Do not overwork: cellular communication network factor 3 for life in cartilage

IF 3.6 3区 生物学 Q3 CELL BIOLOGY
Satoshi Kubota, Harumi Kawaki, Bernard Perbal, Masaharu Takigawa, Kazumi Kawata, Takako Hattori, Takashi Nishida
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引用次数: 3

Abstract

Cellular communication network factor (CCN) 3, which is one of the founding members of the CCN family, displays diverse functions. However, this protein generally represses the proliferation of a variety of cells. Along with skeletal development, CCN3 is produced in cartilaginous anlagen, growth plate cartilage and epiphysial cartilage. Interestingly, CCN3 is drastically induced in the growth plates of mice lacking CCN2, which promotes endochondral ossification. Notably, chondrocytes in these mutant mice with elevated CCN3 production also suffer from impaired glycolysis and energy metabolism, suggesting a critical role of CCN3 in cartilage metabolism. Recently, CCN3 was found to be strongly induced by impaired glycolysis, and in our study, we located an enhancer that mediated CCN3 regulation via starvation. Subsequent investigations specified regulatory factor binding to the X-box 1 (RFX1) as a transcription factor mediating this CCN3 regulation. Impaired glycolysis is a serious problem, resulting in an energy shortage in cartilage without vasculature. CCN3 produced under such starved conditions restricts energy consumption by repressing cell proliferation, leading chondrocytes to quiescence and survival. This CCN3 regulatory system is indicated to play an important role in articular cartilage maintenance, as well as in skeletal development. Furthermore, CCN3 continues to regulate cartilage metabolism even during the aging process, probably utilizing this regulatory system. Altogether, CCN3 seems to prevent “overwork” by chondrocytes to ensure their sustainable life in cartilage by sensing energy metabolism. Similar roles are suspected to exist in relation to systemic metabolism, since CCN3 is found in the bloodstream.

Abstract Image

不要过度劳累:细胞通讯网络因子3对于软骨的生命
细胞通信网络因子(CCN) 3是CCN家族的创始成员之一,具有多种功能。然而,这种蛋白通常抑制多种细胞的增殖。随着骨骼发育,CCN3在软骨胶原、生长板软骨和骨骺软骨中产生。有趣的是,CCN3在缺乏CCN2的小鼠生长板中被显著诱导,从而促进软骨内成骨。值得注意的是,这些CCN3产量升高的突变小鼠的软骨细胞也会出现糖酵解和能量代谢受损,这表明CCN3在软骨代谢中起着关键作用。最近,人们发现糖酵解受损会强烈诱导CCN3,在我们的研究中,我们找到了一个通过饥饿介导CCN3调控的增强子。随后的研究确定了与X-box 1结合的调节因子(RFX1)是介导CCN3调控的转录因子。糖酵解受损是一个严重的问题,导致没有血管的软骨能量短缺。在这种饥饿条件下产生的CCN3通过抑制细胞增殖来限制能量消耗,导致软骨细胞静止和存活。该CCN3调控系统在关节软骨维持和骨骼发育中发挥重要作用。此外,CCN3甚至在衰老过程中继续调节软骨代谢,可能利用了这一调节系统。总而言之,CCN3似乎通过感知能量代谢来防止软骨细胞“过度工作”,以确保其在软骨中的可持续生命。由于CCN3存在于血液中,因此怀疑在全身代谢中也存在类似的作用。
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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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