Project description:Gene regulation is highly cell type-specific and understanding the function of non-coding genetic variants associated with complex traits requires molecular phenotyping at cell type resolution. In this study we performed single nucleus ATAC-seq (snATAC-seq) and genotyping in peripheral blood mononuclear cells from 13 individuals. Clustering chromatin accessibility profiles of 96,002 total nuclei identified 17 immune cell types and sub-types. We mapped chromatin accessibility QTLs (caQTLs) in each immune cell type and sub-type which identified ~6,000 total caQTL peaks, including those obscured from assays of bulk tissue such as with divergent effects on different cell types. For ~3,000 caQTLs we further annotated putative target genes of variant activity using single cell co-accessibility, and caQTL variants were significantly correlated with the accessibility level of linked gene promoters. We fine-mapped loci associated with 16 complex immune traits and identified immune cell caQTLs, including those with cell type-specific effects. At the 6q15 locus associated with type 1 diabetes, in line with previous reports, variant rs72928038 was a naïve CD4+ T cell caQTL linked to BACH2 and we validated the allelic effects of this variant on regulatory activity in Jurkat T cells. These results highlight the utility of snATAC-seq for mapping genetic effects on accessible chromatin in specific cell types and provide a resource for annotating complex immune trait loci.

Project description:Studies correlating genetic variation to gene expression facilitate the interpretation of common human phenotypes and disease. As functional variants may be operating in a tissue-dependent manner, we performed gene expression profiling and association with genetic variants (SNPs) on three cell types of 85 individuals. After excluding 10 outlier individuals detected through principal component analysis, we detected cell type-specific genetic effects, with 69 - 80% of regulatory variants operating in a cell type-specific manner and identified multiple eQTLs per gene, unique or shared among cell types and positively correlated with the number of transcripts per gene. Cell type specific eQTLs were found at larger distances from genes and lower effect size similar to known enhancers. These data suggest that the complete regulatory variant repertoire can only be uncovered in the context of cell type specificity.

Project description:Studies correlating genetic variation to gene expression facilitate the interpretation of common human phenotypes and disease. As functional variants may be operating in a tissue-dependent manner, we performed gene expression profiling and association with genetic variants (SNPs) on three cell types of 85 individuals. After excluding 10 outlier individuals detected through principal component analysis, we detected cell type-specific genetic effects, with 69 - 80% of regulatory variants operating in a cell type-specific manner and identified multiple eQTLs per gene, unique or shared among cell types and positively correlated with the number of transcripts per gene. Cell type specific eQTLs were found at larger distances from genes and lower effect size similar to known enhancers. These data suggest that the complete regulatory variant repertoire can only be uncovered in the context of cell type specificity. Total RNA was extracted from fibroblasts, LCLs, and T-cells of the 85 unrelated individuals of the GenCord. Two one-quarter scale Message Amp II reactions (Ambion, Foster City, CA) were performed for each RNA extraction with 200 ng of total RNA. 1.5 μg of cRNA was hybridized to a commercial whole-genome expression array (WG-6 v3 Expression BeadChip, Illumina) to quantify transcript abundance. In total there were two technical replicates (labeling and hybridization) for each RNA sample.

Project description:While it is well established that variation in gene expression levels can be influenced by single nucleotide polymorphisms (SNPs), little is known about the regulatory mechanisms by which this occurs. To address this gap, we used DNaseI sequencing to measure genome-wide chromatin accessibility in 70 Yoruba lymphoblastoid cell lines (LCLs), for which genome-wide genotypes and estimates of gene expression levels based on RNA-sequencing are also available. We obtained a total of 2.8 billion uniquely mapped DNase-seq reads, which allowed us to produce genome-wide maps of chromatin accessibility for each individual. We identified 7,759 locations at which DNase-seq read depth correlates significantly with variation at a nearby SNP or indel (FDR=10%). We call such variants 'chromatin accessibility Quantitative Trait Loci' (or caQTLs). Most caQTLs lie within or very near the target DNaseI hypersensitive sites, and they are strongly enriched within inferred transcription factor binding sites. We find that a substantial fraction (14%) of caQTLs are also significantly associated with variation in the expression levels of nearby genes (namely, these loci are also classified as eQTLs), suggesting that changes in chromatin accessibility or transcription factor binding frequently lead to gene expression changes. Conversely, 12% of eQTL SNPs are also classified as caQTLs and, accounting for incomplete power, we estimate that the true fraction may be as high as 41%. Our observations indicate that caQTLs are abundant in the human genome, and are likely to be significant contributors to phenotypic variation. DNaseI-Seq on 70 YRI Hapmap cell lines. Each individual sequenced on several lanes of a flow cell on the Illumina Genome Analyzer II

Project description:Systemic lupus erythematosus (SLE) is a heterogeneous autoimmune disease. Knowledge of circulating immune cell types and cell states associated with SLE remains incomplete. We profiled over 1.2 million PBMCs (162 cases, 99 controls) with multiplexed single-cell RNA-seq (mux-seq). Cases exhibited prominent expression of type-1 interferon-stimulated genes (ISG) in monocytes, reduction of naïve CD4+ T cells that correlated with monocyte ISG expression, and expansion of repertoire-restricted cytotoxic GZMH+ CD8+ T cells. Cell-type-specific expression features accurately predicted case-control status and stratified patients into two molecular subtypes. We integrated dense genotyping data, mapping cell-type-specific cis-eQTLs and linked known and novel SLE-associated variants to cell-type-specific gene expression. These results demonstrate mux-seq as a systematic approach to characterize cellular composition, identify transcriptional signatures, and annotate genetic variants associated with SLE.

Project description:Gene regulation is highly cell type-specific and understanding the function of non-coding genetic variants associated with complex traits requires molecular phenotyping at cell type resolution. In this study we performed single nucleus ATAC-seq (snATAC-seq) and genotyping in peripheral blood mononuclear cells from 13 individuals. We mapped chromatin accessibility QTLs (caQTLs) in each immune cell type and sub-type in a subset of 10 samples of European genetic ancestry.

Project description:The impact of genetic regulatory elements on gene expression can vary across cell states. During dynamic processes such as cellular differentiation, cells transition through multiple cell states, and may differentiate toward multiple terminal cell types. We collected time-series single-cell RNA-sequencing data from 19 human cell lines, capturing 7 time points along a 16-day differentiation from induced pluripotent stem cells to cardiomyocytes. We used unsupervised clustering, marker gene expression patterns, and pseudotime inference methods to map individual cells to a position along one of two bifurcating differentiation trajectories that were inferred from the data. We then identified genetic effects on gene regulation with varying effects across these trajectories. We identified hundreds of dynamic eQTLs that change significantly across pseudotime, including many variants whose effects are specific to one of the two lineages. We then re-analyzed previously collected bulk data, and used cell state information to infer cell type interaction eQTLs in bulk, assigning previously identified dynamic eQTLs to one of the newly characterized cellular trajectories.

Project description:The impact of genetic regulatory elements on gene expression can change during differentiation and across cell types and environments. We mapped expression quantitative trait loci (eQTLs) throughout differentiation to elucidate the dynamics of genetic effects and the associated cell type specific mechanisms. To do so, we generated high resolution time-series RNA-sequencing data, capturing differentiation from induced pluripotent stem cells to cardiomyocytes with 16 time points in 19 human cell lines. Genetic effects on gene regulation in these data show clear temporal structure. We identified hundreds of dynamic eQTLs that change significantly over time, with enrichment in enhancers of relevant cell types. We also found nonlinear dynamic eQTLs, which have effects only during intermediate stages of differentiation. These include a variant associated with body mass index, highlighting that transient genetic effects can contribute to disease.

Project description:Genetic variants that impact gene regulation are important contributors to human phenotypic variation. For this reason, considerable efforts have been made to identify genetic associations with differences in mRNA levels of nearby genes, namely, cis expression quantitative trait loci (eQTLs). The phenotypic consequences of eQTLs are presumably due, in most cases, to their ultimate effects on protein expression levels. Yet, only few studies have quantified the impact of genetic variation on proteins levels directly. It remains unclear how faithfully eQTLs are reflected at the protein level, and whether there is a significant layer of cis regulatory variation acting primarily on translation or steady state protein levels. To address these questions, we measured ribosome occupancy by high-throughput sequencing, and relative protein levels by high-resolution quantitative mass spectrometry, in a panel of lymphoblastoid cell lines (LCLs) in which we had previously measured transcript expression using RNA sequencing. We then mapped genetic variants that are associated with changes in transcript expression (eQTLs), ribosome occupancy (rQTLs), or protein abundance (pQTLs). Most of the QTLs we detected are associated with transcript expression levels, with consequent effects on ribosome and protein levels. However, we found that eQTLs tend to have significantly reduced effect sizes on protein levels, suggesting that their potential impact on downstream phenotypes is often attenuated or buffered. Additionally, we confirmed the presence of a class of cis QTLs that specifically affect protein abundance with little or no effect on mRNA levels; most of these QTLs have little effect on ribosome occupancy, and hence may arise from differences in post-translational regulation.

Project description:While it is well established that variation in gene expression levels can be influenced by single nucleotide polymorphisms (SNPs), little is known about the regulatory mechanisms by which this occurs. To address this gap, we used DNaseI sequencing to measure genome-wide chromatin accessibility in 70 Yoruba lymphoblastoid cell lines (LCLs), for which genome-wide genotypes and estimates of gene expression levels based on RNA-sequencing are also available. We obtained a total of 2.8 billion uniquely mapped DNase-seq reads, which allowed us to produce genome-wide maps of chromatin accessibility for each individual. We identified 7,759 locations at which DNase-seq read depth correlates significantly with variation at a nearby SNP or indel (FDR=10%). We call such variants 'chromatin accessibility Quantitative Trait Loci' (or caQTLs). Most caQTLs lie within or very near the target DNaseI hypersensitive sites, and they are strongly enriched within inferred transcription factor binding sites. We find that a substantial fraction (14%) of caQTLs are also significantly associated with variation in the expression levels of nearby genes (namely, these loci are also classified as eQTLs), suggesting that changes in chromatin accessibility or transcription factor binding frequently lead to gene expression changes. Conversely, 12% of eQTL SNPs are also classified as caQTLs and, accounting for incomplete power, we estimate that the true fraction may be as high as 41%. Our observations indicate that caQTLs are abundant in the human genome, and are likely to be significant contributors to phenotypic variation.