Abstract
Despite decades of progress, coronary artery disease (CAD) remains the top cause of death worldwide. Additionally, trends in outcomes have worsened recently, highlighting the critical need for additional treatments. Human genetics has identified over 300 loci associated with CAD, but understanding the molecular mechanisms leading to disease remains a huge barrier to developing new therapies. These CAD-associated loci are enriched in smooth muscle cells (SMC) of the vascular wall, but no current therapies target these cells. Since insulin resistance is an important risk factor for CAD, understanding the molecular functions of genes associated with both insulin resistance and CAD will prioritize therapeutic candidates, especially if expressed in SMCs. One promising candidate is the gene PRDM16 (PR domain containing 16), which is highly expressed in vascular tissue. PRDM16 regulates cell fate decisions and insulin resistance in adipose tissue, but its role in atherosclerosis and SMC function is unknown. Recent advances in lineage tracing and conditional SMC knockout mouse models in conjunction with single cell technologies have demonstrated the cellular trajectories of SMC into several cellular states, including fibromyocytes (FMC) and chondromyocytes (CMC). Here, we employ this innovative approach to understand the role of Prdm16 on SMC phenotypic modulation in vivo and its role in the development of FMC and CMC. We also demonstrate the impact of Prdm16 in atherosclerosis and other important lesion characteristics relating to disease risk. We validate these effects in vitro and employ epigenetic analysis to identify the gene regulatory mechanisms whereby PRDM16 mediates its effects on SMC phenotypic modulation. Collectively these data demonstrate that PRDM16 is a causal factor that promotes risk of CAD.
Published Version
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