Project description:Aim R-spondin 4 (RSPO4) is a suggestive risk gene of stage III–IV, grade C periodontitis and upregulated in gingiva of mice resistant to bacteria-induced alveolar bone loss. We aimed to replicate the association, identify and characterize the putative causal variant(s) and molecular effects, and understand the downstream effects of RSPO4 upregulation. Materials and Methods We performed a two-step association study for RSPO4 with imputed genotypes of a German–Dutch (896 stage III–IV, grade C periodontitis cases, 7104 controls) and Spanish sample (441 cases and 1141 controls). We analysed the allelic effects on transcription factor binding sites with reporter gene and antibody electrophoretic mobility shift assays. We used CRISPR/dCas9 activation and RNA sequencing to pinpoint RSPO4 as the target gene and to analyse downstream effects. Results RSPO4 was associated with periodontitis (rs6056178, pmeta = 4.6 × 10−5). rs6056178 contains a GATA-binding motif. The rs6056178 T-allele abolished reporter activity (p = .004) and reduced GATA binding (−14.5%). CRISPRa of the associated region increased RSPO4 expression (25.8 ± 6.5-fold, p = .003). RSPO4 activation showed strongest induction of Gliomedin (439-fold) and Mucin 21 (178-fold) and of the gene set “response to interferon-alpha” (area under the curve [AUC] = 0.8, p < 5 × 10−6). The most repressed gene set was “extracellular matrix interactions” (AUC = 0.8, padj = .00016). Conclusion RSPO4 is a potential periodontitis risk gene and modifies host defence and barrier integrity.

Project description:Although genetic studies have identified many hundreds of loci associated with human traits and diseases, pinpointing the causal alleles remains difficult, particularly for non-coding variants. To address this challenge, we have enhanced the sensitivity and reproducibility of the massively parallel reporter assay (MPRA), adapting it to identify variants that directly modulate gene expression. We then applied it to over 29,000 single nucleotide and insertion/deletion polymorphisms from 3,965 cis-expression quantitative trait loci (eQTL). We demonstrate strong correlation between our MPRA approach and existing measures of regulatory function, and determine an approximate sensitivity of ~20% with a positive predictive value of 60-65% to detect an eQTL causal allele. We identify 842 variants showing differential expression between alleles, including 53 well-annotated variants associated with diseases and traits. Thus, we have created a resource of concrete leads for understanding the genetic basis of specific phenotypes and illustrate the promise of this kind of approach for comprehensively interrogating how non-coding polymorphism shapes human biology.

Project description:Background: The identification of causal variants responsible for disease associations from genome-wide association studies (GWAS) facilitates functional understanding of the disease mechanisms implicated by GWAS. One of the earliest GWAS associations to COPD spans an intragenic region within FAM13A, but the causal variants at this loci have not yet been identified. Massively parallel reporter assays (MPRA) can be used to prioritize functional regulatory variants in a high-throughput manner. Methods: We used an integrated approach using fine-mapping in over 10,000 subjects from COPD GWAS studies, two MPRA experiments, traditional reporter assays, chromatin conformation capture, and CRISPR-based gene editing to characterize COPD-associated regulatory variants in FAM13A in human bronchial epithelial cell lines. Results: Conditional genetic association and fine mapping analyses identified two independent COPD association signals in FAM13A. MPRA identified 45 common functional regulatory variants, and six COPD-associated putative functional variants were prioritized for further functional investigation. Three variants demonstrated significant activity in traditional reporter assays, and one variant, rs2013701, was selected for further testing in the endogenous genomic context based on a direction of effect consistent with postulated mechanisms of FAM13A-mediated COPD susceptibility. CRISPR-based genome editing for this variant confirmed allele-specific effects on FAM13A expression and altered rates of cellular proliferation, providing multiple levels of functional characterization for this COPD-associated variant. Conclusions: Comprehensive screening for regulatory variants near FAM13A identified the presence of extensive functional regulatory variation within a 250kb window of FAM13A in HBECs. Focused functional evaluation of the COPD-associated functional variants in LD with the two independent association signals in this region prioritized the common variant rs2013701, for which multiple parallel lines of functional evidence confirm allelic effects on FAM13A regulation.

Project description:Genome-wide association studies (GWASs) identified the MEIS1 locus for Restless Legs Syndrome (RLS), but causal single nucleotide polymorphisms (SNPs) and the functional relevance have remained to be elucidated. The MEIS1 locus contains an exceptionally large number of highly conserved non-coding regions (HCNRs), which potentially function as cis-regulatory modules. We analyzed the HCNRs in the RLS-associated linkage disequilibrium (LD) block for allele-dependent enhancer activity in both zebrafish and mouse, comparing the protective and risk alleles of RLS-associated common variants. We found one enhancer, harboring the lead SNP rs12469063, which showed an allele-dependent reduction of reporter gene expression exclusively in the embryonic ganglionic eminences at developmental stage E12.5. Notably, the reporter activity overlapped with the endogenous telencephalic Meis1 expression domain, which co-localized with transcripts of all four validated RLS loci. Thus, the developing telencephalon represents the first neuroanatomic region implicated for RLS based on GWAS findings. Total RNA obtained from 2-3 male and female mice E12.5 (wildtype, heterzygote, homozygote) and 3-4 male heterozygote and wildtype mice (adult)

Project description:We used 2 massively parallel reporter assays to characterize 5,706 unique noncoding genetic variants derived from genome-wide association studies for two neurodegenerative disorders: Alzheimer’s disease (AD) and Progressive Supranuclear Palsy (PSP). Specifically, we synthesized a library consisting of both alleles of each SNV embedded within their native genomic context, which was cloned upstream of a minimal promoter within an expression vector. We then measured the transcriptional drive of each library element using next-generation sequencing of barcoded transcripts uniquely associated with each regulatory element. This enabled the identification of variants with significant transcriptional skew between alleles representing likely functional regulatory variants underlying disease risk.

Project description:Genome-wide association studies (GWAS) have successfully identified thousands of associations between common genetic variants and human disease phenotypes, but the majority of these variants are non-coding, often requiring genetic fine-mapping, extensive epigenomic profiling, and individual reporter assays to delineate potential causal variants. We employ a massively parallel reporter assay to simultaneous screen 2756 variants in strong linkage-disequilibrium with 75 sentinel variants associated with red blood cell traits. We show that this assay identifies elements with erythroid-specific endogenous regulatory activity. Across 23 variants, we conservatively identified 32 putative causal variants (PCVs). We demonstrate endogenous enhancer activity for three PCVs that predominantly affect the transcription of SMIM1, RBM38, and CD164 using targeted genome editing. Functional follow up of RBM38 delineates a key role for this gene in the dramatic alternative splicing program occurring during terminal erythropoiesis. Finally, we provide evidence for how common GWAS-nominated variants can disrupt cell-type specific transcriptional regulatory pathways.

Project description:Coronary artery disease (CAD) is a complex disorder with genetic and environmental influences. Genome-wide association studies (GWAS) have identified over 300 genomic loci associated with disease risk. However, identifying the functional variants within these loci has been limited in large part due to linkage disequilibrium. This represents a critical step in understanding the molecular mechanisms underlying disease risk. To identify and prioritize candidate causal CAD-associated variants, we performed lentivirus-based massively parallel reporter assays (lentiMPRAs) in primary vascular smooth muscle cells (SMCs), which play significant roles in atherosclerosis, the underlying cause of CAD. We tested 25892 CAD-associated variants for their allele-specific enhancer activity in quiescent and proliferative SMCs, modeling healthy and disease conditions. We identified 122 candidate variants showing significant enhancer activity and differences in reporter gene expression between risk and non-risk alleles. We also identified 23 variants showing condition-biased allelic imbalance and 41 variants showing sex-biased allelic imbalance. We further functionally characterized 25892 variants by performing CUT&RUN assays to identify variants in enhancer and promoter regions of SMCs. By integrating the results of these experiments, we identified a credible set of 49 CAD-associated variants in functionally relevant regions. Furthermore, by comparing these identified variants with our previously obtained expression quantitative trait loci (eQTL) data, 27 of these 49 variants were associated with SMC gene expression levels. Finally, we performed CRISPRi experiments on 8 variants comprising 9 variant-gene pairs, rs35976034 (MAP1S), rs4888409 (CFDP1), rs73193808 (MAP3K7CL), rs67631072 (INPP5B/FHL3), rs1651285 (SNHG18), rs17293632 (SMAD3), rs2238792 (ARVCF), rs4627080 (NRIP3), to confirm their regulatory potential of nearby gene expression. Taken together, our results comprehensively fine-map the causal variants that confer increased risk of CAD through their effects on vascular smooth muscle cells.

Project description:Coronary artery disease (CAD) is a complex disorder with genetic and environmental influences. Genome-wide association studies (GWAS) have identified over 300 genomic loci associated with disease risk. However, identifying the functional variants within these loci has been limited in large part due to linkage disequilibrium. This represents a critical step in understanding the molecular mechanisms underlying disease risk. To identify and prioritize candidate causal CAD-associated variants, we performed lentivirus-based massively parallel reporter assays (lentiMPRAs) in primary vascular smooth muscle cells (SMCs), which play significant roles in atherosclerosis, the underlying cause of CAD. We tested 25892 CAD-associated variants for their allele-specific enhancer activity in quiescent and proliferative SMCs, modeling healthy and disease conditions. We identified 122 candidate variants showing significant enhancer activity and differences in reporter gene expression between risk and non-risk alleles. We also identified 23 variants showing condition-biased allelic imbalance and 41 variants showing sex-biased allelic imbalance. We further functionally characterized 25892 variants by performing CUT&RUN assays to identify variants in enhancer and promoter regions of SMCs. By integrating the results of these experiments, we identified a credible set of 49 CAD-associated variants in functionally relevant regions. Furthermore, by comparing these identified variants with our previously obtained expression quantitative trait loci (eQTL) data, 27 of these 49 variants were associated with SMC gene expression levels. Finally, we performed CRISPRi experiments on 8 variants comprising 9 variant-gene pairs, rs35976034 (MAP1S), rs4888409 (CFDP1), rs73193808 (MAP3K7CL), rs67631072 (INPP5B/FHL3), rs1651285 (SNHG18), rs17293632 (SMAD3), rs2238792 (ARVCF), rs4627080 (NRIP3), to confirm their regulatory potential of nearby gene expression. Taken together, our results comprehensively fine-map the causal variants that confer increased risk of CAD through their effects on vascular smooth muscle cells.

Project description:Genome-wide association studies (GWASs) identified the MEIS1 locus for Restless Legs Syndrome (RLS), but causal single nucleotide polymorphisms (SNPs) and the functional relevance have remained to be elucidated. The MEIS1 locus contains an exceptionally large number of highly conserved non-coding regions (HCNRs), which potentially function as cis-regulatory modules. We analyzed the HCNRs in the RLS-associated linkage disequilibrium (LD) block for allele-dependent enhancer activity in both zebrafish and mouse, comparing the protective and risk alleles of RLS-associated common variants. We found one enhancer, harboring the lead SNP rs12469063, which showed an allele-dependent reduction of reporter gene expression exclusively in the embryonic ganglionic eminences at developmental stage E12.5. Notably, the reporter activity overlapped with the endogenous telencephalic Meis1 expression domain, which co-localized with transcripts of all four validated RLS loci. Thus, the developing telencephalon represents the first neuroanatomic region implicated for RLS based on GWAS findings.

Project description:Integration of a scalable parallel reporter genes for qRT-PCR based enhancer screening with CRISPR dCas9 activation and supershift EMSA identifies impaired BACH1 repression of ST8SIA1 to contribute to the increased risk for periodontitis in smokers