Jaganathan Bithiah Grace, Ruester Brigitte, Dressel Lars, Stein Stefan, Grez Manuel, Seifried Erhard, Henschler Reinhard
Institute of Transfusion Medicine and Immune Hematology, University Hospital Frankfurt, Sandhofstrasse 1, Frankfurt, Germany.
Stem Cells. 2007 Aug;25(8):1966-74. doi: 10.1634/stemcells.2007-0167. Epub 2007 May 17.
Although mesenchymal stromal cells (MSCs) are being increasingly used as cell therapeutics in clinical trials, the mechanisms that regulate their chemotactic migration behavior are incompletely understood. We aimed to better define the ability of the GTPase regulator of cytoskeletal activation, Rho, to modulate migration induction in MSCs in a transwell chemotaxis assay. We found that culture-expanded MSCs migrate poorly toward exogenous phospholipids lysophosphatidic acid (LPA) and sphingosine-1-phosphate (S1P) in transwell assays. Moreover, plasma-induced chemotactic migration of MSCs was even inhibited after pretreatment with LPA. LPA treatment activated intracellular Rho and increased actin stress fibers in resident MSCs. Very similar cytoskeletal changes were observed after microinjection of a cDNA encoding constitutively active RhoA (RhoAV14) in MSCs. In contrast, microinjection of cDNA encoding Rho inhibitor C3 transferase led to resolution of actin stress fibers, appearance of a looser actin meshwork, and increased numbers of cytoplasmic extensions in the MSCs. Surprisingly, in LPA-pretreated MSCs migrating toward plasma, simultaneous addition of Rho inhibitor C2I-C3 reversed LPA-induced migration suppression and led to improved migration. Moreover, addition of Rho inhibitor C2I-C3 resulted in an approximately 3- to 10-fold enhancement of chemotactic migration toward LPA, S1P, as well as platelet-derived growth factor or hepatocyte growth factor. Thus, inhibition of Rho induces rearrangement of actin cytoskeleton in MSCs and renders them susceptible to induction of migration by physiological stimuli. Disclosure of potential conflicts of interest is found at the end of this article.
尽管间充质基质细胞(MSCs)在临床试验中越来越多地被用作细胞治疗剂,但其调节趋化性迁移行为的机制仍未完全了解。我们旨在通过Transwell趋化性分析更好地确定细胞骨架激活的GTPase调节因子Rho调节MSCs迁移诱导的能力。我们发现,在Transwell分析中,培养扩增的MSCs对外源性磷脂溶血磷脂酸(LPA)和1-磷酸鞘氨醇(S1P)的迁移能力较差。此外,LPA预处理后,血浆诱导的MSCs趋化性迁移甚至受到抑制。LPA处理激活了驻留MSCs中的细胞内Rho,并增加了肌动蛋白应力纤维。在MSCs中显微注射编码组成型活性RhoA(RhoAV14)的cDNA后,观察到非常相似的细胞骨架变化。相反,显微注射编码Rho抑制剂C3转移酶的cDNA导致MSCs中肌动蛋白应力纤维消失,出现更松散的肌动蛋白网络,并且细胞质延伸数量增加。令人惊讶的是,在向血浆迁移的LPA预处理的MSCs中,同时添加Rho抑制剂C2I-C3可逆转LPA诱导的迁移抑制并改善迁移。此外,添加Rho抑制剂C2I-C3导致对LPA、S1P以及血小板衍生生长因子或肝细胞生长因子的趋化性迁移增强约3至10倍。因此,抑制Rho会诱导MSCs中肌动蛋白细胞骨架的重排,并使它们易于受到生理刺激诱导的迁移。潜在利益冲突的披露见本文末尾。
