Project description:Functional consequences of genetic variation in the non-coding human genome are difficult to ascertain despite demonstrated associations to common, complex disease traits. To elucidate properties of functional non-coding SNPs with effects in human endothelial cells (EC), we utilized our previous molecular Quantitative Trait Locus (molQTL) analysis for transcription factor binding, chromatin accessibility, and H3K27 acetylation to nominate a set of likely functional non-coding SNPs. Together with information from Genome-Wide Association Studies (GWAS) for vascular disease traits, we tested the ability of more than 34,000 genetic variants to perturb enhancer function in ECs using the highly multiplexed reporter assay. Based on these results, CRISPR-mediated deletion followed by mRNA-Seq was carried out for SNP-containing regulatory elements near SMAD3 and LDAH (C2orf43) in order to functionally verify the target genes of the regulatory elements.

Project description:The development of whole genome association studies from the general population has lead to the robust identification of several loci involved in different common human diseases. Interestingly, most of the strongest signals of association observed in these studies arise from non-coding regions, raising the possibility that these regions are involved in the etiology of the disease through regulatory mechanisms. These findings highlight the importance of better understanding the inter-individual differences in gene expression in humans. The aim of the study was to search for biomarker, to identify eQTLs and to elucidate whether whole-blood eQTLs allow to identify putative functional variants involved in the etiology of complex traits. Note: Due to ethical issues no phenotypic information is provided.

Project description:Genetic variants altering cis-regulation of normal gene expression (cis-eQTLs) have been extensively mapped in human cells and tissues, but the extent to which environmental perturbation influences such traits has not been studied to date. We carried out large-scale induction experiments using primary human bone cells derived from 113 unrelated donors of Swedish origin harvested under 18 different conditions (seven treatments, two vehicles, each assessed at two time points). The treatments with the largest impact on the transcriptome, verified on two independent expression arrays, included BMP-2 (t=2h), dexamethasone (DEX) (t=24h), and PGE2 (t=24h). Using these treatments, we performed expression profiling for 18,144 RefSeq transcripts applying biological replicates of the complete study cohort (ntotal=782) and combined it with genome-wide SNP-genotyping data in order to map treatment-specific cis-eQTLs. We found that 93% of cis-eQTLs at 1% FDR were replicated in at least one additional treatment and in fact, on average only 1.4% of the cis-eQTLs were considered as treatment-specific at high confidence. The relative invariability of cis-regulation following perturbation was reiterated independently by genome-wide allelic expression tests where only a small proportion of variance could be attributed to treatment, though treatment-specific cis-regulatory effects were 2-6-fold more abundant among up-or downregulated genes. We further followed-up and validated the DEX-specific cis-regulation of the MYO6 and TNC loci and found top cis-regulatory variants located 180 and 250kb upstream of the transcription start sites, respectively. Our results suggest that, as opposed to tissue-specificity of cis-eQTLs, the interaction between cellular environment and cis-variants are relatively rare (~1.5%), but that detection of such specific interactions can be achieved by combination of functional genomic tools. Total RNA from cultured trabecular bone cells obtained from ~100 unrelated Caucasian donors treated under multiple different conditions and timepoints. Each sample represented by two or three biological replicates. This dataset includes samples treated with bone morphogenetic protein 2 (BMP2) for 2 hours.

Project description:Genetic variants altering cis-regulation of normal gene expression (cis-eQTLs) have been extensively mapped in human cells and tissues, but the extent to which environmental perturbation influences such traits has not been studied to date. We carried out large-scale induction experiments using primary human bone cells derived from 113 unrelated donors of Swedish origin harvested under 18 different conditions (seven treatments, two vehicles, each assessed at two time points). The treatments with the largest impact on the transcriptome, verified on two independent expression arrays, included BMP-2 (t=2h), dexamethasone (DEX) (t=24h), and PGE2 (t=24h). Using these treatments, we performed expression profiling for 18,144 RefSeq transcripts applying biological replicates of the complete study cohort (ntotal=782) and combined it with genome-wide SNP-genotyping data in order to map treatment-specific cis-eQTLs. We found that 93% of cis-eQTLs at 1% FDR were replicated in at least one additional treatment and in fact, on average only 1.4% of the cis-eQTLs were considered as treatment-specific at high confidence. The relative invariability of cis-regulation following perturbation was reiterated independently by genome-wide allelic expression tests where only a small proportion of variance could be attributed to treatment, though treatment-specific cis-regulatory effects were 2-6-fold more abundant among up-or downregulated genes. We further followed-up and validated the DEX-specific cis-regulation of the MYO6 and TNC loci and found top cis-regulatory variants located 180 and 250kb upstream of the transcription start sites, respectively. Our results suggest that, as opposed to tissue-specificity of cis-eQTLs, the interaction between cellular environment and cis-variants are relatively rare (~1.5%), but that detection of such specific interactions can be achieved by combination of functional genomic tools. Total RNA from cultured trabecular bone cells obtained from ~100 unrelated Caucasian donors treated under multiple different conditions and timepoints. Each sample represented by two or three biological replicates. This dataset includes samples treated with dexamethasone (DEX) for 24 hours.

Project description:Genetic variants altering cis-regulation of normal gene expression (cis-eQTLs) have been extensively mapped in human cells and tissues, but the extent to which environmental perturbation influences such traits has not been studied to date. We carried out large-scale induction experiments using primary human bone cells derived from 113 unrelated donors of Swedish origin harvested under 18 different conditions (seven treatments, two vehicles, each assessed at two time points). The treatments with the largest impact on the transcriptome, verified on two independent expression arrays, included BMP-2 (t=2h), dexamethasone (DEX) (t=24h), and PGE2 (t=24h). Using these treatments, we performed expression profiling for 18,144 RefSeq transcripts applying biological replicates of the complete study cohort (ntotal=782) and combined it with genome-wide SNP-genotyping data in order to map treatment-specific cis-eQTLs. We found that 93% of cis-eQTLs at 1% FDR were replicated in at least one additional treatment and in fact, on average only 1.4% of the cis-eQTLs were considered as treatment-specific at high confidence. The relative invariability of cis-regulation following perturbation was reiterated independently by genome-wide allelic expression tests where only a small proportion of variance could be attributed to treatment, though treatment-specific cis-regulatory effects were 2-6-fold more abundant among up-or downregulated genes. We further followed-up and validated the DEX-specific cis-regulation of the MYO6 and TNC loci and found top cis-regulatory variants located 180 and 250kb upstream of the transcription start sites, respectively. Our results suggest that, as opposed to tissue-specificity of cis-eQTLs, the interaction between cellular environment and cis-variants are relatively rare (~1.5%), but that detection of such specific interactions can be achieved by combination of functional genomic tools. Total RNA from cultured trabecular bone cells obtained from ~100 unrelated Caucasian donors treated under multiple different conditions and timepoints. Each sample represented by two or three biological replicates. This dataset includes samples treated with prostaglandin E2 (PGE2) for 24 hours.

Project description:The development of whole genome association studies from the general population has lead to the robust identification of several loci involved in different common human diseases. Interestingly, most of the strongest signals of association observed in these studies arise from non-coding regions, raising the possibility that these regions are involved in the etiology of the disease through regulatory mechanisms. These findings highlight the importance of better understanding the inter-individual differences in gene expression in humans. Aim of the study was to search for biomarker, to identify eQTLs and to elucidate whether whole-blood eQTLs allow to identify putative functional variants involved in the etiology of complex traits. For more information about the KORA F4 study, please see http://www.helmholtz-muenchen.de/en/kora-en/information-for-scientists/current-kora-studies/f4-study/index.html .

Project description:Systematic characterization of how genetic variation modulates gene regulation in a cell type specific context is essential for understanding complex traits. To address this question, we profiled gene expression and chromatin state of cells from healthy retinae of 20 human donors with a single-cell multiomics approach, and performed genomic sequencing. sc-eQTLs, sc-caQTL, sc-ASCA and sc-ASE were mapped in major retinal cell types. By integrating these results, we identified and characterized regulatory elements and genetic variants effective on gene regulation in individual cell types. Most of the identified sc-eQTLs and sc-caQTLs exhibit cell type-specific effects. Interestingly, the cis-elements harboring genetic variants with cell type-specific effects tend to be accessible in multiple cell types. Lastly, we identified the enriched cell types, fine-mapped candidate causal variants and genes, and uncovered cell type-specific regulatory mechanism underlying GWAS loci.

Project description:Genetic variants altering cis-regulation of normal gene expression (cis-eQTLs) have been extensively mapped in human cells and tissues, but the extent to which environmental perturbation influences such traits has not been studied to date. We carried out large-scale induction experiments using primary human bone cells derived from 113 unrelated donors of Swedish origin harvested under 18 different conditions (seven treatments, two vehicles, each assessed at two time points). The treatments with the largest impact on the transcriptome, verified on two independent expression arrays, included BMP-2 (t=2h), dexamethasone (DEX) (t=24h), and PGE2 (t=24h). Using these treatments, we performed expression profiling for 18,144 RefSeq transcripts applying biological replicates of the complete study cohort (ntotal=782) and combined it with genome-wide SNP-genotyping data in order to map treatment-specific cis-eQTLs. We found that 93% of cis-eQTLs at 1% FDR were replicated in at least one additional treatment and in fact, on average only 1.4% of the cis-eQTLs were considered as treatment-specific at high confidence. The relative invariability of cis-regulation following perturbation was reiterated independently by genome-wide allelic expression tests where only a small proportion of variance could be attributed to treatment, though treatment-specific cis-regulatory effects were 2-6-fold more abundant among up-or downregulated genes. We further followed-up and validated the DEX-specific cis-regulation of the MYO6 and TNC loci and found top cis-regulatory variants located 180 and 250kb upstream of the transcription start sites, respectively. Our results suggest that, as opposed to tissue-specificity of cis-eQTLs, the interaction between cellular environment and cis-variants are relatively rare (~1.5%), but that detection of such specific interactions can be achieved by combination of functional genomic tools. Total RNA from cultured trabecular bone cells obtained from ~100 unrelated Caucasian donors treated under multiple different conditions and timepoints. Each sample represented by two or three biological replicates. This dataset includes samples treated with control vehicle (Ctrl), bone morphogenetic protein 2 (BMP2), dexamethasone (DEX), 1.25 VitD3 (VitD), insulin-like growth factor 1 (IGF1), prostaglandin E2 (PGE2), or tumor necrosis factor alpha (TNFalpha) for 2 or 24 hours.

Project description:Genetic variants altering cis-regulation of normal gene expression (cis-eQTLs) have been extensively mapped in human cells and tissues, but the extent to which environmental perturbation influences such traits has not been studied to date. We carried out large-scale induction experiments using primary human bone cells derived from 113 unrelated donors of Swedish origin harvested under 18 different conditions (seven treatments, two vehicles, each assessed at two time points). The treatments with the largest impact on the transcriptome, verified on two independent expression arrays, included BMP-2 (t=2h), dexamethasone (DEX) (t=24h), and PGE2 (t=24h). Using these treatments, we performed expression profiling for 18,144 RefSeq transcripts applying biological replicates of the complete study cohort (ntotal=782) and combined it with genome-wide SNP-genotyping data in order to map treatment-specific cis-eQTLs. We found that 93% of cis-eQTLs at 1% FDR were replicated in at least one additional treatment and in fact, on average only 1.4% of the cis-eQTLs were considered as treatment-specific at high confidence. The relative invariability of cis-regulation following perturbation was reiterated independently by genome-wide allelic expression tests where only a small proportion of variance could be attributed to treatment, though treatment-specific cis-regulatory effects were 2-6-fold more abundant among up-or downregulated genes. We further followed-up and validated the DEX-specific cis-regulation of the MYO6 and TNC loci and found top cis-regulatory variants located 180 and 250kb upstream of the transcription start sites, respectively. Our results suggest that, as opposed to tissue-specificity of cis-eQTLs, the interaction between cellular environment and cis-variants are relatively rare (~1.5%), but that detection of such specific interactions can be achieved by combination of functional genomic tools.

Project description:Genetic variants altering cis-regulation of normal gene expression (cis-eQTLs) have been extensively mapped in human cells and tissues, but the extent to which environmental perturbation influences such traits has not been studied to date. We carried out large-scale induction experiments using primary human bone cells derived from 113 unrelated donors of Swedish origin harvested under 18 different conditions (seven treatments, two vehicles, each assessed at two time points). The treatments with the largest impact on the transcriptome, verified on two independent expression arrays, included BMP-2 (t=2h), dexamethasone (DEX) (t=24h), and PGE2 (t=24h). Using these treatments, we performed expression profiling for 18,144 RefSeq transcripts applying biological replicates of the complete study cohort (ntotal=782) and combined it with genome-wide SNP-genotyping data in order to map treatment-specific cis-eQTLs. We found that 93% of cis-eQTLs at 1% FDR were replicated in at least one additional treatment and in fact, on average only 1.4% of the cis-eQTLs were considered as treatment-specific at high confidence. The relative invariability of cis-regulation following perturbation was reiterated independently by genome-wide allelic expression tests where only a small proportion of variance could be attributed to treatment, though treatment-specific cis-regulatory effects were 2-6-fold more abundant among up-or downregulated genes. We further followed-up and validated the DEX-specific cis-regulation of the MYO6 and TNC loci and found top cis-regulatory variants located 180 and 250kb upstream of the transcription start sites, respectively. Our results suggest that, as opposed to tissue-specificity of cis-eQTLs, the interaction between cellular environment and cis-variants are relatively rare (~1.5%), but that detection of such specific interactions can be achieved by combination of functional genomic tools.