Transforming growth factor-β receptors

Transforming growth factor beta (TGF-) binds specifically and with high affinity to several different cell surface proteins. Low M_r proteins of 50,000 and 80,000 have been termed type I and type II receptors. Intermediate sized binding components of 115,000–140,000 M_r and a high binding components of approximately 250,000 M_r in subunit size have been termed type III receptors. The high M_r component is a proteoglycan containing the glycosaminoglycan chains of heparan sulfate and chondroitin sulfate and the intermediate sized components are its core proteins. Although almost all cells have TGF- receptors, binding of TGF- to the type III binding components is restricted to cells of fibroblastic, osteoblastic and chondroblastic origin. The physiological relevance of each individual binding class is unclear. However, recent data indicate that the type III protein does not transmit signals to inhibit cell proliferation, induce protein synthesis, or promote cytomorphological change and that these activities may be mediated through the type I receptor. The mechanism of signal transduction remains unknown, but it does not appear to be associated with tyrosine phosphorylation or phosphorylation of the 40s ribosomal protein S6.Abbreviations TGF Transforming Growth Factor - GAG Glycosaminoglycan - EGF Epidermal Growth Factor     

Transforming growth factor-β activates c-Myc to promote palatal growth

During palatogenesis, the palatal mesenchyme undergoes increased cell proliferation resulting in palatal growth, elevation and fusion of the two palatal shelves. Interestingly, the palatal mesenchyme expresses all three transforming growth factor (TGF) β isoforms (1, 2, and 3) throughout these steps of palatogenesis. However, the role of TGFβ in promoting proliferation of palatal mesenchymal cells has never been explored. The purpose of this study was to identify the effect of TGFβ on human embryonic palatal mesenchymal (HEPM) cell proliferation. Our results showed that all isoforms of TGFβ, especially TGFβ3, increased HEPM cell proliferation by up‐regulating the expression of cyclins and cyclin‐dependent kinases as well as c‐Myc oncogene. TGFβ activated both Smad‐dependent and Smad‐independent pathways to induce c‐Myc gene expression. Furthermore, TBE1 is the only functional Smad binding element (SBE) in the c‐Myc promoter and Smad4, activated by TGFβ, binds to the TBE1 to induce c‐Myc gene activity. We conclude that HEPM proliferation is manifested by the induction of c‐Myc in response to TGFβ signaling, which is essential for complete palatal confluency. Our data highlights the potential role of TGFβ as a therapeutic molecule to correct cleft palate by promoting growth. J. Cell. Biochem. 113: 3069–3085, 2012. © 2012 Wiley Periodicals, Inc.     

Transforming growth factor-β and the hallmarks of cancer

Tumorigenesis is in many respects a process of dysregulated cellular evolution that drives malignant cells to acquire six phenotypic hallmarks of cancer, including their ability to proliferate and replicate autonomously, to resist cytostatic and apoptotic signals, and to induce tissue invasion, metastasis, and angiogenesis. Transforming growth factor-β (TGF-β) is a potent pleiotropic cytokine that functions as a formidable barrier to the development of cancer hallmarks in normal cells and tissues. Paradoxically, tumorigenesis counteracts the tumor suppressing activities of TGF-β, thus enabling TGF-β to stimulate cancer invasion and metastasis. Fundamental gaps exist in our knowledge of how malignant cells overcome the cytostatic actions of TGF-β, and of how TGF-β stimulates the acquisition of cancer hallmarks by developing and progressing human cancers. Here we review the molecular and cellular mechanisms that underlie the ability of TGF-β to mediate tumor suppression in normal cells, and conversely, to facilitate cancer progression and disease dissemination in malignant cells.     

The Smad pathway in transforming growth factor-β signaling

The transforming growth factor b (TGF-b) superfamily comprises a great number of structurally related polypeptide growth factors, such as TGF-bs, activins, inhibins, bone morphogenic proteins (BMPs), growth differentiation factors (GDFs), M黮lerian inhibitory substance, and glial cell-derived neurotrophic factor (GDNF), etc[1]. The TGF-b superfamily members are multifunctional agonists involved in a broad spectrum of biological processes such as cell proliferation and differentiation, e…     

Inhibin and activin modulate transforming growth factor-β-induced immunosuppression

Inhibin, activin, and transforming growth factor (TGF) inhibited lipopoly-saccharide (LPS)-induced lymphocyte proliferation in a dose-dependent fashion. These induced suppressions were neutralized by coincubation of a preparation of antibodies to inhibin and TGF, respectively. Inhibin and activin also facilitated TGF-mediated immunosuppression of LPS-induced proliferation of splenocytes. These gonadal proteins showed no effect on phytohemagglutinin-or concanavalin A (Con-A)-induced proliferation of lymphocytes. However, inhibin facilitated and activin inhibited the TGF-mediated immunosuppression in thymocytes stimulated by Con-A. These findings suggest that inhibin or activin by itself, and/or together with TGF, may play an important role in immune response.     

Differential in vitro phenotype pattern, transforming growth factor-β1 activity and mRNA expression of transforming growth factor-β1 in Apert osteoblasts

The phenotype of Apert osteoblasts differs from that of normal osteoblasts in the accumulation of macromolecules in the extracellular matrix. Apert osteoblasts increase type I collagen, fibronectin and glycosaminoglycans secretion compared with normal osteoblasts. Because the extracellular matrix macromolecule accumulation is greatly modulated by transforming growth factor-beta(1), we examined the ability of normal and Apert osteoblasts to secrete transforming growth factor-beta(1) by CCL-64 assay and to produce transforming growth factor-beta(1 )by analysis of the mRNA expression of transforming growth factor-beta(1). Northern blot analysis revealed an increased amount of transforming growth factor-beta(1) mRNA expression in Apert osteoblasts compared with normal ones. Moreover, the level of the active transforming growth factor-beta(1) isoform was higher in Apert than in normal media. In pathologic cells, the increase in transforming growth factor-beta(1) gene expression was associated with a parallel increase in the factor secreted into the medium. The level of transforming growth factor-beta(1) was decreased by the addition of basic fibroblast growth factor. Transforming growth factor-beta(1) is controlled temporally and spatially during skeletal tissue development and produces complex stimulatory and inhibitory changes in osteoblast functions. We hypothesise that in vitro differences between normal and Apert osteoblasts may be correlated to different transforming growth factor-beta(1) cascade patterns, probably due to an altered balance between transforming growth factor-beta(1) and basic fibroblast growth factor.     

Transforming growth factor-β receptors: Role in physiology and disease

Transforming growth factor- (TGF-) plays a pivotal role in numerous vital cellular activities, most significantly the regulation of cellular proliferation and differentiation and synthesis of extracellular matrix components. Its ubiquitous presence in different tissues and strict conservation of nucleotide sequence down through the most primitive vertebrate organisms underscore the essential nature of this family of molecules. The effects of TGF- are mediated by a family of dedicated receptors, the TGF- types I, II, and III receptors. It is now known that a wide variety of human pathology can be caused by aberrant expression and function of these receptors or their cognate ligands. The coding sequence of the human type II receptor appears to render it uniquely susceptible to DNA replication errors in the course of normal cell division. There are now substantial data suggesting that TGF- type II receptor should be considered a tumor suppressor gene. High levels of mutation in the TGF- type II receptor gene have been observed in a wide variety of primarily epithelial malignancies, including colon, gastric, and hepatic cancer. It appears likely that mutation of the TGF- type II receptor gene represents a very critical step in the pathway of carcinogenesis.     

Aging,osteoarthritis and transforming growth factor-β signaling in cartilage

Osteoarthritis is a common malady of the musculoskeletal system affecting the articular cartilage. The increased frequency of osteoarthritis with aging indicates the complex etiology of this disease, which includes pathophysiology and joint stability including biomechanics. The balance between anabolic morphogens and growth factors and catabolic cytokines is at the crux of the problem of osteoarthritis. One such signal is transforming growth factor-β (TGF-β). The impaired TGF-β signaling has been identified as a culprit in old mice in a recent article in this journal. This commentary places this discovery in the context of anabolic and catabolic signals and articular cartilage homeostasis in the joint.     

Hyaluronan facilitates transforming growth factor-β1-dependent proliferation via CD44 and epidermal growth factor receptor interaction

Fibroblast proliferation is an early feature of progressive tissue fibrosis and is largely regulated by the cytokine transforming growth factor-β1 (TGF-β1). In the oral mucosa, fibroblasts have a unique phenotype and demonstrate healing with no fibrosis/scarring. Our previous studies show that whereas dermal fibroblasts proliferate in response to TGF-β1, oral fibroblasts have an antiproliferative response to this cytokine. Hyaluronan (HA) was directly linked to this TGF-β1-dependent response. The aim of this study was to understand the underlying mechanism through which HA regulates TGF-β-dependent responses. Using patient-matched oral and dermal fibroblasts, we show that TGF-β1-dependent proliferation is mediated through the HA receptor CD44, whereas the TGF-β1-mediated antiproliferative response is CD44-independent. Furthermore, overexpression of HAS2 (HA synthase-2) in oral cells modifies their response, and they subsequently demonstrate a proliferative, CD44-dependent response to TGF-β1. We also show that epidermal growth factor (EGF) and its receptor (EGFR) are essential for TGF-β1/HA/CD44-dependent proliferation. Increased HA levels promote EGFR and CD44 coupling, potentiating signal transduction through the MAPK/ERK pathway. Thus, in a HA-rich environment, late ERK1/2 activation results from EGFR/CD44 coupling and leads to a proliferative response to TGF-β1. In comparison, in a non-HA-rich environment, only early ERK1/2 activation occurs, and this is associated with an antiproliferative response to TGF-β1. In summary, HA facilitates TGF-β1-dependent fibroblast proliferation through promoting interaction between CD44 and EGFR, which then promotes specific MAPK/ERK activation, inducing cellular proliferation.     

Expression of transforming growth factor-α mRNA and peptide in rodent kidneys

The expression and function of transforming growth factor alpha (TGF-α) in the kidney are not fully characterised. There exists controversy concerning the detection of renal TGF-α mRNA and the localisation of its immunoreactivity. In attempts to clarify the detection and localisation issue, the present study aimed to detect TGF-α mRNA in neonate and adult rat kidneys, to examine the specificity of two commonly used anti-TGF-α antibodies and finally to localise renal TGF-α immunoreactivity using a specific antibody. TGF-α mRNA of around 4.8 kb was readily detected with a sensitive non-radioactive northern analysis, with a similar abundance in neonatal and adult rat kidneys. Renal TGF-α peptide of the 6-kDa mature form was identified by western blotting. By using various controls, including specimens from TGF-α knock out mice in comparison with wild-type mice, the present study has confirmed the specificity of a polyclonal anti-human recombinant TGF-α antibody. With this antibody, TGF-α immunoreactivity was localised to the proximal tubules in renal cortex. In addition, the present study has also demonstrated a non-specificity in localising TGF-α in rodent kidneys by the most commonly used monoclonal anti-human TGF-α C-terminal peptide antibody, which stained collecting ducts in renal cortex and medulla. Accepted: 8 April 1999     

Transforming growth factor-β signaling: Tumorigenesis and targeting for cancer therapy

Transforming growth factor (TGF)-β is a multitasking cytokine such that its aberrant expression is related to cancer progression and metastasis. TGF-β is produced by a variety of cells within the tumor microenvironment (TME), and it is responsible for regulation of the activity of cells within this milieu. TGF-β is a main inducer of epithelial–mesenchymal transition (EMT), immune evasion, and metastasis during cancer progression. TGF-β exerts most of its functions by acting on TβRI and TβRII receptors in canonical (Smad-dependent) or noncanonical (Smad-independent) pathways. Members of mitogen-activated protein kinase, phosphatidylinositol 3-kinase/protein kinase B, and nuclear factor κβ are involved in the non-Smad TGF-β pathway. TGF-β acts by complex signaling, and deletion in one of the effectors in this pathway may influence the outcome in a diverse way by taking even an antitumor role. The stage and the type of tumor (contextual cues from cancer cells and/or the TME) and the concentration of TGF-β are other important factors determining the fate of cancer (progression or repression). There are a number of ways for targeting TGF-β signaling in cancer, among them the special focus is on TβRII suppression.