Endothelial cell (EC)-specific Ctgf/Ccn2 expression increases EC reprogramming and atherosclerosis

IF 4.5 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Matrix Biology Pub Date : 2025-01-14 DOI:10.1016/j.matbio.2025.01.003

Feifei Li , Sandeep Kumar , Anastassia Pokutta-Paskaleva , Dong-won Kang , Chanwoo Kim , Julia Raykin , Victor Omojola , Carson Hoffmann , Fujie Zhao , Maiko Teichmann , Christian Park , Kyung In Baek , Gloriani Sanchez Marrero , Jing Ma , Hiromi Yanagisawa , Andrew Leask , Lucas Timmins , Xiangqin Cui , Roy Sutliff , Rudy L. Gleason Jr. , Luke P. Brewster

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引用次数: 0

Abstract

Arterial endothelial cells (ECs) reside in a complex biomechanical environment. ECs sense and respond to wall shear stress. Low and oscillatory wall shear stress is characteristic of disturbed flow and commonly found at arterial bifurcations and around atherosclerotic plaques. Disturbed flow is pro-inflammatory to ECs. Arteries also stiffen with aging and/or the onset of vascular disease. ECs sense and respond to stiffening in a pro-fibrotic manner. Thus, flow and stiffening disturbances elicit EC responses that promote pathologic arterial remodeling. However, the pathways elicited by ECs under pathologic stiffening and disturbed flow are not well understood.

The objective of this work was to discover and test the modifiability of key pathways in ECs. To do this we used the partial carotid ligation model to impose disturbed flow onto the precociously stiffened fibulin-5 knockout (Fbln5^-/-) mouse carotid arteries. Biomechanical testing demonstrated that Fbln5^-/- arteries under disturbed flow approximate the stiffness ratio of diseased human arteries, and the ECs in these Fbln5^-/- arteries underwent rapid reprogramming via endothelial to mesenchymal transition (EndMT). Under atherogenic conditions, disturbed flow Fbln5^-/- arteries developed more vulnerable plaques than the wild type (WT) mouse arteries. Connective tissue growth factor/cellular communication network factor 2 (Ctgf/Ccn2) was upregulated in vivo in ECs with aging, with stiffening in the Fbln5^-/- arteries, and increased again by disturbed flow under stiffened conditions, supporting CTGF as a key biomarker for flow and stiffening. This was validated by immunohistochemistry, which demonstrated increased CTGF deposition in areas of disturbed flow in patient carotid endarterectomy and peripheral artery disease (PAD) specimens. Finally, to test the role of CTGF in regulating and combining these processes, we created an EC-specific Ctgf knockout (Ctgf^ecko). We identified that carotid arteries under disturbed flow and atherogenic conditions in male Ctgf^ecko, but not female, mice had decreased plaque area compared to WT control mice. We then tested the Ctgf expression in the carotid endothelium exposed to disturbed or stable flow in WT and Fbln5^-/- mice. Here we found that under disturbed flow male mice had greater Ctgf expression than female mice.

This work demonstrates that stiffened + disturbed flow conditions drive EC reprogramming, that CTGF is increased by these conditions, and that this increase is more prominent in male carotid arteries. Future exploration of sex-based differences in these fibrotic pathways are warranted to develop targeted therapeutics to limit pathologic arterial remodeling under pathologically stiffened + disturbed flow environments.

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内皮细胞（EC）特异性CTGF/CCN2表达增加EC重编程和动脉粥样硬化

动脉内皮细胞（ECs）生活在一个复杂的生物力学环境中。ECs感知并响应壁面剪应力。低且振荡的壁剪应力是血流紊乱的特征，常见于动脉分叉处和动脉粥样硬化斑块周围。血流紊乱对内皮细胞有促炎作用。动脉也会随着年龄的增长和/或血管疾病的发生而变硬。内皮细胞以促纤维化的方式感知和响应硬化。因此，血流和硬化紊乱引起EC反应，促进病理性动脉重塑。然而，在病理性硬化和血流紊乱的情况下，内皮细胞所引发的途径尚不清楚。这项工作的目的是发现和测试ECs关键通路的可修饰性。为此，我们使用部分颈动脉结扎模型，对纤维蛋白-5敲除（Fbln5-/-）小鼠颈动脉施加干扰血流。生物力学测试表明，Fbln5-/-动脉在血流干扰下的刚度比接近人类病变动脉，这些Fbln5-/-动脉中的内皮细胞通过内皮细胞到间充质细胞的转化（EndMT）进行了快速重编程。在动脉粥样硬化条件下，血流紊乱的Fbln5-/-动脉比野生型（WT）小鼠动脉更容易形成斑块。结缔组织生长因子/细胞通信网络因子2 （Ctgf/Ccn2）在ec体内随着年龄的增长而上调，Fbln5-/-动脉硬化，在硬化条件下因血流紊乱而再次升高，支持Ctgf作为血流和硬化的关键生物标志物。免疫组织化学证实了这一点，在患者颈动脉内膜切除术和外周动脉病变（PAD）标本中，CTGF沉积在血流紊乱区域增加。最后，为了测试CTGF在调节和结合这些过程中的作用，我们创建了ec特异性CTGF敲除（Ctgfecko）。我们发现，在血流紊乱和动脉粥样硬化条件下，雄性Ctgfecko小鼠的颈动脉斑块面积比WT对照组小鼠减少，而雌性小鼠则没有。然后，我们测试了Ctgf在WT和Fbln5-/-小鼠颈动脉内皮中受干扰或稳定血流影响的表达。我们发现，在水流干扰下，雄性小鼠的Ctgf表达高于雌性小鼠。这项工作表明，硬化 + 紊乱的血流条件驱动EC重编程，CTGF在这些条件下增加，并且这种增加在男性颈动脉中更为突出。未来探索这些纤维化途径的性别差异是有必要的，以开发有针对性的治疗方法，以限制病理性硬化 + 紊乱血流环境下的病理性动脉重塑。

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来源期刊

Matrix Biology 生物-生化与分子生物学

CiteScore

11.40

自引率

4.30%

发文量

审稿时长

45 days

期刊介绍： Matrix Biology (established in 1980 as Collagen and Related Research) is a cutting-edge journal that is devoted to publishing the latest results in matrix biology research. We welcome articles that reside at the nexus of understanding the cellular and molecular pathophysiology of the extracellular matrix. Matrix Biology focusses on solving elusive questions, opening new avenues of thought and discovery, and challenging longstanding biological paradigms.