Project description:Calcium Signaling Prompts NIPBL Recruitment at Active Enhancers and Promoters via Distinct Mechanisms to Reconstruct Genome Compartmentalization

Project description:The gene expression program is regulated by a cell-type specific chromosome architecture. The connection between enhancer and promoter regions is dependent on a protein complex containing Nipbl, Mediator and Cohesin. To gain insights into the chromosome architecture of human differentiated cells, we profiled NIPBL and SMC1 in lymphoblastoid cells (LCLs). DNA was enriched from hLCLs and chromatin immunoprecipitations (ChIPs) were analyzed by Solexa sequencing. ChIPs were performed using an antibody against NIPBL and SMC1. Whole cell extract is provided for background.

Project description:The gene expression program is regulated by a cell-type specific chromosome architecture. The connection between enhancer and promoter regions is dependent on a protein complex containing Nipbl, Mediator and Cohesin. To gain insights into the chromosome architecture of human differentiated cells, we profiled NIPBL and SMC1 in lymphoblastoid cells (LCLs).

Project description:Mutations in NIPBL are the major cause of Cornelia de Lange Syndrome (CdLS). NIPBL is the cohesin loading factor and has recently been associated with the BET (Bromodomains and Extra Terminal (ET) domain) proteins BRD2 and BRD4. Related to this, a CdLS-like phenotype has been described associated to BRD4 mutations. We have study the genomic occupancy of NIPBL in mouse P19 teratocarcinoma cells.

Project description:Dysplasia of cardiac endothelial cells significantly contributes to congenital heart disease (CHD), the most common congenital disability. The regulatory role of miRNAs in this process remains elusive. This study identified elevated miR-187 expression in embryonic heart endothelial cells from CHD fetuses. Using a conditional knock-in model, we showed that increased miR-187 levels in embryonic endothelial cells induce CHD in homozygous fetal mice, closely mirroring human CHD. Mechanistically, miR-187 targets NIPBL, which is responsible for recruiting the cohesin complex and facilitating chromatin accessibility between enhancers and promoters. Consequently, the endothelial cell-specific upregulation of miR-187 inhibited NIPBL, leading to reduced chromatin accessibility and impaired gene expression, which hindered endothelial cell development and ultimately caused heart septal defects and reduced heart size both in vitro and in vivo. Importantly, exogenous miR-187 expression in human cardiac organoids mimicked developmental defects in the cardiac endothelial cells, reversible by NIPBL replenishment. Our findings establish the miR-187/NIPBL axis as a potent regulator that inhibits cardiac endothelial cell development by attenuating the transcription of numerous endothelial genes, with our mouse and human cardiac organoid models effectively replicating severe defects from minor perturbations.

Project description:Dysplasia of cardiac endothelial cells significantly contributes to congenital heart disease (CHD), the most common congenital disability. The regulatory role of miRNAs in this process remains elusive. This study identified elevated miR-187 expression in embryonic heart endothelial cells from CHD fetuses. Using a conditional knock-in model, we showed that increased miR-187 levels in embryonic endothelial cells induce CHD in homozygous fetal mice, closely mirroring human CHD. Mechanistically, miR-187 targets NIPBL, which is responsible for recruiting the cohesin complex and facilitating chromatin accessibility between enhancers and promoters. Consequently, the endothelial cell-specific upregulation of miR-187 inhibited NIPBL, leading to reduced chromatin accessibility and impaired gene expression, which hindered endothelial cell development and ultimately caused heart septal defects and reduced heart size both in vitro and in vivo. Importantly, exogenous miR-187 expression in human cardiac organoids mimicked developmental defects in the cardiac endothelial cells, reversible by NIPBL replenishment. Our findings establish the miR-187/NIPBL axis as a potent regulator that inhibits cardiac endothelial cell development by attenuating the transcription of numerous endothelial genes, with our mouse and human cardiac organoid models effectively replicating severe defects from minor perturbations.

Project description:Dysplasia of cardiac endothelial cells significantly contributes to congenital heart disease (CHD), the most common congenital disability. The regulatory role of miRNAs in this process remains elusive. This study identified elevated miR-187 expression in embryonic heart endothelial cells from CHD fetuses. Using a conditional knock-in model, we showed that increased miR-187 levels in embryonic endothelial cells induce CHD in homozygous fetal mice, closely mirroring human CHD. Mechanistically, miR-187 targets NIPBL, which is responsible for recruiting the cohesin complex and facilitating chromatin accessibility between enhancers and promoters. Consequently, the endothelial cell-specific upregulation of miR-187 inhibited NIPBL, leading to reduced chromatin accessibility and impaired gene expression, which hindered endothelial cell development and ultimately caused heart septal defects and reduced heart size both in vitro and in vivo. Importantly, exogenous miR-187 expression in human cardiac organoids mimicked developmental defects in the cardiac endothelial cells, reversible by NIPBL replenishment. Our findings establish the miR-187/NIPBL axis as a potent regulator that inhibits cardiac endothelial cell development by attenuating the transcription of numerous endothelial genes, with our mouse and human cardiac organoid models effectively replicating severe defects from minor perturbations.

Project description:Genome occupancy of NIPBL in mouse P19 teratocarcinoma cells.

Project description:Dysplasia of cardiac endothelial cells significantly contributes to congenital heart disease (CHD), the most common congenital disability. The regulatory role of miRNAs in this process remains elusive. This study identified elevated miR-187 expression in embryonic heart endothelial cells from CHD fetuses. Using a conditional knock-in model, we showed that increased miR-187 levels in embryonic endothelial cells induce CHD in homozygous fetal mice, closely mirroring human CHD. Mechanistically, miR-187 targets NIPBL, which is responsible for recruiting the cohesin complex and facilitating chromatin accessibility between enhancers and promoters. Consequently, the endothelial cell-specific upregulation of miR-187 inhibited NIPBL, leading to reduced chromatin accessibility and impaired gene expression, which hindered endothelial cell development and ultimately caused heart septal defects and reduced heart size both in vitro and in vivo. Importantly, exogenous miR-187 expression in human cardiac organoids mimicked developmental defects in the cardiac endothelial cells, reversible by NIPBL replenishment. Our findings establish the miR-187/NIPBL axis as a potent regulator that inhibits cardiac endothelial cell development by attenuating the transcription of numerous endothelial genes, with our mouse and human cardiac organoid models effectively replicating severe defects from minor perturbations.

Project description:Dysplasia of cardiac endothelial cells significantly contributes to congenital heart disease (CHD), the most common congenital disability. The regulatory role of miRNAs in this process remains elusive. This study identified elevated miR-187 expression in embryonic heart endothelial cells from CHD fetuses. Using a conditional knock-in model, we showed that increased miR-187 levels in embryonic endothelial cells induce CHD in homozygous fetal mice, closely mirroring human CHD. Mechanistically, miR-187 targets NIPBL, which is responsible for recruiting the cohesin complex and facilitating chromatin accessibility between enhancers and promoters. Consequently, the endothelial cell-specific upregulation of miR-187 inhibited NIPBL, leading to reduced chromatin accessibility and impaired gene expression, which hindered endothelial cell development and ultimately caused heart septal defects and reduced heart size both in vitro and in vivo. Importantly, exogenous miR-187 expression in human cardiac organoids mimicked developmental defects in the cardiac endothelial cells, reversible by NIPBL replenishment. Our findings establish the miR-187/NIPBL axis as a potent regulator that inhibits cardiac endothelial cell development by attenuating the transcription of numerous endothelial genes, with our mouse and human cardiac organoid models effectively replicating severe defects from minor perturbations.