Abstract

We have recently identified rs2019090 and PDGFD as the functional variant and gene mediating CAD risk at the 11q22.3 locus, with our initial analysis using a global knockout (KO) model showing that this gene may promote phenotypic changes in smooth muscle cells (SMCs) in the plaque and contribute to neointimal vascular calcification. Nonetheless, the specific cell-type and phenotypic states through which PDGFD may confer disease risk remains unexplored.To delineate the impact of SMC-derived PDGFD signalling on cell state transitions and plaque progression in atherosclerosis, we have developed a novel SMC-specific lineage tracing and Pdgfd KO mouse ( Pdgfd ΔSMC/ΔSMC , Myh11 CreERT2 , ROSA tdT/+ , ApoE -/- ) allowing us to confidently define the impact of SMC-derived Pdgfd in the vascular SMC lineage as well as in neighbouring populations. Leveraging our lineage tracing KO mutants on a hypercholesterolemic diet, we have employed single cell RNA sequencing (scRNAseq) and histological analyses to characterize the cellular and molecular effect of Pdgfd in vascular disease. SMC-specific Pdgfd deletion resulted in alterations in the distribution of transitioning SMC populations, as well as previously unexplored gene expression differences within these cell types. This was accompanied by a significant reduction in atherosclerotic burden and plaque size across the aorta, including aortic root as well as descending abdominal aorta. Histological analysis revealed decreased monocyte recruitment, show by quantifying CD68+ cells within the plaque. To explore this further we interrogated the scRNAseq dataset to identify major pathways of cell-cell communication and the impact of altered Pdgfd signalling across different cell types. Overall, these data reveal that SMC-derived PDGFD substantially alters lesional SMC cell phenotype transitions, as well as inflammatory cell recruitment, implicating it as a major regulator of atherosclerotic disease progression.