild-type locus. By swapping genomic sequences, we found that the genomic location of a full ERE strongly influences enhancer activity. Our results lead to a model in which a full ERE is required for ER recruitment, but the presence of a pre-existing permissible chromatin environment can also be needed for estrogen-driven gene regulation to occur.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:The human genome encodes an order of magnitude more gene expression enhancers than promoters, suggesting that most genes are regulated by the combined action of multiple enhancers. We have previously shown that neighboring estrogen-responsive enhancers, which are approximately 5,000 basepairs apart, exhibit complex synergistic contributions to the production of an estrogenic transcriptional response. Here we sought to determine the molecular underpinnings of the observed enhancer cooperativity. We generated genetic deletions of individual estrogen receptor  (ER) bound enhancers and found that enhancers containing full estrogen response element (ERE) motifs control ER binding at neighboring sites, while enhancers with pre-existing histone acetylation/accessibility confer a permissible chromatin environment to the neighboring enhancers. Genome engineering revealed that a cluster of two enhancers with half EREs could not compensate for the lack of a full ERE site within the cluster. In contrast, two enhancers with full EREs produced a transcriptional response greater than the wild-type locus. By swapping genomic sequences between enhancers, we found that the genomic location in which a full ERE resides strongly influences enhancer activity. Our results lead to a model in which a full ERE is required for ER recruitment, but the presence of pre-existing histone acetylation within an enhancer cluster is also needed in order for estrogen-driven gene regulation to occur.

Project description:The human genome encodes an order of magnitude more gene expression enhancers than promoters, suggesting that most genes are regulated by the combined action of multiple enhancers. We have previously shown that neighboring estrogen-responsive enhancers, which are approximately 5,000 basepairs apart, exhibit complex synergistic contributions to the production of an estrogenic transcriptional response. Here we sought to determine the molecular underpinnings of the observed enhancer cooperativity. We generated genetic deletions of individual estrogen receptor  (ER) bound enhancers and found that enhancers containing full estrogen response element (ERE) motifs control ER binding at neighboring sites, while enhancers with pre-existing histone acetylation/accessibility confer a permissible chromatin environment to the neighboring enhancers. Genome engineering revealed that a cluster of two enhancers with half EREs could not compensate for the lack of a full ERE site within the cluster. In contrast, two enhancers with full EREs produced a transcriptional response greater than the wild-type locus. By swapping genomic sequences between enhancers, we found that the genomic location in which a full ERE resides strongly influences enhancer activity. Our results lead to a model in which a full ERE is required for ER recruitment, but the presence of pre-existing histone acetylation within an enhancer cluster is also needed in order for estrogen-driven gene regulation to occur.