Kindlin-2 对流动的相分离控制着血管的稳定性。

IF 16.5 1区 医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS Circulation research Pub Date : 2024-11-04 DOI:10.1161/CIRCRESAHA.124.324773
Nina Ma, Fangfang Wu, Jiayu Liu, Ziru Wu, Lu Wang, Bochuan Li, Yuming Liu, Xue Dong, Junhao Hu, Xi Fang, Heng Zhang, Ding Ai, Jing Zhou, Xiaohong Wang
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Pulsatile shear (2±4 dynes/cm<sup>2</sup>) or oscillatory shear (0.5±4 dynes/cm<sup>2</sup>) were applied to culture ECs. Live-cell imaging, fluorescence recovery after photobleaching assay, and optoDroplet assay were used to study the liquid-liquid phase separation (LLPS) of Kindlin-2. Co-immunoprecipitation, mutagenesis, proximity ligation assay, and transendothelial electrical resistance assay were used to explore the underlying mechanism of flow-regulated Kindlin-2 function.</p><p><strong>Results: </strong>We found that Kindlin-2 localization is altered under different flow patterns. <i>Kindlin-2</i><sup><i>iΔEC</i></sup> mice showed heightened vascular permeability. <i>Kindlin-2</i><sup><i>iΔEC</i></sup> were bred onto <i>ApoE</i><sup><i>-/-</i></sup> mice to generate <i>Kindlin-2</i><sup><i>iΔEC</i></sup>; <i>ApoE</i><sup><i>-</i></sup><sup><i>/-</i></sup> mice, which displayed a significant increase in atherosclerosis lesions. 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引用次数: 0

摘要

背景:保护动脉粥样硬化的剪切应力可保护内皮屏障功能,而动脉粥样硬化剪切应力则会增强内皮通透性。然而,不同流动模式调节内皮完整性的潜在机制仍有待明确。本研究旨在调查 Kindlin-2 的参与情况,Kindlin-2 是局灶粘附和内皮粘附连接的关键成分,对调节内皮细胞(EC)完整性和血管稳定性至关重要:方法:利用内皮细胞特异性 Kindlin-2 基因敲除小鼠(Kindlin-2iΔEC)动脉粥样硬化模型研究 Kindlin-2 在动脉粥样硬化发生中的作用。对培养的EC施加脉冲剪切力(2±4达因/平方厘米)或振荡剪切力(0.5±4达因/平方厘米)。利用活细胞成像、光漂白后荧光恢复试验和光学滴液试验研究了Kindlin-2的液-液相分离(LLPS)。我们还利用共免疫共沉淀、诱变、近距离连接试验和跨内皮电阻试验等方法探讨了Kindlin-2功能受血流调控的内在机制:结果:我们发现Kindlin-2的定位在不同的血流模式下会发生改变。Kindlin-2iΔEC小鼠的血管通透性增加。将 Kindlin-2iΔEC 与载脂蛋白E-/-小鼠杂交,产生 Kindlin-2iΔEC;载脂蛋白E-/-小鼠,其动脉粥样硬化病变显著增加。体外数据显示,在EC中,Kindlin-2经历了LLPS,这是正确的局灶粘附组装、成熟和连接形成的关键过程。质谱分析显示,在 PRMT5(蛋白精氨酸甲基转移酶 5)的催化下,振荡剪切增加了 Kindlin-2 的精氨酸甲基化。从功能上讲,精氨酸高甲基化抑制了 Kindlin-2 LLPS,损害了焦点粘附组装和连接成熟。值得注意的是,我们发现 Kindlin-2 的 R290 是 LLPS 的关键残基,也是精氨酸甲基化的关键位点。最后,药物抑制精氨酸甲基化可减少心血管细胞的活化和斑块的形成:总之,我们的研究阐明了机械力能诱导 Kindlin-2 的精氨酸甲基化,从而通过对 Kindlin-2 LLPS 的影响来调节血管的稳定性。以 Kindlin-2 精氨酸甲基化为靶点是治疗血管疾病和动脉粥样硬化的一种有前景的基于血液动力学的策略:URL: https://www.clinicaltrials.gov; Unique identifier:NCT02783300。
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Kindlin-2 Phase Separation in Response to Flow Controls Vascular Stability.

Background: Atheroprotective shear stress preserves endothelial barrier function, while atheroprone shear stress enhances endothelial permeability. Yet, the underlying mechanisms through which distinct flow patterns regulate EC integrity remain to be clarified. This study aimed to investigate the involvement of Kindlin-2, a key component of focal adhesion and endothelial adherens junctions crucial for regulating endothelial cell (EC) integrity and vascular stability.

Methods: Mouse models of atherosclerosis in EC-specific Kindlin-2 knockout mice (Kindlin-2iΔEC) were used to study the role of Kindlin-2 in atherogenesis. Pulsatile shear (2±4 dynes/cm2) or oscillatory shear (0.5±4 dynes/cm2) were applied to culture ECs. Live-cell imaging, fluorescence recovery after photobleaching assay, and optoDroplet assay were used to study the liquid-liquid phase separation (LLPS) of Kindlin-2. Co-immunoprecipitation, mutagenesis, proximity ligation assay, and transendothelial electrical resistance assay were used to explore the underlying mechanism of flow-regulated Kindlin-2 function.

Results: We found that Kindlin-2 localization is altered under different flow patterns. Kindlin-2iΔEC mice showed heightened vascular permeability. Kindlin-2iΔEC were bred onto ApoE-/- mice to generate Kindlin-2iΔEC; ApoE-/- mice, which displayed a significant increase in atherosclerosis lesions. In vitro data showed that in ECs, Kindlin-2 underwent LLPS, a critical process for proper focal adhesion assembly, maturation, and junction formation. Mass spectrometry analysis revealed that oscillatory shear increased arginine methylation of Kindlin-2, catalyzed by PRMT5 (protein arginine methyltransferase 5). Functionally, arginine hypermethylation inhibits Kindlin-2 LLPS, impairing focal adhesion assembly and junction maturation. Notably, we identified R290 of Kindlin-2 as a crucial residue for LLPS and a key site for arginine methylation. Finally, pharmacologically inhibiting arginine methylation reduces EC activation and plaque formation.

Conclusions: Collectively, our study elucidates that mechanical force induces arginine methylation of Kindlin-2, thereby regulating vascular stability through its impact on Kindlin-2 LLPS. Targeting Kindlin-2 arginine methylation emerges as a promising hemodynamic-based strategy for treating vascular disorders and atherosclerosis.

Registration: URL: https://www.clinicaltrials.gov; Unique identifier: NCT02783300.

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来源期刊
Circulation research
Circulation research 医学-外周血管病
CiteScore
29.60
自引率
2.00%
发文量
535
审稿时长
3-6 weeks
期刊介绍: Circulation Research is a peer-reviewed journal that serves as a forum for the highest quality research in basic cardiovascular biology. The journal publishes studies that utilize state-of-the-art approaches to investigate mechanisms of human disease, as well as translational and clinical research that provide fundamental insights into the basis of disease and the mechanism of therapies. Circulation Research has a broad audience that includes clinical and academic cardiologists, basic cardiovascular scientists, physiologists, cellular and molecular biologists, and cardiovascular pharmacologists. The journal aims to advance the understanding of cardiovascular biology and disease by disseminating cutting-edge research to these diverse communities. In terms of indexing, Circulation Research is included in several prominent scientific databases, including BIOSIS, CAB Abstracts, Chemical Abstracts, Current Contents, EMBASE, and MEDLINE. This ensures that the journal's articles are easily discoverable and accessible to researchers in the field. Overall, Circulation Research is a reputable publication that attracts high-quality research and provides a platform for the dissemination of important findings in basic cardiovascular biology and its translational and clinical applications.
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