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Novel Role of Thrombospondin-1 in Protection against Rupture of Abdominal Aortic Aneurysm

$491,881R01FY2024HLNIH

University Of Wisconsin-Madison, Madison WI

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Abstract

Abdominal aortic aneurysm (AAA) is the progressive weakening and dilation of the aorta. A substantial knowledge gap exists in the understanding of molecular mechanisms responsible for aneurysm rupture, the major cause of mortality among AAA patients. Following our prior report of elevated thrombospondin-1 (TSP1) in human and mouse aneurysmal tissues, we conducted single-cell RNA sequencing (scRNA-seq) analysis and identified macrophages (Mɸs) being the primary source of elevated TSP1 in mouse aneurysmal aorta. We subsequently generated Mɸ-specific Thbs1 knockout mice (Thbs1∆Mɸ) by crossing Lyz2-Cre with our newly constructed Thbs1flox/flox mice. When subjected to aneurysm induction by angiotensin II (Ang II) coupled with hypercholesterolemia, over 60% of Thbs1∆Mɸ died due to AAA rupture, an incidence that was 2.6 times higher than Thbs1wt. Intriguingly, Thbs1∆Mɸ mice that survived to the end of 28-day Ang II infusion showed less aneurysm dilation than Thbs1wt. Smaller aneurysmal expansion was also found when Thbs1∆Mɸ mice were challenged with perivascular application of CaCl2, an AAA model that does not produce rupture. We propose two specific aims to delineate the mechanisms through which Mɸ-specific Thbs1 gene deletion differentially affects aortic dilation and rupture with an emphasis on AAA rupture. Specific Aim 1 devotes to establishing the rupture- preventive function of Mɸ TSP1. Specifically, we will determine the aortic responses proceeding lethal rupture in male and female Thbs1∆Mɸ mice in the Ang II model followed by identifying rupture-associated molecular signatures through scRNA-seq, in situ hybridization and immunostaining. Furthermore, we will examine the effects of Mɸ-specific Thbs1 knockout using a different murine model that produces rupture in advanced stages of aneurysm, which is more relevant to human AAA than the early rupture produced by the Ang II model. Specific Aim 2 focuses on investigating molecular mechanisms of aneurysm rupture. Preliminary studies showed that compared to wildtype, Thbs1-/- Mɸs had significantly reduced ability to migrate or to engulf apoptotic cells as well as neutrophil extracellular traps (NETs). We will test whether Mɸ TSP1 promotes NET clearance through CD47- mediated actin polymerization. Next, we will establish the causal effect of impaired Mɸ migration and phagocytosis on aneurysm rupture of Thbs1∆Mɸ mice. We will first determine whether NET burden is increased in Thbs1∆Mɸ died from rupture, and the spatial relationship between NETs and Mɸs. Second, we will test whether restoring Mɸ migration in Thbs1∆Mɸ reduces NET accumulation via adoptive transfer strategies. Furthermore, we will examine whether enhancing or attenuating NET clearance affect aneurysm rupture in Thbs1∆Mɸ. Lastly, we will analyze TSP1 expression and its association with Mɸ and NET accumulation in ruptured and non-ruptured human AAA tissues. By dissecting the multifaceted functions of Mɸs through TSP1 manipulations, this project will produce significant impact on the understanding of aneurysm rupture.

View original record on NIH RePORTER →