Characterization of genomic regulation profiles in human mitral valve whole tissue to annotate genetic risk loci for mitral valve prolapse

Abstract

ABSTRACTRationaleMitral valve prolapse (MVP) is a common valve disease that leads to mitral insufficiency, heart failure and sudden death. The identification of risk loci provided insight into its genetic architecture, although the causal variants and target genes need to be fully characterized.ObjectiveTo establish the chromatin accessibility profiles and gene regulation specificities of human mitral valve and identify functional variants and target genes at MVP loci.Methods and ResultsWe mapped the open chromatin accessible regions in nuclei from 11 human mitral valves by an assay for transposase-accessible chromatin with high-throughput sequencing (ATAC-Seq). Compared to the heart tissue and cardiac fibroblasts, we found that mitral valve-specific ATAC-Seq peaks were enriched near genes involved in extracellular matrix organization, chondrocyte differentiation, and connective tissue development. The most enriched motif in mitral valve-specific open chromatin peaks was for the nuclear factor of activated T cells (NFATC) family of transcription factors, involved in valve endocardial and interstitial cells formation. We also found that MVP-associated variants (p < 10−5) observed in the current MVP GWAS were significantly enriched (p< 0.05) in mitral valve open chromatin peaks. Integration of the ATAC-Seq data with GWAS loci, extensive functional annotation, and gene reporter assay revealed plausible causal variants at two risk loci: rs6723013 at the IGFBP5/TNS1 locus and rs2641440 at the SMG6/SRR locus. Circular chromosome conformation capture followed by high-throughput sequencing provided evidence for several target genes, including SRR, HIC1, and DPH1 at the SMG6/SRR locus and further supported TNS1 as the most likely target gene on Chr2.ConclusionsHere we describe unprecedented genome-wide open chromatin profiles from human mitral valves that indicates specific gene regulation profiles, compared to the heart. We also report in vitro functional evidence for potential causal variants and target genes at MVP risk loci involving established and new biological mechanisms relevant to mitral valve disease.