Down-regulation of Transforming Growth Factor-β Receptors: Cooperativity between the Types I, II, and III Receptors and Modulation at the Cell Surface

The types I, II, and III receptors (RI, RII, RIII) for transforming growth factor-β (TGF-β) become down-regulated in response to ligand, presumably via their internalization from the cell surface. This report examines the down-regulation of full-length RI, RII, and RIII in cells endogenously or transiently expressing these receptors. Down-regulation occurred rapidly (within 2 h after TGF-β1 treatment at 37°C) and showed a dose response, between 10 and 200 pM TGF-β1, in cells expressing RI, RII, and RIII (Mv1lu and A549 cells). A comparison between Mv1Lu and mutant cell derivatives R-1B (lacking RI) or DR-26 (lacking RII) indicated that all three receptors were necessary for efficient down-regulation. Down-regulation experiments, utilizing TGF-β-treated 293 cells transiently expressing different combinations of these receptors indicated that neither RII or RIII were down-regulated when expressed alone and that RI was required for maximal down-regulation of RII. RII and RIII were partially down-regulated when these receptors were coexpressed in the absence of RI (in R-1B and 293 cells). Surprisingly, TGF-β receptors were partially down-regulated in Mv1Lu, A549, and 293 cells treated with TGF-β1 at 4°C. Microscopic examination of 293 cells coexpressing RI fused to green fluorescent protein (RI–GFP) and RII indicated that, after treatment with TGF-β1 at 4°C, RI–GFP formed aggregates at the cell surface at this temperature. RI–GFP was not detected at the surface of these cells after TGF-β1 treatment at 37°C. Our results suggest a two phase mechanism for TGF-β1 receptor down-regulation involving receptor modulation (aggregation) at the cell surface and internalization.     

Latent Transforming Growth Factor-β Binding Protein Domains Involved in Activation and Transglutaminase-dependent Cross-Linking of Latent Transforming Growth Factor-β

Transforming growth factor-β (TGF-β) is secreted by many cell types as part of a large latent complex composed of three subunits: TGF-β, the TGF-β propeptide, and the latent TGF-β binding protein (LTBP). To interact with its cell surface receptors, TGF-β must be released from the latent complex by disrupting noncovalent interactions between mature TGF-β and its propeptide. Previously, we identified LTBP-1 and transglutaminase, a cross-linking enzyme, as reactants involved in the formation of TGF-β. In this study, we demonstrate that LTBP-1 and large latent complex are substrates for transglutaminase. Furthermore, we show that the covalent association between LTBP-1 and the extracellular matrix is transglutaminase dependent, as little LTBP-1 is recovered from matrix digests prepared from cultures treated with transglutaminase inhibitors. Three polyclonal antisera to glutathione S–transferase fusion proteins containing amino, middle, or carboxyl regions of LTBP-1S were used to identify domains of LTBP-1 involved in crosslinking and formation of TGF-β by transglutaminase. Antibodies to the amino and carboxyl regions of LTBP-1S abrogate TGF-β generation by vascular cell cocultures or macrophages. However, only antibodies to the amino-terminal region of LTBP-1 block transglutaminase-dependent cross-linking of large latent complex or LTBP-1. To further identify transglutaminase-reactive domains within the amino-terminal region of LTBP-1S, mutants of LTBP-1S with deletions of either the amino-terminal 293 (ΔN293) or 441 (ΔN441) amino acids were expressed transiently in CHO cells. Analysis of the LTBP-1S content in matrices of transfected CHO cultures revealed that ΔN293 LTBP-1S was matrix associated via a transglutaminasedependent reaction, whereas ΔN441 LTBP-1S was not. This suggests that residues 294–441 are critical to the transglutaminase reactivity of LTBP-1S.     

Expression of Recombinant Extracellular Domain of the Type II Transforming Growth Factor-β Receptor: Utilization in a Modified Enzyme-Linked Immunoabsorbent Assay to Screen TGF-β Agonists and Antagonists

TGF-β is a ubiquitous protein that exhibits a broad spectrum of biological activity. The prokaryotic expression and purification of the extracellular domain of the type II TGF-β receptor (TβR-II-ED), without the need for fusion protein cleavage and refolding, is described. The recombinant TβR-II-ED fusion protein bound commercially available TGF-β1 and displayed an affinity of 11.1 nM. In a modified ELISA, receptor binding to TGF-β1 was inhibited by TGF-β3. The technique lends itself to high-throughput screening of combinatorial libraries for the identification of TGF-β agonists and antagonists and this, in turn, may have important therapeutic implications.     

The β4Integrin Subunit Is Expressed in Mouse Fibroblasts and Modulated by Transforming Growth Factor-β1

Integrin β₄subunit is present in association with α₆chain on both normal and transformed epithelial cells. Recently α₆β₄heterodimer was found on the endothelium of medium-sized blood vessels and on immature thymocytes. In this report we show, by Northern blotting, indirect immunofluorescence, immunoprecipitation, and Western blotting, that β₄subunit is expressed also on cells of mesenchymal origin such as fibroblasts, myoblasts, and myotubes. Increased expression of α₆β₄has been related to the aggressive metastatic phenotype of human and murine carcinomas. The transforming growth factor β₁(TGF-β₁) has been found to modulate the expression of several integrins and intracellular matrix proteins, as well as to stimulate cell invasion and metastatic potential. To evaluate whether α₆β₄expression is modulated by TGF-β₁, we transfected 3T3 fibroblasts with an expression vector carrying the human TGF-β₁cDNA driven by the SV40 early promoter. We observed by indirect immunofluorescence a modification in the subcellular distribution of β₄subunit, which acquires a perinuclear localization. This finding suggests this integrin subunit correlates with the cytoskeletal reorganization induced by TGF-β₁.     

Differential Modulation of Integrin Receptors and Extracellular Matrix Laminin by Transforming Growth Factor-β1 in Rat Alveolar Epithelial Cells

The transforming growth factors-β (TGFs-β) family of genes plays important roles in cell growth and differentiation in many cell types. TGFβ modulates the synthesis and accumulation of extracellular matrix (ECM) components and the expression of cell surface receptors for ECM components. TGFβ is increased in alveolar lining fluid during inflammatory reactions of the lung and has been identified in alveolar epithelial cells of developing lungs and hyperplastic type II cells during repair. However, little is known about how TGFβ may regulate expression of extracellular matrix proteins and ECM receptors in lung alveolar epithelial cells. Laminin, a major glycoprotein component of epithelial basement membrane, is synthesized and secreted by alveolar epithelial cells. To study the effects of TGFβ on modulation of laminin and its integrin receptors α₆β₁ and α₃β₁ in lung alveolar epithelial cells, a rat alveolar type II cell-derived cell line, LM5, was incubated with TGFβ₁ (0-100 pg/ml) in serum-free medium for 0-16 h. We examined the expression of integrin subunits and laminin β2 chain (s-laminin) mRNAs and protein expression. By Northern blot analysis, TGFβ₁ induced dose-dependent increases in α₆ and β₁ mRNA levels. TGFβ₁ also increased the expression of laminin β2 chain mRNA at 12-16 h poststimulation. In contrast, TGFβ decreased α₃ mRNA expression. Immunoprecipitation studies of TGFβ₁-treated cells showed increased surface expression of both α₆ and β₁ protein while surface expression of the α₃ integrin subunit was decreased. The same treatment resulted in increased laminin protein expression. These data suggest that TGFβ₁ may regulate alveolar epithelial cell differentiation in part through its modulation of integrins and laminin chains.     

Oligomeric Structure of Type I and Type II Transforming Growth Factor β Receptors: Homodimers Form in the ER and Persist at the Plasma Membrane

Abstract. Transforming growth factor β (TGF-β) signaling involves interactions of at least two different receptors, types I (TβRI) and II (TβRII), which form ligand-mediated heteromeric complexes. Although we have shown in the past that TβRII in the absence of ligand is a homodimer on the cell surface, TβRI has not been similarly investigated, and the site of complex formation is not known for either receptor. Several studies have indicated that homomeric interactions are involved in TGF-β signaling and regulation, emphasizing the importance of a detailed understanding of the homooligomerization of TβRI or TβRII. Here we have combined complementary approaches to study these homomeric interactions in both naturally expressing cell lines and cells cotransfected with various combinations of epitope-tagged type I or type II receptors. We used sedimentation velocity of metabolically labeled receptors on sucrose gradients to show that both TβRI and TβRII form homodimer-sized complexes in the endoplasmic reticulum, and we used coimmunoprecipitation studies to demonstrate the existence of type I homooligomers. Using a technique based on antibody-mediated immunofluorescence copatching of receptors carrying different epitope tags, we have demonstrated ligand-independent homodimers of TβRI on the surface of live cells. Soluble forms of both receptors are secreted as monomers, indicating that the ectodomains are not sufficient to mediate homodimerization, although TGF-β1 is able to promote dimerization of the type II receptor ectodomain. These findings may have important implications for the regulation of TGF-β signaling.     

Specific Activation of Mitogen-activated Protein Kinase by Transforming Growth Factor-β Receptors in Lipid Rafts Is Required for Epithelial Cell Plasticity

Transforming growth factor (TGF)-β regulates a spectrum of cellular events, including cell proliferation, differentiation, and migration. In addition to the canonical Smad pathway, TGF-β can also activate mitogen-activated protein kinase (MAPK), phosphatidylinositol 3-kinase (PI3K)/Akt, and small GTPases in a cell-specific manner. Here, we report that cholesterol depletion interfered with TGF-β–induced epithelial-mesenchymal transition (EMT) and cell migration. This interference is due to impaired activation of MAPK mediated by cholesterol-rich lipid rafts. Cholesterol-depleting agents specifically inhibited TGF-β–induced activation of extracellular signal-regulated kinase (ERK) and p38, but not Smad2/3 or Akt. Activation of ERK or p38 is required for both TGF-β–induced EMT and cell migration, whereas PI3K/Akt is necessary only for TGF-β–promoted cell migration but not for EMT. Although receptor heterocomplexes could be formed in both lipid raft and nonraft membrane compartments in response to TGF-β, receptor localization in lipid rafts, but not in clathrin-coated pits, is important for TGF-β–induced MAPK activation. Requirement of lipid rafts for MAPK activation was further confirmed by specific targeting of the intracellular domain of TGF-β type I receptor to different membrane locations. Together, our findings establish a novel link between cholesterol and EMT and cell migration, that is, cholesterol-rich lipid rafts are required for TGF-β–mediated MAPK activation, an event necessary for TGF-β–directed epithelial plasticity.     

Modulation of Activin Expression by Type β Transforming Growth Factors

Activins are potentially important regulators of early developmental processes in vertebrates. Although the different forms of activin appear to be differentially expressed during early amphibian, avian, and murine development, little is known about the factors that regulate their expression. In this study we report the qualitative effects of several growth and differentiation factors on the expression of inhibin subunits in three differentiated cell lines derived from P19 embryonal carcinoma cells. These cell lines include mesodermal (MES-1), neuroepithelial (EPI-7), and visceral endoderm-like (END-2) cell types, expressing both inhibin β_A and β_B subunit mRNAs. We have shown for the first time that this expression is modulated by transforming growth factor (TGF)β₁ and TGFβ₂ but not significantly by other growth factors such as leukemia inhibitory factor or members of the fibroblast growth factor family (aFGF, bFGF, or kFGF). β_A mRNA expression is increased while β_B expression is simultaneously decreased by TGFβ. Furthermore, TGFβ increased the amount of bioactive activin secreted by MES-1 and END-2 cells. Inhibin α subunit mRNA expression is not affected by TGFβ. These results point to a possible role of type β transforming growth factors as regulators of activin expression in embryonal cells.     

Biphasic Effect of Transforming Growth Factor-β1 on in Vitro Angiogenesis

Although the existence of an increasing number of angiogenesis-regulating cytokines is well documented, the response elicited by combinations of these cytokines is largely unknown. Using an in vitro model in which microvascular endothelial cells can be induced to form capillary-like tubes within three-dimensional collagen or fibrin gels, we have investigated the effect of transforming growth factor-β₁ (TGF-β₁) on basic fibroblast growth factor (bFGF)-induced and vascular endothelial growth factor (VEGF)-induced angiogenesis. Endothelial cell invasion and capillary lumen formation were inhibited by TGF-β1 at relatively high concentrations (5-10 ng/ml), while lower concentrations (100 pg/ml-1 ng/ml) of TGF-β1 potentiated the effect of bFGF- and VEGF-induced invasion. The optimal potentiating effect was observed at 200-500 pg/ml TGF-β1. At invasion-potentiating doses of TGF-beta;1, lumen size in fibrin gels was markedly reduced compared to that in cultures treated with bFGF alone. These results show that TGF-β1 exerts a biphasic effect on bFGF- and VEGF-induced angiogenesis in vitro. Our studies support the notion that the nature of the angiogenic response elicited by a specific cytokine is contextual, i.e., depends on the presence and concentration of other cytokines in the pericellular environment of the responding endothelial cell.     

The Presence and Role of Transmembrane Transforming Growth Factor-α in Cultures of Rat Liver Epithelial Cells

We assessed the presence and the role of membrane TGF-α in two rat liver epithelial cell lines, either parental or transfected with c-fos proto-oncogene. c-fos overexpressing cells had more TGF-α-like activity in their membranes. When TGF-α was removed by elastase or neutralized, the growth rates of both cell lines were markedly reduced, but to a higher extent for parental cells. If membrane TGF-α seemed to play a key contribution in normal cell growth, both cell lines were unable to react to the addition of soluble TGF-α, showing that these two forms of growth factors are not equivalent.     

Dihydrocytochalasin B Enhances Transforming Growth Factor-β-Induced Reexpression of the Differentiated Chondrocyte Phenotype without Stimulation of Collagen Synthesis

Rabbit articular chondrocytes were treated with retinoic acid (RA) to eliminate the differentiated phenotype marked by the synthesis of type II collagen and high levels of proteoglycan. Exposure of such cells to transforming growth factor-β1 (TGF-β1) in secondary culture under serum-free and RA-free, defined conditions led to reexpression of the differentiated phenotype. The microfilament modifying drug, dihydrocytochalasin B (DHCB), enhanced the effectiveness of TGF-β1 and produced a threefold stimulation of type II collagen reexpression (measured by 2-D CNBr peptide mapping) at 0.3 ng/ml TGF-β1 without altering total collagen synthesis. Type II collagen reexpression was maximal from 1 to 5 ng/ml TGF-β1, with or without DHCB. The effect of DHCB on proteoglycan synthesis was maximal at 1 ng/ml TGF-β1. At this dose TGF-β alone produced no increase in ³⁵ SO₄ incorporation, while simultaneous treatment with DHCB caused a sevenfold stimulation of proteoglycan synthesis. DHCB-independent stimulation of proteoglycan reexpression occurred between 5 and 15 ng/ml TGF-β1. In contrast, TGF-β1-dependent stimulation of proteoglycan synthesis in differentiated chondrocytes in primary monolayer culture was not substantially affected by DHCB. The collagen data suggest that TGF-β1 utilizes separate pathways to control phenotypic change and collagen (matrix) synthesis. Microfilament modification by DHCB selectively enhances the effectiveness of the TGF-β1-dependent signaling pathway that controls reexpression of the differentiated phenotype.     

Evidence of Type I and Type II Transforming Growth Factor-β Receptors in Central Nervous Tissues: Changes Induced by Focal Cerebral Ischemia

Abstract: The peptides of the transforming growth factor-β (TGF-β) family transduce their signal through ligand-induced heteromeric complexes that consist of type I and type II serine/threonine kinases. Both TGF-β receptors are abundant in many peripheral tissues, but clear evidence of their expression in cortical astrocytes and neurons has not been published so far. In this study, we investigated the expression of type I and type II TGF-β receptors and their potential ligands (TGF-β1, TGF-β2, and TGF-β3) in the CNS by using RT-PCR and immunohistochemistry. Moreover, to further the study of those cell types that exhibit TGF-β isoforms and related receptors, we examined through the use of RT-PCR whether cortical neurons and astrocytes in culture express the mRNAs for TGF-βs and their receptors. We show that the three TGF-β isoform mRNAs are present in the CNS. However, although astrocytes in culture display all three isoforms, neurons in culture express only TGF-β2. We have demonstrated that both type I and type II TGF-β receptor mRNAs and proteins are present in the CNS and in cultures of cortical neurons and astrocytes. Thus, TGF-βs may act as autocrine and paracrine signals in the CNS between both neurons and astrocytes via the same receptor systems as those found in peripheral tissues. TGF-β1 has been shown to be induced following hypoxic-ischemic brain injury and may play a critical role in the pathophysiology of degenerative processes in the CNS. In the present investigation, we confirmed that the expression of TGF-β1 was increased markedly up until 24 h and thereafter was stable over the first 3 days following permanent occlusion of the middle cerebral artery in mice. However, whereas the expression of the type I TGF-β receptor was not altered by the ischemic insult, the pattern of the type II TGF-β receptors was modified dramatically in the ischemic area 3 days after the occlusion. These data show that, even if ligands are present, they may not be able to transduce their signal. Finally, the present study clearly demonstrates that a knowledge of the expression of ligand-specific receptors following brain injury is a fundamental step in clarifying the involvement of cytokines in neurodegenerative diseases.     

Physical and Functional Interactions between Type I Transforming Growth Factor β Receptors and Bα, a WD-40 Repeat Subunit of Phosphatase 2A

We have previously shown that a WD-40 repeat protein, TRIP-1, associates with the type II transforming growth factor β (TGF-β) receptor. In this report, we show that another WD-40 repeat protein, the Bα subunit of protein phosphatase 2A, associates with the cytoplasmic domain of type I TGF-β receptors. This association depends on the kinase activity of the type I receptor, is increased by coexpression of the type II receptor, which is known to phosphorylate and activate the type I receptor, and allows the type I receptor to phosphorylate Bα. Furthermore, Bα enhances the growth inhibition activity of TGF-β in a receptor-dependent manner. Because Bα has been characterized as a regulator of phosphatase 2A activity, our observations suggest possible functional interactions between the TGF-β receptor complex and the regulation of protein phosphatase 2A.     

Interactions between Growth Factors and Integrins: Latent Forms of Transforming Growth Factor-β Are Ligands for the Integrin αvβ1

The multipotential cytokine transforming growth factor-β (TGF-β) is secreted in a latent form. Latency results from the noncovalent association of TGF-β with its processed propeptide dimer, called the latency-associated peptide (LAP); the complex of the two proteins is termed the small latent complex. Disulfide bonding between LAP and latent TGF-β–binding protein (LTBP) produces the most common form of latent TGF-β, the large latent complex. The extracellular matrix (ECM) modulates the activity of TGF-β. LTBP and the LAP propeptides of TGF-β (isoforms 1 and 3), like many ECM proteins, contain the common integrin-binding sequence RGD. To increase our understanding of latent TGF-β function in the ECM, we determined whether latent TGF-β1 interacts with integrins. A549 cells adhered and spread on plastic coated with LAP, small latent complex, and large latent complex but not on LTBP-coated plastic. Adhesion was blocked by an RGD peptide, and cells were unable to attach to a mutant form of recombinant LAP lacking the RGD sequence. Adhesion was also blocked by mAbs to integrin subunits αv and β1. We purified LAP-binding integrins from extracts of A549 cells using LAP bound to Sepharose. αvβ1 eluted with EDTA. After purification in the presence of Mn²⁺, a small amount of αvβ5 was also detected. A549 cells migrated equally on fibronectin- and LAP-coated surfaces; migration on LAP was αvβ1 dependent. These results establish αvβ1 as a LAP-β1 receptor. Interactions between latent TGF-β and αvβ1 may localize latent TGF-β to the surface of specific cells and may allow the TGF-β1 gene product to initiate signals by both TGF-β receptor and integrin pathways.     

Distinct Endocytic Responses of Heteromeric and Homomeric Transforming Growth Factor β Receptors

Transforming growth factor β (TGFβ) family ligands initiate a cascade of events capable of modulating cellular growth and differentiation. The receptors responsible for transducing these cellular signals are referred to as the type I and type II TGFβ receptors. Ligand binding to the type II receptor results in the transphosphorylation and activation of the type I receptor. This heteromeric complex then propagates the signal(s) to downstream effectors. There is presently little data concerning the fate of TGFβ receptors after ligand binding, with conflicting reports indicating no change or decreasing cell surface receptor numbers. To address the fate of ligand-activated receptors, we have used our previously characterized chimeric receptors consisting of the ligand binding domain from the granulocyte/macrophage colony-stimulating factor α or β receptor fused to the transmembrane and cytoplasmic domain of the type I or type II TGFβ receptor. This system not only provides the necessary sensitivity and specificity to address these types of questions but also permits the differentiation of endocytic responses to either homomeric or heteromeric intracellular TGFβ receptor oligomerization. Data are presented that show, within minutes of ligand binding, chimeric TGFβ receptors are internalized. However, although all the chimeric receptor combinations show similar internalization rates, receptor down-regulation occurs only after activation of heteromeric TGFβ receptors. These results indicate that effective receptor down-regulation requires cross-talk between the type I and type II TGFβ receptors and that TGFβ receptor heteromers and homomers show distinct trafficking behavior.     

Transforming Growth Factor-β1 Differentially Regulates Proliferation, Morphology, and Extracellular Matrix Expression by Three Neural Crest-Derived Neuroblastoma Cell Lines

We reported previously (S. L. Rogers, P. J. Gegick, S. M. Alexander, and P. G. McGuire, Dev. Biol. 151, 191-203, 1992) that transforming growth factor-β1 (TGFβ1) inhibited proliferation, up-regulated fibronectin synthesis, and suppressed melanogenesis in a population of quail neural crest cells in vitro. Here, we report that cell lines derived from the parent SK-N-SH neuroblastoma line (R. A. Ross, B. A. Spengler, and J. L. Biedler, J. Natl. Cancer Inst. 71, 741-747, 1983) respond differentially to TGFβ1, and their responses provide further insights into the actions of this growth factor on neural crest subpopulations. The SH-EP cell line exhibits primarily nonneuronal traits and responded to TGFβ1 with increased thymidine uptake after 6 days of culture, increased expression of fibronectin mRNA and protein, and decreased laminin synthesis. Many SH-EP cells also acquired a dramatically elongated morphology, reminiscent of Schwann cells in culture. Thymidine uptake by the neuronal SY5Y cell line was not substantially altered. Neither fibronectin mRNA nor protein was detectable in either TGFβ1-treated or untreated cultures, although laminin synthesis was upregulated by the growth factor. In TGFβ1-treated cultures of the intermediate SH-IN cell line, which has been reported to display both neuronal and nonneuronal characteristics, there was marked flattening of many cells, a steady decrease in thymidine uptake, and increased expression of both fibronectin and laminin. The observed responses of SH-IN cells mimic those observed in primary neural crest cultures and appear to represent similar differentiation toward a mesenchymal phenotype. These results substantiate the idea that closely related but diverging neural crest-derived cell types respond selectively to TGFβ1 and demonstrate that these SK-N-SH-derived cell lines will be useful in experimental approaches that will allow us to infer mechanisms underlying regulation of neural crest differentiation.