Abstract 10223: Tissue-Entrapped Extracellular Vesicles Modulate Divergent Mechanisms of Cardiovascular Calcification

Abstract

Introduction: Fewer than 50% of patients develop vascular and valvular calcification, implying differential pathogenesis. Tissue-entrapped extracellular vesicles (EVs) are implicated in mineralization but their contents and functions are unstudied. We investigated entrapped EV cargoes in human cardiovascular disease. Methods: Human carotid endarterectomy specimens and stenotic aortic valves were obtained from 53 patients. Disease stage-specific proteomics was performed on whole tissue (non-diseased/fibrotic/calcified areas). Tissue EVs were enriched by gradient fractionation then underwent proteomics and miRNA-seq. miR targets were predicted by TargetScan, pathway analyses utilized BioCarta/KEGG/Reactome, and protein-protein interaction networks employed STRING. Results: Disease progression drove significant convergence (p<0.0001) of atherosclerotic plaque and valve proteomes (2,318 proteins). 548 and 158 proteins were exclusively altered (q<0.05) by disease in plaques or valves, respectively. Vesicular GO terms increased 2.2x (p<0.01) amongst proteins altered by disease in both tissues (202). Proteomics found 24 EV markers in the low-density fractions of plaques and valves, confirmed by electron microscopy and nanoparticle tracking. EV omics quantified 1,104 proteins and 123 miR cargoes. Networks of proteins and miR targets shared by plaque and valve EVs revealed common regulation of Rho GTPase and MAPK signaling. 179 proteins and 5 miRs were altered between plaque and valve EVs (q<0.05); multi-omics integration found that EVs modulated cellular contraction and p53-mediated transcriptional regulation in plaques and valves, respectively. Conclusions: This first comparative proteomics study of human valves and arteries finds shared EV functionality in both diseases. Using novel means to examine tissue EV molecular cargoes, we also reveal critical divergent tissue-specific roles for EVs in mediating cardiovascular disease.