剪切应力诱导基质细胞CCN蛋白的调控及功能

IF 3.6 3区 生物学 Q3 CELL BIOLOGY
Yang-Kao Wang, Hung-Kai Weng, Fan-E Mo
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引用次数: 1

摘要

剪切应力是由血液或间质液等流体流动产生的摩擦阻力,在调节细胞基因表达和功能表型方面起着关键作用。基质细胞CCN家族蛋白受不同流型剪切应力的动态调控,其表达显著改变细胞微环境。分泌的CCN蛋白主要与几种细胞表面整合素受体结合,介导其调节细胞存活、功能和行为的多种功能。基因敲除研究表明,CCN蛋白在心血管和骨骼系统中具有主要功能,这两个主要系统中CCN的表达受剪切应力调节。在心血管系统中,内皮直接暴露于血管剪切应力下。单向层流血流产生层流剪切应力,促进内皮表型成熟,上调抗炎CCN3表达。相反,受干扰的血流产生振荡剪切应力,通过诱导CCN1和CCN2诱导内皮功能障碍。剪切诱导的CCN1与整合素α6β1结合,促进内皮细胞超氧化物生成、NF-κB活化和炎症基因表达。虽然剪切应力与CCN4-6之间的相互作用尚不清楚,但ccn4显示出促炎特性,CCN5抑制血管细胞的生长和迁移。CCN蛋白在心血管发育、体内平衡和疾病中的关键作用是显而易见的,但尚未完全了解。在骨骼系统中,骨的机械负荷在腔隙-骨管系统中产生来自间质液的剪切应力,促进成骨细胞分化和骨形成。CCN1和CCN2在骨细胞中被诱导并可能介导流体剪切应力力学感知。然而,间质剪切应力诱导的CCN1和CCN2在骨中的确切作用尚不清楚。与其他CCN家族蛋白相比,CCN3抑制成骨细胞分化,尽管尚未报道其受骨细胞间质剪切应力的调节。骨剪切应力诱导CCN蛋白及其功能在很大程度上仍然未知,值得进一步研究。本文综述了剪切胁迫在生理条件、疾病和细胞培养模型中调控CCN蛋白的表达和功能。CCN家族蛋白之间的作用在组织重塑和体内平衡中可以是代偿性的或反作用的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The regulation and functions of the matricellular CCN proteins induced by shear stress

The regulation and functions of the matricellular CCN proteins induced by shear stress

Shear stress is a frictional drag generated by the flow of fluid, such as blood or interstitial fluid, and plays a critical role in regulating cellular gene expression and functional phenotype. The matricellular CCN family proteins are dynamically regulated by shear stress of different flow patterns, and their expression significantly alters the microenvironment of cells. Secreted CCN proteins mainly bind to several cell surface integrin receptors to mediate their diverse functions in regulating cell survival, function, and behavior. Gene-knockout studies indicate major functions of CCN proteins in the cardiovascular and skeletal systems, the two primary systems in which CCN expressions are regulated by shear stress. In the cardiovascular system, the endothelium is directly exposed to vascular shear stress. Unidirectional laminar blood flow generates laminar shear stress, which promotes a mature endothelial phenotype and upregulates anti-inflammatory CCN3 expression. In contrast, disturbed flow generates oscillatory shear stress, which induces endothelial dysfunction through the induction of CCN1 and CCN2. Shear-induced CCN1 binds to integrin α6β1 and promotes superoxide production, NF-κB activation, and inflammatory gene expression in endothelial cells. Although the interaction between shear stress and CCN4-6 is not clear, CCN 4 exhibits a proinflammatory property and CCN5 inhibits vascular cell growth and migration. The crucial roles of CCN proteins in cardiovascular development, homeostasis, and disease are evident but not fully understood. In the skeletal system, mechanical loading on bone generates shear stress from interstitial fluid in the lacuna-canalicular system and promotes osteoblast differentiation and bone formation. CCN1 and CCN2 are induced and potentially mediate fluid shear stress mechanosensing in osteocytes. However, the exact roles of interstitial shear stress-induced CCN1 and CCN2 in bone are still not clear. In contrast to other CCN family proteins, CCN3 inhibits osteoblast differentiation, although its regulation by interstitial shear stress in osteocytes has not been reported. The induction of CCN proteins by shear stress in bone and their functions remain largely unknown and merit further investigation. This review discusses the expression and functions of CCN proteins regulated by shear stress in physiological conditions, diseases, and cell culture models. The roles between CCN family proteins can be compensatory or counteractive in tissue remodeling and homeostasis.

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来源期刊
CiteScore
6.40
自引率
4.90%
发文量
40
期刊介绍: The Journal of Cell Communication and Signaling provides a forum for fundamental and translational research. In particular, it publishes papers discussing intercellular and intracellular signaling pathways that are particularly important to understand how cells interact with each other and with the surrounding environment, and how cellular behavior contributes to pathological states. JCCS encourages the submission of research manuscripts, timely reviews and short commentaries discussing recent publications, key developments and controversies. Research manuscripts can be published under two different sections : In the Pathology and Translational Research Section (Section Editor Andrew Leask) , manuscripts report original research dealing with celllular aspects of normal and pathological signaling and communication, with a particular interest in translational research. In the Molecular Signaling Section (Section Editor Satoshi Kubota) manuscripts report original signaling research performed at molecular levels with a particular interest in the functions of intracellular and membrane components involved in cell signaling.
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