Abstract
Background: Genome-wide association studies have identified common genetic variants (Single Nucleotide Polymorphisms – SNPs) at ~300 human genomic loci linked to coronary artery disease (CAD) susceptibility. Among these genomic regions, the most impactful is the 9p21.3 CAD risk locus, which spans a 60 kb gene desert and encompasses ~80 SNPs in high linkage disequilibrium. We have previously generated isogenic induced Pluripotent Stem Cells (iPSCs) lines from risk and non-risk donors at 9p21.3 and performed a complete deletion of the locus. By using iPSC-derived vascular smooth muscle cells (iPSC-VSMCs) we demonstrated that the risk haplotype at 9p21.3 causes altered expression of numerous genes essential for muscle function, including contraction and adhesion. Notably, deletion of the risk haplotype restores the non-risk phenotype, suggesting a gain of function effect. Here, we aimed to identify the transcriptomic signature and state trajectories of VSMCs induced by the 9p21.3 risk haplotype and validate them through functional assays and ex-vivo analysis of human coronary arteries. Methods: We have used iPSCs from individuals carrying the risk and non-risk haplotype at 9p21.3 and isogenic knockout lines. After VSMCs differentiation induction, mature VSMCs were used for single cell RNA sequencing using 10X Chromium platform and functional assays. Results: Our analysis revealed that the 9p21.3 risk haplotype prompts VSMCs to acquire a novel cellular state showing reduced plasticity and divergent from other VSMC states previously linked to CAD. We found markers of alternative lineages, including osteogenic and neuronal, coupled with altered expression of genes within other CAD loci, and functional defects. We identified a set of new molecular markers crucial to define risk-associated VSMCs and uncovered their upstream regulators. Conclusions: Our study provides insights into CAD pathogenesis driven by the 9p21.3 risk locus and identified new gene regulatory networks essential for maintaining the normal functionality of the muscle layer of the arteries. Leveraging the power of iPSCs we present novel concepts about the biology of VSMCs and shed light on the impact of the strongest CAD genetic risk factor in preserving a healthy cellular state within the vasculature.
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