Miyakawa Y, Rojnuckarin P, Habib T, Kaushansky K
Division of Hematology, University of Washington School of Medicine, Seattle 98195, USA.
J Biol Chem. 2001 Jan 26;276(4):2494-502. doi: 10.1074/jbc.M002633200. Epub 2000 Oct 27.
Thrombopoietin (TPO) is a recently characterized member of the hematopoietic growth factor family that serves as the primary regulator of megakaryocyte (MK) and platelet production. The hormone acts by binding to the Mpl receptor, the product of the cellular proto-oncogene c-mpl. Although many downstream signaling targets of TPO have been identified in cell lines, primary MKs, and platelets, the molecular mechanism(s) by which many of these molecules are activated remains uncertain. In this report we demonstrate that the TPO-induced activation of phosphoinositol 3-kinase (PI3K), a signaling intermediate vital for cellular survival and proliferation, occurs through its association with inducible signaling complexes in both BaF3 cells engineered to express Mpl (BaF3/Mpl) and in primary murine MKs. Although a direct association between PI3K and Mpl could not be demonstrated, we found that several proteins, including SHP2, Gab2, and IRS2, undergo phosphorylation and association in BaF3/Mpl cells in response to TPO stimulation, complexes that recruit and enhance the enzymatic activity of PI3K. To verify the physiological relevance of the complex, SHP2-Gab2 association was disrupted by overexpressing a dominant negative SHP2 construct. TPO-induced Akt phosphorylation was significantly decreased in transfected cells suggesting an important role of SHP2 in the complex to enhance PI3K activity. In primary murine MKs, TPO also induced phosphorylation of SHP2, its association with p85 and enhanced PI3K activity, but in contrast to the results in cell lines, neither Gab2 nor IRS2 are phosphorylated in MKs. Instead, a 100-kDa tyrosine-phosphorylated protein (pp100) co-immunoprecipitated with the regulatory subunit of PI3K. These findings support a model where PI3K activity is dependent on its recruitment into TPO-induced multiphosphoprotein complexes, implicate the existence of a scaffolding protein in primary MKs distinct from the known Gab and IRS proteins, and suggest that, in contrast to erythroid progenitor cells that employ Gab1 in PI3K signaling complexes, utilization of an alternate member of the Gab/IRS family could be responsible for specificity in TPO signaling.
血小板生成素(TPO)是造血生长因子家族中最近被鉴定出的成员,它是巨核细胞(MK)和血小板生成的主要调节因子。该激素通过与Mpl受体结合发挥作用,Mpl受体是细胞原癌基因c-mpl的产物。尽管在细胞系、原代MK和血小板中已经鉴定出许多TPO的下游信号靶点,但这些分子中许多被激活的分子机制仍不确定。在本报告中,我们证明TPO诱导的磷酸肌醇3激酶(PI3K)激活,这是一种对细胞存活和增殖至关重要的信号中间体,通过其与在工程化表达Mpl的BaF3细胞(BaF3/Mpl)和原代小鼠MK中的诱导性信号复合物的结合而发生。尽管无法证明PI3K与Mpl之间存在直接关联,但我们发现包括SHP2、Gab2和IRS2在内的几种蛋白质在BaF3/Mpl细胞中响应TPO刺激时会发生磷酸化和结合,这些复合物募集并增强PI3K的酶活性。为了验证该复合物的生理相关性,通过过表达显性负性SHP2构建体破坏了SHP2-Gab2的结合。在转染细胞中,TPO诱导的Akt磷酸化显著降低,表明SHP2在复合物中增强PI3K活性中起重要作用。在原代小鼠MK中,TPO也诱导SHP2磷酸化,其与p85结合并增强PI3K活性,但与细胞系中的结果相反,MK中Gab2和IRS2均未磷酸化。相反,一种100 kDa的酪氨酸磷酸化蛋白(pp100)与PI3K的调节亚基共免疫沉淀。这些发现支持了一种模型,即PI3K活性依赖于其被募集到TPO诱导的多磷酸蛋白复合物中,暗示原代MK中存在一种不同于已知Gab和IRS蛋白 的支架蛋白,并表明,与在PI3K信号复合物中使用Gab1的红系祖细胞相反,Gab/IRS家族的另一个成员的利用可能是TPO信号特异性的原因。
