Xu Xin, Francis Richard, Wei Chih Jen, Linask Kaari L, Lo Cecilia W
Laboratory of Developmental Biology, National Heart, Lung and Blood Institute, National Institutes of Health, Bethesda, MD 20850, USA.
Development. 2006 Sep;133(18):3629-39. doi: 10.1242/dev.02543. Epub 2006 Aug 16.
Connexin 43 knockout (Cx43alpha1KO) mice have conotruncal heart defects that are associated with a reduction in the abundance of cardiac neural crest cells (CNCs) targeted to the heart. In this study, we show CNCs can respond to changing fibronectin matrix density by adjusting their migratory behavior, with directionality increasing and speed decreasing with increasing fibronectin density. However, compared with wild-type CNCs, Cx43alpha1KO CNCs show reduced directionality and speed, while CNCs overexpressing Cx43alpha1 from the CMV43 transgenic mice show increased directionality and speed. Altered integrin signaling was indicated by changes in the distribution of vinculin containing focal contacts, and altered temporal response of Cx43alpha1KO and CMV43 CNCs to beta1 integrin function blocking antibody treatment. High resolution motion analysis showed Cx43alpha1KO CNCs have increased cell protrusive activity accompanied by the loss of polarized cell movement. They exhibited an unusual polygonal arrangement of actin stress fibers that indicated a profound change in cytoskeletal organization. Semaphorin 3A, a chemorepellent known to inhibit integrin activation, was found to inhibit CNC motility, but in the Cx43alpha1KO and CMV43 CNCs, cell processes failed to retract with semaphorin 3A treatment. Immunohistochemical and biochemical analyses suggested close interactions between Cx43alpha1, vinculin and other actin-binding proteins. However, dye coupling analysis showed no correlation between gap junction communication level and fibronectin plating density. Overall, these findings indicate Cx43alpha1 may have a novel function in mediating crosstalk with cell signaling pathways that regulate polarized cell movement essential for the directional migration of CNCs.
连接蛋白43基因敲除(Cx43α1KO)小鼠患有圆锥动脉干心脏缺陷,这与靶向心脏的心脏神经嵴细胞(CNCs)数量减少有关。在本研究中,我们发现CNCs能够通过调整其迁移行为来响应纤连蛋白基质密度的变化,随着纤连蛋白密度增加,方向性增强而速度降低。然而,与野生型CNCs相比,Cx43α1KO CNCs的方向性和速度降低,而来自CMV43转基因小鼠的过表达Cx43α1的CNCs的方向性和速度增加。含纽蛋白的粘着斑分布变化以及Cx43α1KO和CMV43 CNCs对β1整合素功能阻断抗体处理的时间反应改变表明整合素信号传导发生了改变。高分辨率运动分析显示,Cx43α1KO CNCs的细胞突出活动增加,同时细胞极性运动丧失。它们表现出肌动蛋白应力纤维异常的多边形排列,这表明细胞骨架组织发生了深刻变化。已知可抑制整合素激活的化学排斥分子Semaphorin 3A被发现可抑制CNC运动,但在Cx43α1KO和CMV43 CNCs中,用Semaphorin 3A处理后细胞突起未能缩回。免疫组织化学和生化分析表明Cx43α1、纽蛋白和其他肌动蛋白结合蛋白之间存在密切相互作用。然而,染料偶联分析显示间隙连接通讯水平与纤连蛋白铺板密度之间没有相关性。总体而言,这些发现表明Cx43α1可能在介导与调节CNCs定向迁移所必需的极性细胞运动的细胞信号通路的串扰中具有新功能。
