Browsing by keyword "Activin Receptors"
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A surface component on GH3 pituitary cells that recognizes transforming growth factor-beta, activin, and inhibinWe have examined the ability of various forms of activin and inhibin, which are structurally related to transforming growth factor-beta (TGF-beta), to interact with various types of cell surface TGF-beta binding sites. Activin AB, inhibin A, and inhibin B were unable to compete with 125I-TGF-beta 1 for binding to the TGF-beta receptor types I, II, or III that coexist in human skin fibroblasts, rat liver epithelial cells, and mink lung epithelial cells. In contrast, activins and inhibins effectively competed for TGF-beta 1 binding to GH3 rat pituitary tumor cells. Binding of TGF-beta 1 to GH3 cells was mediated by about 2700 sites/cell with a Kd = 90 pM. Affinity labeling of these GH3 binding sites by cross-linking to 125I-TGF-beta 1 yielded 70-74-kDa labeled complexes distinct from previously identified TGF-beta binding components. Labeling of these 70-74-kDa components with 125I-TGF-beta 1 was inhibited by TGF-beta 1, TGF-beta 2, activin AB, and inhibin B at concentrations in the high picomolar to low nanomolar range, but it was not significantly affected by other polypeptide hormones and growth factors tested. The 70-74-kDa labeled GH3 components represent a novel type of cell surface TGF-beta binding protein that is unique in its ability to recognize various other members of the TGF-beta family of bioactive polypeptides.
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Mullerian Inhibiting Substance Recruits ALK3 to Regulate Leydig Cell DifferentiationMullerian inhibiting substance (MIS) not only induces Mullerian duct regression during male sexual differentiation but also modulates Leydig cell steroidogenic capacity and differentiation. MIS actions are mediated through a complex of homologous receptors: a type II ligand-binding receptor [MIS type II receptor (MISRII)] and a tissue-specific type I receptor that initiates downstream signaling. The putative MIS type I receptors responsible for Mullerian duct regression are activin A type II receptor, type I [Acvr1/activin receptor-like kinase 2 (ALK2)], ALK3, and ALK6, but the one recruited by MIS in Leydig cells is unknown. To identify whether ALK3 is the specific type I receptor partner for MISRII in Leydig cells, we generated Leydig cell-specific ALK3 conditional knockout mice using a Cre-lox system and compared gene expression and steroidogenic capacity in Leydig cells of ALK3(fx/fx)Cyp17(cre+) and control mice (ALK3(fx/fx)Cyp17(cre-) or ALK3(fx/wt)Cyp17(cre-) littermates). We found reduced mRNA expression of the genes encoding P450c17, StAR, and two enzymes (17betaHSD-III and 3betaHSD-VI) that are expressed in differentiated adult Leydig cells and increased expression of androgen-metabolizing enzymes (3alpha-HSD and SRD5A2) and proliferating cell nuclear antigen (PCNA) in Leydig cells of ALK3(fx/fx)Cyp17(cre+) mice. Despite down-regulation of steroidogenic capacity in ALK3(fx/fx)Cyp17(cre+) mice, the loss of MIS signaling also stimulates Leydig cell proliferation such that plasma testosterone and androstenedione concentrations are comparable to that of control mice. Collectively, these results indicate that the phenotype in ALK3 conditional knockout mice is similar to that of the MIS-knockout mice, confirming that ALK3 is the primary type I receptor recruited by the MIS-MISRII complex during Leydig cell differentiation.
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The Drosophila Activin-like ligand Dawdle signals preferentially through one isoform of the Type-I receptor BaboonHow TGF-beta-type ligands achieve signaling specificity during development is only partially understood. Here, we show that Dawdle, one of four Activin-type ligands in Drosophila, preferentially signals through Babo(c), one of three isoforms of the Activin Type-I receptor that are expressed during development. In cell culture, Dawdle signaling is active in the presence of the Type-II receptor Punt but not Wit, demonstrating that the Type-II receptor also contributes to the specificity of the signaling complex. During development, different larval tissues express unique combinations of these receptors, and ectopic expression of Babo(c) in a tissue where it is not normally expressed at high levels can make that tissue sensitive to Dawdle signaling. These results reveal a mechanism by which distinct cell types can discriminate between different Activin-type signals during development as a result of differential expression of Type-I receptor isoforms.