Project description:Medical research focuses on disease-specific genes. By contrast, here we systematically examined the roles of shared genes for disease susceptibility and as therapeutic and diagnostic targets. Meta-analysis of all published disease-related genome-wide association studies (GWAS) showed that T helper (Th) cell differentiation was the most shared pathway. Expression profiling data from highly diverse CD4+ T cell-associated diseases revealed shared disease-associated genes, which were enriched for Th cell differentiation, but also metabolic and proliferative pathways. This pleiotropy suggested that altered functions of shared genes could generally increase disease susceptibility. Indeed, compared to specific genes, the shared genes were enriched for disease-associated SNPs identified by all published disease-related GWAS. To examine if the shared genes induced disease-relevant pathways, we focused on transcription factors (TFs) that induced Th differentiation. Those TFs were enriched among the shared genes, as well as for disease-associated SNPs identified by GWAS, and disease-phenotypes in mice knock-out studies. Original GWAS and profiling data from patients with multiple sclerosis and allergy confirmed enrichment of disease-associated SNPs in the TFs, and that the TFs were differentially expressed at early disease stages, and their targets increased in parallel with disease development. From a clinical perspective, the shared genes were significantly enriched for known diagnostic and therapeutic targets. Prospective clinical studies of multiple sclerosis and allergy showed that shared or specific genes could be used to stratify patients for individualized medicine. Our findings show that shared disease genes generally increase disease susceptibility and are important therapeutic and diagnostic targets. Patients with seasonal allergic rhinitis (SAR) show considerable variations in response to glucocorticoids (GCs) treatment. Peripheral blood mononuclear cells (PBMCs) were collected from 8 high responders (HR) and 8 low responders (LR) to GC treatment. PBMCs were challenged with diluent, grass pollen extract (ALK-Abelló A/S; 100 μg/mL) as well as grass pollen extract plus glucocorticoids (100ug/mL) for one week. Total CD4+ T cells were enriched for the gene expression microarray analysis, which was performed using SurePrint G3 Human Gene Expression 8X60K microarrays.

Project description:Medical research focuses on disease-specific genes. By contrast, here we systematically examined the roles of shared genes for disease susceptibility and as therapeutic and diagnostic targets. Meta-analysis of all published disease-related genome-wide association studies (GWAS) showed that T helper (Th) cell differentiation was the most shared pathway. Expression profiling data from highly diverse CD4+ T cell-associated diseases revealed shared disease-associated genes, which were enriched for Th cell differentiation, but also metabolic and proliferative pathways. This pleiotropy suggested that altered functions of shared genes could generally increase disease susceptibility. Indeed, compared to specific genes, the shared genes were enriched for disease-associated SNPs identified by all published disease-related GWAS. To examine if the shared genes induced disease-relevant pathways, we focused on transcription factors (TFs) that induced Th differentiation. Those TFs were enriched among the shared genes, as well as for disease-associated SNPs identified by GWAS, and disease-phenotypes in mice knock-out studies. Original GWAS and profiling data from patients with multiple sclerosis and allergy confirmed enrichment of disease-associated SNPs in the TFs, and that the TFs were differentially expressed at early disease stages, and their targets increased in parallel with disease development. From a clinical perspective, the shared genes were significantly enriched for known diagnostic and therapeutic targets. Prospective clinical studies of multiple sclerosis and allergy showed that shared or specific genes could be used to stratify patients for individualized medicine. Our findings show that shared disease genes generally increase disease susceptibility and are important therapeutic and diagnostic targets.

Project description:Medical research focuses on disease-specific genes. By contrast, here we systematically examined the roles of shared genes for disease susceptibility and as therapeutic and diagnostic targets. Meta-analysis of all published disease-related genome-wide association studies (GWAS) showed that T helper (Th) cell differentiation was the most shared pathway. Expression profiling data from highly diverse CD4+ T cell-associated diseases revealed shared disease-associated genes, which were enriched for Th cell differentiation, but also metabolic and proliferative pathways. This pleiotropy suggested that altered functions of shared genes could generally increase disease susceptibility. Indeed, compared to specific genes, the shared genes were enriched for disease-associated SNPs identified by all published disease-related GWAS. To examine if the shared genes induced disease-relevant pathways, we focused on transcription factors (TFs) that induced Th differentiation. Those TFs were enriched among the shared genes, as well as for disease-associated SNPs identified by GWAS, and disease-phenotypes in mice knock-out studies. Original GWAS and profiling data from patients with multiple sclerosis and allergy confirmed enrichment of disease-associated SNPs in the TFs, and that the TFs were differentially expressed at early disease stages, and their targets increased in parallel with disease development. From a clinical perspective, the shared genes were significantly enriched for known diagnostic and therapeutic targets. Prospective clinical studies of multiple sclerosis and allergy showed that shared or specific genes could be used to stratify patients for individualized medicine. Our findings show that shared disease genes generally increase disease susceptibility and are important therapeutic and diagnostic targets.

Project description:Medical research focuses on disease-specific genes. By contrast, here we systematically examined the roles of shared genes for disease susceptibility and as therapeutic and diagnostic targets. Meta-analysis of all published disease-related genome-wide association studies (GWAS) showed that T helper (Th) cell differentiation was the most shared pathway. Expression profiling data from highly diverse CD4+ T cell-associated diseases revealed shared disease-associated genes, which were enriched for Th cell differentiation, but also metabolic and proliferative pathways. This pleiotropy suggested that altered functions of shared genes could generally increase disease susceptibility. Indeed, compared to specific genes, the shared genes were enriched for disease-associated SNPs identified by all published disease-related GWAS. To examine if the shared genes induced disease-relevant pathways, we focused on transcription factors (TFs) that induced Th differentiation. Those TFs were enriched among the shared genes, as well as for disease-associated SNPs identified by GWAS, and disease-phenotypes in mice knock-out studies. Original GWAS and profiling data from patients with multiple sclerosis and allergy confirmed enrichment of disease-associated SNPs in the TFs, and that the TFs were differentially expressed at early disease stages, and their targets increased in parallel with disease development. From a clinical perspective, the shared genes were significantly enriched for known diagnostic and therapeutic targets. Prospective clinical studies of multiple sclerosis and allergy showed that shared or specific genes could be used to stratify patients for individualized medicine. Our findings show that shared disease genes generally increase disease susceptibility and are important therapeutic and diagnostic targets.

Project description:Medical research focuses on disease-specific genes. By contrast, here we systematically examined the roles of shared genes for disease susceptibility and as therapeutic and diagnostic targets. Meta-analysis of all published disease-related genome-wide association studies (GWAS) showed that T helper (Th) cell differentiation was the most shared pathway. Expression profiling data from highly diverse CD4+ T cell-associated diseases revealed shared disease-associated genes, which were enriched for Th cell differentiation, but also metabolic and proliferative pathways. This pleiotropy suggested that altered functions of shared genes could generally increase disease susceptibility. Indeed, compared to specific genes, the shared genes were enriched for disease-associated SNPs identified by all published disease-related GWAS. To examine if the shared genes induced disease-relevant pathways, we focused on transcription factors (TFs) that induced Th differentiation. Those TFs were enriched among the shared genes, as well as for disease-associated SNPs identified by GWAS, and disease-phenotypes in mice knock-out studies. Original GWAS and profiling data from patients with multiple sclerosis and allergy confirmed enrichment of disease-associated SNPs in the TFs, and that the TFs were differentially expressed at early disease stages, and their targets increased in parallel with disease development. From a clinical perspective, the shared genes were significantly enriched for known diagnostic and therapeutic targets. Prospective clinical studies of multiple sclerosis and allergy showed that shared or specific genes could be used to stratify patients for individualized medicine. Our findings show that shared disease genes generally increase disease susceptibility and are important therapeutic and diagnostic targets.

Project description:Using Massively Parallel Reporter Assays (MPRAs), we functionally screened over 1,000 SNPs, prioritized from 39 neuropsychiatric trait/disease GWAS loci based on overlap with predicted regulatory features—including expression quantitative trait loci (eQTL) and histone marks—from human brains and cell cultures. Using mouse neuroblastoma Neuro2a (N2a) cells, we identify over 100 SNPs with allelic effects on expression. Functional SNPs were enriched for binding sequences of retinoic acid-receptive transcription factors (TFs); with additional allelic differences unmasked in cells treated with all-trans retinoic acid (ATRA). Motifs overrepresented at functional SNPs corresponded to a set of TFs highly specific to serotonergic neurons and collectively downregulated in schizophrenia. Our application of MPRAs to screen MDD-associated SNPs suggested a shared transcriptional regulatory program across loci, a subset of which are unmasked by retinoids. Additional code and results corresponding to this GEO submission can be found at https://bitbucket.org/jdlabteam/n2a_atra_mdd_mpra_paper/src

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.