Vivien D, Attisano L, Wrana J L, Massagué J
Cell Biology and Genetics Program, Memorial Sloan-Kettering Cancer Center, New York, New York 10021, USA.
J Biol Chem. 1995 Mar 31;270(13):7134-41. doi: 10.1074/jbc.270.13.7134.
Transforming growth factor-beta (TGF-beta) signaling in Mv1Lu lung epithelial cells requires coexpression of TGF-beta receptors I (T beta R-I) and II (T beta R-II), two distantly related transmembrane serine/threonine kinases that form a heteromeric complex upon ligand binding. Here, we examine the formation of TGF-beta receptor homo-oligomers and their possible contribution to signaling. T beta R-I can contact ligand bound to T beta R-II, but not ligand free in the medium, and thus cannot form ligand-induced homo-oligomers. T beta R-II, which binds ligand on its own, formed oligomeric complexes when overexpressed in transfected COS cells. However, these complexes were largely ligand-independent and involved immature receptor protein. Since ligand-induced homo-oligomers could not be obtained with the wild-type TGF-beta receptors, we studied receptor cytoplasmic domain homo-oligomerization by using receptor chimeras. The extracellular domain of T beta R-II was fused to the transmembrane and cytoplasmic domains of T beta R-I, yielding T beta R-II/I, and the extracellular domain of T beta R-I was fused to the transmembrane and cytoplasmic domains of T beta R-II, yielding T beta R-I/II. When contransfected with wild-type receptors and exposed to ligand, T beta R-II/I formed a complex with T beta R-I, and T beta R-I/II formed a complex with T beta R-II, thus yielding complexes with homologous cytoplasmic domains. T beta R-II/I transfected alone or with T beta R-I did not restore TGF-beta responsiveness in T beta R-II-defective cell mutants. Furthermore, T beta R-II/I acted in a dominant negative fashion, inhibiting restoration of TGF-beta responsiveness by a cotransfected T beta R-II in T beta R-II-defective cells and by a cotransfected T beta R-I in T beta R-I-defective cells. Similarly, T beta R-I/II transfected alone or with T beta R-II did not restore TGF-beta responsiveness and acted in a dominant negative fashion against T beta R-I. Together with previous genetic and biochemical evidence, these results suggest that TGF-beta mediates transcriptional and antiproliferative responses through the heteromeric T beta R-I.T beta R-II complex and not through homo-oligomeric T beta R-I or T beta R-II complexes.
在Mv1Lu肺上皮细胞中,转化生长因子-β(TGF-β)信号传导需要TGF-β受体I(TβR-I)和II(TβR-II)的共表达,这两种受体是远亲关系的跨膜丝氨酸/苏氨酸激酶,在配体结合后形成异源复合物。在此,我们研究了TGF-β受体同型寡聚体的形成及其对信号传导的可能贡献。TβR-I可以与结合在TβR-II上的配体接触,但不能与培养基中游离的配体接触,因此不能形成配体诱导的同型寡聚体。TβR-II自身能够结合配体,在转染的COS细胞中过表达时会形成寡聚体复合物。然而,这些复合物在很大程度上不依赖配体,并且涉及未成熟的受体蛋白。由于野生型TGF-β受体无法获得配体诱导的同型寡聚体,我们通过使用受体嵌合体研究了受体胞质结构域的同型寡聚化。TβR-II的胞外结构域与TβR-I的跨膜和胞质结构域融合,产生TβR-II/I,TβR-I的胞外结构域与TβR-II的跨膜和胞质结构域融合,产生TβR-I/II。当与野生型受体共转染并暴露于配体时,TβR-II/I与TβR-I形成复合物,TβR-I/II与TβR-II形成复合物,从而产生具有同源胞质结构域的复合物。单独转染或与TβR-I一起转染的TβR-II/I不能恢复TβR-II缺陷细胞突变体中的TGF-β反应性。此外,TβR-II/I以显性负性方式起作用,抑制共转染的TβR-II在TβR-II缺陷细胞中以及共转染的TβR-I在TβR-I缺陷细胞中恢复TGF-β反应性。同样,单独转染或与TβR-II一起转染的TβR-I/II不能恢复TGF-β反应性,并以显性负性方式对抗TβR-I。与先前的遗传学和生化证据一起,这些结果表明TGF-β通过异源TβR-I.TβR-II复合物介导转录和抗增殖反应,而不是通过同型寡聚体TβR-I或TβR-II复合物。
