Project description:Dosage-sensitive transcription factors (TFs) underlie altered gene regulation in congenital heart disease (CHD), and cell-type specific gene regulation is linked to the reorganization of 3D chromatin during cellular differentiation. Here, we show dose-dependent regulation of chromatin organization by the congenital heart disease (CHD)-linked, lineage-restricted TF TBX5 in human cardiomyocyte differentiation. Genome organization, including compartments, topologically associated domains, and chromatin loops, are sensitive to reduced TBX5 dosage in a human model of CHD, with variations in response across individual cells. Regions normally bound by TBX5 were especially sensitive, while co-occupancy with CTCF partially protected TBX5-bound TAD boundaries and loop anchors. These results highlight the importance of lineage-restricted TF dosage in cell-type specific 3D chromatin dynamics, suggesting a new mechanism for TF-dependent disease.

Project description:Dosage-sensitive transcription factors (TFs) underlie altered gene regulation in congenital heart disease (CHD), and cell-type specific gene regulation is linked to the reorganization of 3D chromatin during cellular differentiation. Here, we show dose-dependent regulation of chromatin organization by the congenital heart disease (CHD)-linked, lineage-restricted TF TBX5 in human cardiomyocyte differentiation. Genome organization, including compartments, topologically associated domains, and chromatin loops, are sensitive to reduced TBX5 dosage in a human model of CHD, with variations in response across individual cells. Regions normally bound by TBX5 were especially sensitive, while co-occupancy with CTCF partially protected TBX5-bound TAD boundaries and loop anchors. These results highlight the importance of lineage-restricted TF dosage in cell-type specific 3D chromatin dynamics, suggesting a new mechanism for TF-dependent disease.

Project description:Dosage-sensitive transcription factors (TFs) underlie altered gene regulation in congenital heart disease (CHD), and cell-type specific gene regulation is linked to the reorganization of 3D chromatin during cellular differentiation. Here, we show dose-dependent regulation of chromatin organization by the congenital heart disease (CHD)-linked, lineage-restricted TF TBX5 in human cardiomyocyte differentiation. Genome organization, including compartments, topologically associated domains, and chromatin loops, are sensitive to reduced TBX5 dosage in a human model of CHD, with variations in response across individual cells. Regions normally bound by TBX5 were especially sensitive, while co-occupancy with CTCF partially protected TBX5-bound TAD boundaries and loop anchors. These results highlight the importance of lineage-restricted TF dosage in cell-type specific 3D chromatin dynamics, suggesting a new mechanism for TF-dependent disease.

Project description:Haploinsufficiency of transcriptional regulators causes human congenital heart disease (CHD), predicting gene regulatory network (GRN) imbalances. Here, we define transcriptional responses to reduced transcription factor dosage in human iPSCs heterozygous or homozygous for loss of the CHD gene TBX5.

Project description:Haploinsufficiency of transcriptional regulators causes human congenital heart disease (CHD), predicting gene regulatory network (GRN) imbalances. Here, we define transcriptional responses to reduced transcription factor dosage in human iPSCs heterozygous or homozygous for loss of the CHD gene TBX5.

Project description:Haploinsufficiency of transcriptional regulators causes human congenital heart disease (CHD), predicting gene regulatory network (GRN) imbalances. Here, we define transcriptional responses to reduced transcription factor dosage in human iPSCs heterozygous or homozygous for loss of the CHD gene TBX5.

Project description:Haploinsufficiency of transcriptional regulators causes human congenital heart disease (CHD), predicting gene regulatory network (GRN) imbalances. Here, we define transcriptional responses to reduced transcription factor dosage in human iPSCs heterozygous or homozygous for loss of the CHD gene TBX5.

Project description:Haploinsufficiency of transcriptional regulators causes human congenital heart disease (CHD), predicting gene regulatory network (GRN) imbalances. Here, we define transcriptional responses to reduced transcription factor dosage in human iPSCs heterozygous or homozygous for loss of the CHD gene TBX5.

Project description:Haploinsufficiency of transcriptional regulators causes human congenital heart disease (CHD), suggesting that reduced transcription factor dosage causes a gene regulation imbalance. Here, we define transcriptional responses to reduced TBX5 in embryonic mouse hearts.

Project description:Congenital Heart Disease (CHD) accounts for 1% of birth defects, and while large-scale genetic studies have uncovered genes associated with CHDs, identifying causal mutations remains a challenge. We hypothesized that genetic determinants for CHDs could be found in the protein interactomes of GATA4 and TBX5, two cardiac transcription factors (TFs) associated with CHDs. Defining their interactomes in human cardiac progenitors via affinity purification-mass spectrometry and integrating the results with genetic data from the Pediatric Cardiac Genomic Consortium (PCGC) revealed an enrichment of de novo variants among proteins that interact with GATA4 or TBX5. A consolidative score designed to prioritize TF interactome members based on distinctive variant, gene and proband features identified numerous likely CHD-causing genes, including the epigenetic reader GLYR1. GLYR1 and GATA4 widely co-occupied cardiac developmental genes resulting in co-activation and the GLYR1 variant associated with CHD disrupted interaction with GATA4. This integrative proteomic and genetic approach provides a framework for prioritizing and interrogating the contribution of genetic variants in CHD and can be extended to other genetic diseases.