TGF-beta type I receptor Alk5 regulates tooth initiation and mandible patterning in a type II receptor-independent manner

TGF-beta superfamily members signal through a heteromeric receptor complex to regulate craniofacial development. TGF-beta type II receptor appears to bind only TGF-beta, whereas TGF-beta type I receptor (ALK5) also binds to ligands in addition to TGF-beta. Our previous work has shown that conditional inactivation of Tgfbr2 in the neural crest cells of mice leads to severe craniofacial bone defects. In this study, we examine and compare the defects of TGF-beta type II receptor (Wnt1-Cre;Tgfbr2(fl/fl)) and TGF-beta type I receptor/Alk5 (Wnt1-Cre;Alk5(fl)(/fl)) conditional knockout mice. Loss of Alk5 in the neural crest tissue resulted in phenotypes not seen in the Tgfbr2 mutant, including delayed tooth initiation and development, defects in early mandible patterning and altered expression of key patterning genes including Msx1, Bmp4, Bmp2, Pax9, Alx4, Lhx6/7 and Gsc. Alk5 controls the survival of CNC cells by regulating expression of Gsc and other genes in the proximal aboral region of the developing mandible. We conclude that ALK5 regulates tooth initiation and early mandible patterning through a pathway independent of Tgfbr2. There is an intrinsic requirement for Alk5 signal in regulating the fate of CNC cells during tooth and mandible development.     

TGF-β and cancer

The relationships between transforming growth factor-β (TGF-β) and cancer are varied and complex. The paradigm that is emerging from the experimental evidence accumulated over the past decade or so is that TGF-β can play two different and opposite roles with respect to the process of malignant progression. During early stages of carcinogenesis, TGF-β acts predominantly as a potent tumor suppressor and may mediate the actions of chemopreventive agents such as retinoids and nonsteroidal anti-estrogens. However, at some point during the development and progression of malignant neoplasms, bioactive TGF-βs make their appearance in the tumor microenvironment and the tumor cells escape from TGF-β-dependent growth arrest. In many cases, this resistance to TGF-β is the consequence of loss or mutational inactivation of the genes that encode signaling intermediates. These include the types I and II TGF-β receptors, as well as receptor-associated and common-mediator Smads. The stage of tumor development or progression at which TGF-β-resistant clones come to dominate the tumor cell population in different types of neoplasm remains to be defined. The phenotypic switch from TGF-β-sensitivity to TGF-β-resistance that occurs during carcinogenesis has several important implications for cancer prevention and treatment.     

TGF-β: 20 years and counting

The history of transforming growth factor-beta (TGF-β) as a bifunctional agent in the immune system is briefly described. The importance of cellular context in understanding the role of TGF-β in regulating immune response is emphasized.     

TGF-β in infections and infectious diseases

Since it was first described as having the ability to inhibit macrophage activation, transforming growth factor-beta (TGF-β) has been analyzed for its role in regulating immune responses to a variety of pathogens, including viruses, bacteria, yeast, and protozoa. Most of the studies have involved organisms that infect macrophages, and this discussion will attempt to highlight these findings. Perhaps the most work has been performed with protozoan pathogens, including Trypanosoma cruzi and a variety of Leishmania species, so the discussion will begin with these organisms. Other studies have focused on mycobacteria and viruses, including human immunodeficiency virus, so these areas will also be emphasized in the discussion. For the most part, investigators have reported that TGF-β has, as expected, a negative influence on host responses and a beneficial effect on the survival and growth of intracellular pathogens. However, other studies have found that TGF-β may have a positive or beneficial effect in some models of infection. This review will attempt to highlight studies and conclusions on the roles of TGF-β in infection.     

TGF-β: from latent to active

The transforming growth factor-betas (TGF-βs) are synthesized as precursor proteins that are modified intracellularly prior to secretion. One of the most relevant intracellular modifications is the cleavage of the C-terminal pro-region from the N-terminal portion of the protein. The C-terminal pro-region is referred to as the latency-associated peptide (LAP) while the N-terminal region is called the mature TGF-β or active TGF-β. However, with some exceptions the LAP noncovalently associates with the mature TGF-β prior to secretion. When the mature TGF-β is associated with the LAP it is called L-TGF-β and cannot interact with its receptor and has no biological effect. The TGF-βs and their receptors are very ubiquitously expressed, suggesting that the regulation of TGF-β activity is likely to be complex and multifactorial. However, one of the most important means of controlling the biological effects of TGF-β is the regulation of converting L-TGF-β to active TGF-β. The current literature supports two major mechanisms of activation of L-TGF-β and suggests that the mechanism of activation of L-TGF-β may be varied and context-dependent. For TGF-β to become biologically active the LAP has to be either released from its associations with L-TGF-β or undergo conformational change such that the LAP is not released from the L-TGF-β complex but exposes the TGF-β receptor binding site. Since TGF-β has been associated with the pathogenesis of numerous diseases, the various mechanisms of activation of L-TGF-β in context offer the possibility of controlling TGF-β activity localized to the organ of involvement and to a more specific disease process.     

Modulation of gene expression in the preimplantation mouse embryo by TGF-α and TGF-β

The effect of growth factors on regulating gene expression in the preimplantation mouse embryo was examined, since results of previous experiments revealed a stimulatory effect of exogenously-added growth factors on preimplantation development in vitro. Treatment of early cavitating blastocysts with either 250 pM TGF-α or TGF-β results in changes in the pattern of total protein synthesis as assessed by high-resolution two-dimensional gel electrophoresis. In some cases, the synthesis of a particular polypeptide is either up- or downregulated by each growth factor, whereas in other instances the synthesis of a polypeptide is modulated by one but not the other growth factor. Use of the mRNA differential display method permitted the identification of genes whose expression is either up- or downregulated by these growth factors. Treatment of mouse blastocysts with either TGF-α or TGF-β results in the increased expression of the b subunit of the F₀ ATPase. TGF-β also stimulates the expression of the DNA polymerase α. TGF-α treatment results in the increase in expression of a gene homologous to the human HEPG2 cDNA, as well as in a decrease in expression of fibronectin. © 1995 Wiley-Liss, Inc.     

TGF-β and fibrosis

Transforming growth factor-beta (TGF-β) isoforms are multifunctional cytokines that play a central role in wound healing and in tissue repair. TGF-β is found in all tissues, but is particularly abundant in bone, lung, kidney and placental tissue. TGF-β is produced by many but not all parenchymal cell types, and is also produced or released by infiltrating cells such as lymphocytes, monocytes/macrophages, and platelets. Following wounding or inflammation, all these cells are potential sources of TGF-β. In general, the release and activation of TGF-β stimulates the production of various extracellular matrix proteins and inhibits the degradation of these matrix proteins, although exceptions to these principles abound. These actions of TGF-β contribute to tissue repair, which under ideal circumstances leads to the restoration of normal tissue architecture and may involve a component of tissue fibrosis. In many diseases, excessive TGF-β contributes to a pathologic excess of tissue fibrosis that compromises normal organ function, a topic that has been the subject of numerous reviews [1, 2 and 3]. In the following chapter, we will discuss the role of TGF-β in tissue fibrosis, with particular emphasis on renal fibrosis.     

TGF-β1: immunosuppressant and viability factor for T lymphocytes

Transforming growth factor-beta (TGF-β) is a multifunctional cytokine with multiple roles in the immune system. To date, it has been difficult to develop a comprehensive picture of the effect of TGF-β on T lymphocytes, because TGF-β not only acts directly on T lymphocytes, but also acts indirectly by regulating the function of antigen-presenting cells. In early studies, it was mostly the inhibitory function of TGF-β that was demonstrated; recently, however TGF-β was recognized as an antiapoptotic survival factor for T lymphocytes. The outcome of the TGF-β effect on T lymphocytes was shown to strongly depend on their stage of differentiation and on the cytokine milieu. TGF-β cannot be classified as a classical Th1 or Th2 cytokine. However, recently the existence of the TGF-β-producing Th3 subset was described which might play an important regulatory role during an immune response. A better understanding of the molecular mechanism of how TGF-β inhibits or stimulates T lymphocytes will help to predict the complex functions of this cytokine.     

TGF-β1 regulation of dendritic cells

Dendritic cells (DCs) represent antigen-presenting cell (APC) populations in lymphoid and nonlymphoid organs which are considered to play key roles in the initiation of antigen-specific T-cell proliferation. According to current knowledge, the net outcome of T-cell immune responses seems to be significantly influenced by the activation stage of antigen-presenting DCs. Several studies have shown that transforming growth factor-beta 1 (TGF-β1) inhibits in vitro activation and maturation of DCs. TGF-β1 inhibits upregulation of critical T-cell costimulatory molecules on the surface of DCs and reduces the antigen-presenting capacity of DCs. Thus, in addition to direct inhibitory effects of TGF-β1 on effector T lymphocytes, inhibitory effects of TGF-β1 at the level of APCs may critically contribute to previously characterized immunosuppressive effects of TGF-β1. In contrast to these negative regulatory effects of TGF-β1 on function and maturation of lymphoid tissue type DCs, certain subpopulations of immature DCs in nonlymphoid tissues are positively regulated by TGF-β1 signaling. In particular, epithelial-associated DC populations seem to critically require TGF-β1 stimulation for development and function. Recent studies established that TGF-β1 stimulation is absolutely required for the development of epithelial Langerhans cells (LCs) in vitro and in vivo. Furthermore, TGF-β1 seems to enhance antigen processing and costimulatory functions of epithelial LCs.     

Bidirectional regulation of macrophage function by TGF-β

The dual role of transforming growth factor-beta (TGF-β) in modulating macrophage function is an important concept gaining increasing recognition. In addition to its role as a ‘macrophage-deactivating' agent, TGF-β functions as a monocyte activator, inducing cytoke production and mediating host defence. These functions are context-dependent, modulated by the differentiation state of the cell, the local cytokine environment, and the local levels of TGF-β in itself. In general, during the initial stages of inflammation, TGF-β locally acts as a proinflammatory agent by recruiting and activating resting monocytes. As these cells differentiate specific immunosuppressive actions of TGF-β predominate, leading to resolution of the inflammatory response. Increasing our understanding of the bidirectional regulation of macrophage function will facilitate prediction of the ultimate outcome of modulating TGF-β levels in vivo.     

TGF-β1 is an organizer of responses to neurodgeneration

TGF-β1 mRNA and protein were recently found to increase in animal brains after experimental lesions that cause local deafferentation or neuron death. Elevations of TGF-β1 mRNA after lesions are prominent in microglia but are also observed in neurons and astrocytes. Moreover, TGF-β1 mRNA autoinduces its own mRNA in the brain. These responses provide models for studying the increases of TGF-β1 protein observed in βA/amyloid-containing extracellular plaques of Alzheimer's disease (AD) and Down's syndrome (DS) and in brain cells of AIDS victims. Involvement of TGF-β1 in these human brain disorders is discussed in relation to the potent effects of TGF-β1 on wound healing and inflammatory responses in peripheral tissues. We hypothesize that TGF-β1 and possibly other TGF-β peptides have organizing roles in responses to neurodegeneration and brain injury that are similar to those observed in non-neural tissues. Work from many laboratories has shown that activities of TGF-β peptides on brain cells include chemotaxis, modification of extracellular matrix, and regulation of cytoskeletal gene expression and of neurotrophins. Similar activities of the TGF-β's are well established in other tissues.     

Role of NK cells and TGF-β in the regulation of T-cell-dependent antibody production in health and autoimmune disease

Natural killer (NK) cells are a third lymphocyte population especially important in innate immunity. NK cells may also have an important role in the regulation of acquired immunity. These lymphocytes spontaneously produce large amounts of both active and latent transforming growth factor-beta (TGF-β). NK-cell-derived TGF-β1 enabled activated CD8⁺ T cells to inhibit antibody production by blocking the induction of this response. Production of lymphocyte-derived TGF-β is decreased in systemic lupus erythematosus. Insufficient levels of this cytokine in SLE and other autoimmune diseases may contribute to defective T regulatory cell function characteristic of this and other autoimmune diseases. NK cells are found in mucosal tissues and the TGF-β spontaneously released by these cells could contribute to the usual tolerogenic response of T cells to antigens presented at these sites. Thus, in addition to its well known immunosuppressive effects, TGF-β could have an equally important role in the generation of regulatory T cells.     

Regulation of GM-CSF-Induced Dendritic Cell Development by TGF-β1 and Co-Developing Macrophages

Using a culture system of bone marrow progenitor cells with GM-CSF and TGF-β1, a study was performed to analyze the effect of TGF-β1 on the development of dendritic cells (DC) and to elucidate the regulatory role of macrophages co-developing with dendritic cells. The results demonstrate that DC generated in the presence of TGF-β1 were immature with respect to the expression of CD86, nonspecific esterase activity and cell shape. Such inhibitory effects of TGF-β1 were dependent on FcR⁺ macrophages, which were depleted by panning. TGF-β1 did not appear to inhibit the commitment of progenitor cells to the DC lineage. In addition, TGF-β1 also acted directly on the intermediate stage of DC to prevent their over-maturation, which results in a preferential decrease in MHC class II, but not in CD86, in the presence of TNF-α. FcR⁺ suppressive macrophages were also shown to facilitate DC maturation when stimulated via FcR-mediated signals even in the presence of TGF-β1. These results indicate that TGF-β1 indirectly and directly regulate the development of DC and that co-developing macrophages have a regulatory role in DC maturation.     

Craniofacial defects in mice lacking BMP type I receptor Alk2 in neural crest cells

Neural crest cells (NCCs) are pluripotent migratory cells that contribute to the development of various craniofacial structures. Many signaling molecules have been implicated in the formation, migration and differentiation of NCCs including bone morphogenetic proteins (BMPs). BMPs signal through a receptor complex composed of type I and type II receptors. Type I receptors (Alk2, Alk3 and Alk6) are the primary determinants of signaling specificity and therefore understanding their function is important in revealing the developmental roles of molecular pathways regulated by BMPs. Here we used a Cre/loxP system for neural crest specific deletion of Alk2. Our results show that mice lacking Alk2 in the neural crest display multiple craniofacial defects including cleft palate and a hypotrophic mandible. Based on the present results we conclude that signaling via Alk2 receptors is non-redundant and regulates normal development of a restricted set of structures derived from the cranial neural crest.     

Epithelial and ectomesenchymal role of the type I TGF-beta receptor ALK5 during facial morphogenesis and palatal fusion

Transforming growth factor beta (TGF-beta) proteins play important roles in morphogenesis of many craniofacial tissues; however, detailed biological mechanisms of TGF-beta action, particularly in vivo, are still poorly understood. Here, we deleted the TGF-beta type I receptor gene Alk5 specifically in the embryonic ectodermal and neural crest cell lineages. Failure in signaling via this receptor, either in the epithelium or in the mesenchyme, caused severe craniofacial defects including cleft palate. Moreover, the facial phenotypes of neural crest-specific Alk5 mutants included devastating facial cleft and appeared significantly more severe than the defects seen in corresponding mutants lacking the TGF-beta type II receptor (TGFbetaRII), a prototypical binding partner of ALK5. Our data indicate that ALK5 plays unique, non-redundant cell-autonomous roles during facial development. Remarkable divergence between Tgfbr2 and Alk5 phenotypes, together with our biochemical in vitro data, imply that (1) ALK5 mediates signaling of a diverse set of ligands not limited to the three isoforms of TGF-beta, and (2) ALK5 acts also in conjunction with type II receptors other than TGFbetaRII.     

TGF-β3-Induced Chondroitin Sulphate Proteoglycan Mediates Palatal Shelf Adhesion

In mammals, the adhesion and fusion of the palatal shelves are essential mechanisms in the development of the secondary palate. Failure of any of these processes leads to the formation of cleft palate. The mechanisms underlying palatal shelf adhesion are poorly understood, although the presence of filopodia on the apical surfaces of the superficial medial edge epithelial (MEE) cells seems to play an important role in the adhesion of the opposing MEE. We demonstrate here the appearance of chondroitin sulphate proteoglycan (CSPG) on the apical surface of MEE cells only immediately prior to contact between the palatal shelves. This apical CSPG has a functional role in palatal shelf adhesion, as either the alteration of CSPG synthesis by β-d-Xyloside or its specific digestion by chondroitinase AC strikingly alters the in vitro adhesion of palatal shelves. We also demonstrate the absence of this apical CSPG in the clefted palates of transforming growth factor beta 3 (TGF-β₃) null mutant mice, and its induction, together with palatal shelf adhesion, when TGF-β₃ is added to TGF-β₃ null mutant palatal shelves in culture. When chick palatal shelves (that do not adherein vivo nor express TGF-β₃, nor CSPG in the MEE) are cultured in vitro, they do not express CSPG and partially adhere, but when TGF-β₃ is added to the media, they express CSPG and their adhesion increases strikingly. We therefore conclude that the expression of CSPG on the apical surface of MEE cells is a key factor in palatal shelf adhesion and that this expression is regulated by TGF-β₃.