Department of Laboratory Medicine and Pathobiology (K.H.K., M.Y.M.F., R.N., E.T., B.J.K., P.A.M.).
Keenan Research Centre for Biomedical Science, Li Ka Shing Knowledge Institute (K.H.K., M.K.D., A.N.S., N.S., M.Y.M.F., R.N., B.M.B., P.A.M.).
Circulation. 2021 Aug 3;144(5):365-381. doi: 10.1161/CIRCULATIONAHA.120.051078. Epub 2021 Apr 29.
eNOS (endothelial nitric oxide synthase) is an endothelial cell (EC)-specific gene predominantly expressed in medium- to large-sized arteries where ECs experience atheroprotective laminar flow with high shear stress. Disturbed flow with lower average shear stress decreases eNOS transcription, which leads to the development of atherosclerosis, especially at bifurcations and curvatures of arteries. This prototypic arterial EC gene contains 2 distinct flow-responsive cis-DNA elements in the promoter, the shear stress response element (SSRE) and the KLF (Krüppel-like factor) element. Previous in vitro studies suggested their positive regulatory functions on flow-induced transcription of EC genes including eNOS. However, the in vivo function of these cis-DNA elements remains unknown.
Insertional transgenic mice with a mutation at each flow-responsive cis-DNA element were generated using a murine eNOS promoter-β-galactosidase reporter by linker-scanning mutagenesis and compared with episomal-based mutations in vitro. DNA methylation at the eNOS proximal promoter in mouse ECs was assessed by bisulfite sequencing or pyrosequencing.
Wild type mice with a functional eNOS promoter-reporter transgene exhibited reduced endothelial reporter expression in the atheroprone regions of disturbed flow (n=5). It is surprising that the SSRE mutation abrogated reporter expression in ECs and was associated with aberrant hypermethylation at the eNOS proximal promoter (n=7). Reporter gene silencing was independent of transgene copy number and integration position, indicating that the SSRE is a critical cis-element necessary for eNOS transcription in vivo. The KLF mutation demonstrated an integration site-specific decrease in eNOS transcription, again with marked promoter methylation (n=8), suggesting that the SSRE alone is not sufficient for eNOS transcription in vivo. In wild type mice, the native eNOS promoter was significantly hypermethylated in ECs from the atheroprone regions where eNOS expression was markedly repressed by chronic disturbed flow, demonstrating that eNOS expression is regulated by flow-dependent DNA methylation that is region-specific in the arterial endothelium in vivo.
We report, for the first time, that the SSRE and KLF elements are critical flow sensors necessary for a transcriptionally permissive, hypomethylated eNOS promoter in ECs under chronic shear stress in vivo. Moreover, eNOS expression is regulated by flow-dependent epigenetic mechanisms, which offers novel mechanistic insight on eNOS gene regulation in atherogenesis.
eNOS(内皮型一氧化氮合酶)是一种内皮细胞(EC)特异性基因,主要在中到大动脉中表达,这些动脉中的 EC 经历着具有高剪切力的保护性层流。低平均剪切力的紊乱流动会降低 eNOS 转录,从而导致动脉粥样硬化的发展,尤其是在动脉分叉处和弯曲处。这种典型的动脉 EC 基因在启动子中包含 2 个不同的对流动有反应的顺式 DNA 元件,即剪切力反应元件(SSRE)和 KLF(Krüppel 样因子)元件。先前的体外研究表明,它们对包括 eNOS 在内的 EC 基因的流动诱导转录具有正调节作用。然而,这些顺式 DNA 元件的体内功能仍然未知。
使用通过连接扫描诱变生成的小鼠 eNOS 启动子-β-半乳糖苷酶报告基因的插入型转基因小鼠,与体外的基于附加体的突变进行了比较。通过亚硫酸氢盐测序或焦磷酸测序评估了小鼠 EC 中 eNOS 近端启动子的 DNA 甲基化。
具有功能性 eNOS 启动子-报告基因转基因的野生型小鼠在紊乱流的易损部位观察到内皮报告基因表达减少(n=5)。令人惊讶的是,SSRE 突变使 EC 中的报告基因表达缺失,并与 eNOS 近端启动子的异常高甲基化相关(n=7)。报告基因沉默与转基因拷贝数和整合位置无关,表明 SSRE 是体内 eNOS 转录所必需的关键顺式元件。KLF 突变显示出整合位点特异性的 eNOS 转录减少,同样伴随着明显的启动子甲基化(n=8),这表明 SSRE 本身不足以在体内进行 eNOS 转录。在野生型小鼠中,易损区 EC 中的内源性 eNOS 启动子显著高甲基化,而 eNOS 表达在慢性紊乱流的情况下受到显著抑制,这表明 eNOS 表达受动脉内皮中特定区域的依赖于流动的 DNA 甲基化调节。
我们首次报告,SSRE 和 KLF 元件是体内慢性剪切应力下 EC 中转录允许的、低甲基化 eNOS 启动子所必需的关键流动传感器。此外,eNOS 表达受依赖于流动的表观遗传机制调节,这为动脉粥样硬化形成中的 eNOS 基因调节提供了新的机制见解。
