Project description:Complex gene regulatory networks ensure that important genes are expressed at precise levels. When gene expression within these networks is sufficiently perturbed it can lead to disease. To understand how gene expression disruptions percolate through a network, we must first map the connections between regulatory genes and their downstream targets. However, it has been challenging to identify the upstream regulators for genes of interest. Here we develop a system for systematic discovery of upstream regulators of critical immune factors – IL2RA, IL-2, and CTLA4 – in primary human T cells. Then, CRISPR perturbations coupled with RNA-Seq, and ATAC-Seq, allowed us to map the full network of these regulators’ target genes and enhancers. These regulators form highly interconnected networks with extensive feedback loops. Furthermore, this network is highly enriched for autoimmune-associated disease variants and genes. These results provide insight into how autoimmune associated disease genes are regulated in T cells as well as broader principles about the structure of human gene regulatory networks.

Project description:Complex gene regulatory networks ensure that important genes are expressed at precise levels. When gene expression within these networks is sufficiently perturbed it can lead to disease. To understand how gene expression disruptions percolate through a network, we must first map the connections between regulatory genes and their downstream targets. However, it has been challenging to identify the upstream regulators for genes of interest. Here we develop a system for systematic discovery of upstream regulators of critical immune factors – IL2RA, IL-2, and CTLA4 – in primary human T cells. Then, CRISPR perturbations coupled with RNA-Seq, and ATAC-Seq, allowed us to map the full network of these regulators’ target genes and enhancers. These regulators form highly interconnected networks with extensive feedback loops. Furthermore, this network is highly enriched for autoimmune-associated disease variants and genes. These results provide insight into how autoimmune associated disease genes are regulated in T cells as well as broader principles about the structure of human gene regulatory networks.

Project description:Complex gene regulatory networks ensure that important genes are expressed at precise levels. When gene expression within these networks is sufficiently perturbed it can lead to disease. To understand how gene expression disruptions percolate through a network, we must first map the connections between regulatory genes and their downstream targets. However, it has been challenging to identify the upstream regulators for genes of interest. Here we develop a system for systematic discovery of upstream regulators of critical immune factors – IL2RA, IL-2, and CTLA4 – in primary human T cells. Then, CRISPR perturbations coupled with RNA-Seq, and ATAC-Seq, allowed us to map the full network of these regulators’ target genes and enhancers. These regulators form highly interconnected networks with extensive feedback loops. Furthermore, this network is highly enriched for autoimmune-associated disease variants and genes. These results provide insight into how autoimmune associated disease genes are regulated in T cells as well as broader principles about the structure of human gene regulatory networks.

Project description:Complex gene regulatory networks ensure that important genes are expressed at precise levels. When gene expression within these networks is sufficiently perturbed it can lead to disease. To understand how gene expression disruptions percolate through a network, we must first map the connections between regulatory genes and their downstream targets. However, it has been challenging to identify the upstream regulators for genes of interest. Here we develop a system for systematic discovery of upstream regulators of critical immune factors – IL2RA, IL-2, and CTLA4 – in primary human T cells. Then, CRISPR perturbations coupled with RNA-Seq, and ATAC-Seq, allowed us to map the full network of these regulators’ target genes and enhancers. These regulators form highly interconnected networks with extensive feedback loops. Furthermore, this network is highly enriched for autoimmune-associated disease variants and genes. These results provide insight into how autoimmune associated disease genes are regulated in T cells as well as broader principles about the structure of human gene regulatory networks.

Project description:Complex gene regulatory networks ensure that important genes are expressed at precise levels. When gene expression within these networks is sufficiently perturbed it can lead to disease. To understand how gene expression disruptions percolate through a network, we must first map the connections between regulatory genes and their downstream targets. However, it has been challenging to identify the upstream regulators for genes of interest. Here we develop a system for systematic discovery of upstream regulators of critical immune factors – IL2RA, IL-2, and CTLA4 – in primary human T cells. Then, CRISPR perturbations coupled with RNA-Seq, and ATAC-Seq, allowed us to map the full network of these regulators’ target genes and enhancers. These regulators form highly interconnected networks with extensive feedback loops. Furthermore, this network is highly enriched for autoimmune-associated disease variants and genes. These results provide insight into how autoimmune associated disease genes are regulated in T cells as well as broader principles about the structure of human gene regulatory networks.

Project description:In this work we present an analytical strategy to systematically identify early regulators by combining gene regulatory networks (GRN) with GWAS. We hypothesized that early regulators in T-cell associated diseases could be found by defining upstream transcription factors (TFs) in T-cell differentiation. Time series expression and DNA methylation profiling of T-cell differentiation identified several upstream TFs, of which TFs involved in Th1/2 differentiation were most enriched for disease associated SNPs identified by GWAS.

Project description:In this work we present an analytical strategy to systematically identify early regulators by combining gene regulatory networks (GRN) with GWAS. We hypothesized that early regulators in T-cell associated diseases could be found by defining upstream transcription factors (TFs) in T-cell differentiation. Time series expression and DNA methylation profiling of T-cell differentiation identified several upstream TFs, of which TFs involved in Th1/2 differentiation were most enriched for disease associated SNPs identified by GWAS.

Project description:In this work we present an analytical strategy to systematically identify early regulators by combining gene regulatory networks (GRN) with GWAS. We hypothesized that early regulators in T-cell associated diseases could be found by defining upstream transcription factors (TFs) in T-cell differentiation. Time series expression and DNA methylation profiling of T-cell differentiation identified several upstream TFs, of which TFs involved in Th1/2 differentiation were most enriched for disease associated SNPs identified by GWAS.

Project description:In this work we present an analytical strategy to systematically identify early regulators by combining gene regulatory networks (GRN) with GWAS. We hypothesized that early regulators in T-cell associated diseases could be found by defining upstream transcription factors (TFs) in T-cell differentiation. Time series expression and DNA methylation profiling of T-cell differentiation identified several upstream TFs, of which TFs involved in Th1/2 differentiation were most enriched for disease associated SNPs identified by GWAS.

Project description:RNA Sequencing of Mouse Sinoatrial Node Reveals an Upstream Regulatory Role for Islet-1 in Cardiac Pacemaker Cells Rationale: Treatment of sinus node disease with regenerative or cell-based therapies will require a detailed understanding of gene regulatory networks in cardiac pacemaker cells (PCs). Objective: To characterize the transcriptome of PCs using RNA sequencing, and to identify transcriptional networks responsible for PC gene expression. Methods and Results: We used laser capture micro-dissection (LCM) on a sinus node reporter mouse line to isolate RNA from PCs for RNA sequencing (RNA-Seq). Differential expression and network analysis identified novel SAN-enriched genes, and predicted that the transcription factor Islet-1 (Isl1) is active in developing pacemaker cells. RNA-Seq on SAN tissue lacking Isl1 established that Isl1 is an important transcriptional regulator within the developing SAN. Conclusions: (1) The PC transcriptome diverges sharply from other cardiomyocytes; (2) Isl1 is a positive transcriptional regulator of the PC gene expression program. There are 25 RNA-Sequencing Samples