Wei L, Zhou W, Croissant J D, Johansen F E, Prywes R, Balasubramanyam A, Schwartz R J
Department of Cell Biology, Department of Medicine, Baylor College of Medicine, Houston, Texas 77030, USA.
J Biol Chem. 1998 Nov 13;273(46):30287-94. doi: 10.1074/jbc.273.46.30287.
Serum response factor (SRF) plays a central role during myogenesis, being required for the expression of striated alpha-actin genes. As shown here, the small GTPase RhoA-dependent activation of SRF results in the expression of muscle-specific genes, thereby promoting myogenic differentiation in myoblast cell lines. Co-expression of activated V14-RhoA and SRF results in an approximately 10-fold activation of the skeletal alpha-actin promoter in replicating myoblasts, while SRFpm1, a dominant negative SRF mutant, blocks RhoA dependent skeletal alpha-actin promoter activity. Serum withdrawal further potentiates RhoA- and SRF-mediated activation of alpha-actin promoter to about 30-fold in differentiated myotubes. In addition, the proximal SRE1 in the skeletal alpha-actin promoter is sufficient to mediate RhoA signaling via SRF. Furthermore, SRFpm1 and to a lesser extent dominant negative N19-RhoA inhibit myoblast fusion, postreplicative myogenic differentiation, and expression of direct SRF targets such as skeletal alpha-actin and indirect targets such as myogenin and alpha-myosin heavy chain. Moreover, RhoA also stimulates the autoregulatable murine SRF gene promoter in myoblasts, and the expression level of SRF is reduced in myoblasts overexpressing N19-RhoA. Our study supports the concept that RhoA signaling via SRF serves as an obligatory muscle differentiation regulatory pathway.
血清反应因子(SRF)在肌生成过程中起核心作用,是横纹肌α-肌动蛋白基因表达所必需的。如本文所示,小GTP酶RhoA依赖的SRF激活导致肌肉特异性基因的表达,从而促进成肌细胞系中的肌源性分化。共表达活化的V14-RhoA和SRF可使复制中的成肌细胞中骨骼肌α-肌动蛋白启动子的活性激活约10倍,而显性负性SRF突变体SRFpm1则阻断RhoA依赖的骨骼肌α-肌动蛋白启动子活性。血清撤除进一步增强RhoA和SRF介导的α-肌动蛋白启动子在分化的肌管中的激活,使其达到约30倍。此外,骨骼肌α-肌动蛋白启动子中的近端SRE1足以通过SRF介导RhoA信号传导。此外,SRFpm1以及程度较轻的显性负性N19-RhoA抑制成肌细胞融合、复制后肌源性分化以及直接SRF靶标(如骨骼肌α-肌动蛋白)和间接靶标(如肌细胞生成素和α-肌球蛋白重链)的表达。此外,RhoA还刺激成肌细胞中可自动调节的小鼠SRF基因启动子,并且在过表达N19-RhoA的成肌细胞中SRF的表达水平降低。我们的研究支持这样的概念,即通过SRF的RhoA信号传导作为一种必需的肌肉分化调节途径。
