Integrating molecular and cellular components of endothelial shear stress mechanotransduction.

IF 4.1 2区 医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS American journal of physiology. Heart and circulatory physiology Pub Date : 2024-10-01 Epub Date: 2024-08-23 DOI:10.1152/ajpheart.00431.2024
Gavin Power, Larissa Ferreira-Santos, Luis A Martinez-Lemus, Jaume Padilla
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Abstract

The lining of blood vessels is constantly exposed to mechanical forces exerted by blood flow against the endothelium. Endothelial cells detect these tangential forces (i.e., shear stress), initiating a host of intracellular signaling cascades that regulate vascular physiology. Thus, vascular health is tethered to the endothelial cells' capacity to transduce shear stress. Indeed, the mechanotransduction of shear stress underlies a variety of cardiovascular benefits, including some of those associated with increased physical activity. However, endothelial mechanotransduction is impaired in aging and disease states such as obesity and type 2 diabetes, precipitating the development of vascular disease. Understanding endothelial mechanotransduction of shear stress, and the molecular and cellular mechanisms by which this process becomes defective, is critical for the identification and development of novel therapeutic targets against cardiovascular disease. In this review, we detail the primary mechanosensitive structures that have been implicated in detecting shear stress, including junctional proteins such as platelet endothelial cell adhesion molecule-1 (PECAM-1), the extracellular glycocalyx and its components, and ion channels such as piezo1. We delineate which molecules are truly mechanosensitive and which may simply be indispensable for the downstream transmission of force. Furthermore, we discuss how these mechanosensors interact with other cellular structures, such as the cytoskeleton and membrane lipid rafts, which are implicated in translating shear forces to biochemical signals. Based on findings to date, we also seek to integrate these cellular and molecular mechanisms with a view of deciphering endothelial mechanotransduction of shear stress, a tenet of vascular physiology.

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整合内皮剪切应力机械传导的分子和细胞成分。
血管内膜不断受到血流对内皮施加的机械力的作用。内皮细胞检测到这些切向力(即剪切应力)后,会启动一系列细胞内信号级联,从而调节血管生理机能。因此,血管健康与内皮细胞传递剪切应力的能力息息相关。事实上,剪切应力的机械传导是多种心血管益处的基础,包括与增加体育锻炼相关的一些益处。然而,在衰老和疾病(如肥胖和 2 型糖尿病)状态下,内皮细胞的机械传导能力会受损,从而诱发血管疾病。了解内皮对剪切应力的机械传导以及导致这一过程出现缺陷的分子和细胞机制,对于识别和开发针对心血管疾病的新型治疗靶点至关重要。在这篇综述中,我们详细介绍了与检测切变应力有关的主要机械敏感结构,包括 PECAM-1 等连接蛋白、细胞外糖萼及其成分以及 Piezo1 等离子通道。我们界定了哪些分子是真正的机械增效分子,哪些分子可能只是力的下游传输不可或缺的分子。此外,我们还讨论了这些机械传感器如何与其他细胞结构(如细胞骨架和膜脂筏)相互作用,这些结构在将剪切力转化为生化信号方面发挥着重要作用。根据迄今为止的研究结果,我们还试图整合这些细胞和分子机制,以期破译内皮对剪切应力的机械传导,这是血管生理学的一个原则。
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来源期刊
CiteScore
9.60
自引率
10.40%
发文量
202
审稿时长
2-4 weeks
期刊介绍: The American Journal of Physiology-Heart and Circulatory Physiology publishes original investigations, reviews and perspectives on the physiology of the heart, vasculature, and lymphatics. These articles include experimental and theoretical studies of cardiovascular function at all levels of organization ranging from the intact and integrative animal and organ function to the cellular, subcellular, and molecular levels. The journal embraces new descriptions of these functions and their control systems, as well as their basis in biochemistry, biophysics, genetics, and cell biology. Preference is given to research that provides significant new mechanistic physiological insights that determine the performance of the normal and abnormal heart and circulation.
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