Abstract

Introduction: Endothelial dysfunction and arterial inflammation are critically important for cardiovascular diseases such as atherosclerosis. Of major importance, they are among the predominant culprits that promote the transition from stable to vulnerable atheromas. Our pilot studies revealed Disabled Homolog 2 (Dab2) deficiency in endothelial cells (EC) results in endothelial dysfunction. However, the molecular mechanisms that direct Dab2 to combat endothelial dysfunction during atherosclerosis are completely unknown. Hypothesis: Dab2 prevents the progress of atherosclerosis by maintaining EC function and reducing inflammatory factors. Methods and Results: We examined the expression of endothelial Dab2 in human atherosclerosis patients and ApoE -/- mice fed a western diet (WD) for 12 weeks by immunoflurecent co-staining of VE-cadherin and Dab2 and observed drastically reduced Dab2 expression in the endothelium and intima of human fatty streaks and mouse atherosclerotic aortae. Genetic deletion of Dab2 in the endothelium of ApoE -/- mice on a WD for 12 weeks significantly increased atherosclerosis as revealed by Oil Red O staining of aortic roots and arches, suggesting that Dab2 could be a atheroprotective flow-responsive gene. Similar results were found in WT and EC-iDab2KO mice injected with AAv8-PCSK9 virus. RNA-seq of primary mouse aortic ECs (MAECs) isolated from WT and EC-Dab2iKO mice revealed Dab2 deficiency upregulated many inflammatory genes. qRT-PCR confirmed TNF-α and IL-6 were significantly upregulated in Dab2KO MAECs. Additionally, we observed an increase in Dab2 binding to NEMO in the absence of endocytic adapter proteins epsins via co-IP with anti-Dab2 in WT and epsin-deficient DKO MAECs. We also found three Klf4 binding sites present in the Dab2 gene promoter/enhancer and that overexpression of Klf4 upregulated Dab2 expression in a dosage-dependent manner. Conclusions: Our findings indicated the essential role of Dab2 in protecting the atherogenic endothelium by reducing macrophage accumulation and increasing plaque stability in the aortic roots, which may provide new anti-atherosclerotic therapeutics.

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