Expression cloning of TGF-beta receptors.

Using a powerful expression cloning method in COS cells, we have cloned the TGF-beta types II and III receptors. The type III TGF-beta receptor is a membrane-bound proteoglycan with a core protein of about 110 kDa. Stable expression of the type III receptor in L6 myoblasts leads to an apparent increase in the ability of the type II receptor to bind iodinated TGF-beta 1. The cloned type II receptor has a predicted protein core of about 60 kDa with a cysteine-rich extracellular domain, a single transmembrane domain, and a functional serine/threonine kinase domain that is homologous to the activin receptor and to the C. elegans protein daf-1. These results implicate serine/threonine phosphorylation as an important mechanism of TGF-beta action.     

Expression cloning of the TGF-beta type II receptor, a functional transmembrane serine/threonine kinase.

A cDNA encoding the TGF-beta type II receptor protein has been isolated by an expression cloning strategy. The cloned cDNA, when transfected into COS cells, leads to overexpression of an approximately 80 kd protein that specifically binds radioiodinated TGF-beta 1. Excess TGF-beta 1 competes for binding of radioiodinated TGF-beta 1 in a dose-dependent manner and is more effective than TGF-beta 2. The predicted receptor structure includes a cysteine-rich extracellular domain, a single hydrophobic transmembrane domain, and a predicted cytoplasmic serine/threonine kinase domain. A chimeric protein containing the intracellular domain of the type II receptor and expressed in E. coli can phosphorylate itself on serine and threonine residues in vitro, indicating that the cytoplasmic domain of the type II receptor is a functional kinase. This result implicates serine/threonine phosphorylation as an important mechanism of TGF-beta receptor-mediated signaling.     

Two novel patterns of transforming growth factor beta (TGF-beta) binding to cell surface proteins are dependent upon the binding of TGF-beta 1 and indicate a mechanism of positive cooperativity.

Three isoforms of the transforming growth factor beta (TGF-beta) family, TGF-beta 1, TGF-beta 2, and TGF-beta 3, bind specifically and with high affinity to several cell surface components known as type I, type II, and type III proteins. The type I and II proteins may serve as biological receptors, whereas the type III protein does not appear to be associated with TGF-beta-mediated cell responses, and its function remains unknown. Binding data on confluent monolayers of rat skeletal myoblasts of the L6 cell line reveals two novel patterns of TGF-beta 1 binding. Saturation of the type I receptor with native TGF-beta 2 induces a 7-fold increase in binding of radiolabeled TGF-beta 1 at the type II protein. No induction of type II receptor binding was observed on subconfluent cells indicating a density-dependent phenomenon. The data suggest that the type I and type II proteins may interact during ligand binding in a manner which may be indicative of a regulatory role that is activated by the phase of cell growth or differentiation. A second observation is the binding of TGF-beta to a glycoprotein of 180 kDa and referred to here as the "type VI" binding protein. This protein is not related to previously described TGF-beta binding proteins, and its distribution appears universal among cell types. The level of TGF-beta 1 binding to this protein is dependent on the presence of TGF-beta 2. It is not known whether this protein transmits biological information or whether it serves as an accessory protein of a TGF-beta receptor complex.     

Isolation and characterization of a transforming growth factor-beta Type II receptor cDNA from Xenopus laevis

Transforming Growth Factor-beta (TGF-beta) and their receptors have been characterized from many organisms. Two TGF-beta signaling receptors called Type I and II have been described for various ligands of the superfamily from organisms ranging from Drosophila to humans. In Xenopus laevis, TGF-beta2 and 5 have been reported and presumably, play important roles during early development. Several Type I and type II receptors for many ligands of the TGF-beta superfamily except TGF-beta type II receptor (TbetaIIR), have been characterized in Xenopus laevis. A chemical cross linking experiment using iodinated TGF-beta1 and -beta5, revealed four specific binding proteins on XTC cells. In order to understand the TGF-beta involvement during Xenopus development, a TGF-beta type II receptor (XTbetaIIR) has been isolated from a XTC cDNA library. XTbetaIIR was a partial cDNA lacking a portion of the signal peptide. The sequence analysis and homology comparison with the human TbetaIIR revealed 67% amino acid similarity in the extra cellular domain, 60% similarity in the transmembrane domain and 87% similarity in the cytoplasmic kinase domain, suggesting that XTbetaIIR is a putative TGF-beta type II receptor. In addition, the consensus amino acid motif for serine threonine receptor kinases was also present. Further, a dominant negative expression construct lacking the cytoplasmic kinase domain (engineered with the signal peptide from human TGF-beta type II receptor), was able to abolish TGF-beta mediated induction of a luciferase reporter plasmid, in a transient cell transfection assay. This substantiates the notion that XTbetaIIR cDNA can act as a receptor for TGF-beta. RT-PCR analysis using RNA isolated from various developmental stages of Xenopus laevis revealed expression of this gene in all the early stages of development and in the adult organs, except in stages 46/48.     

Molecular cloning and characterization of the human and porcine transforming growth factor-beta type III receptors.

Full-length cDNAs for the transforming growth factor-beta (TGF-beta) type III receptors were isolated from porcine uterus and human placenta cDNA libraries. The human TGF-beta type III receptor coding region encodes a protein of 849 amino acids with a single transmembrane domain and a short stretch of the intracellular domain. Potential glycosaminoglycan attachment sites were found in the extracellular domain. The overall amino acid sequence identities with those of the porcine and rat TGF-beta type III receptors were 83% and 81%, respectively. A high degree of sequence conservation was observed in the transmembrane and intracellular domains, which also have sequence similarity with human endoglin. In addition, two portions with 29 and 52 amino acids in the extracellular domain were found to be substantially similar with human endoglin.     

Betaglycan inhibits TGF-beta signaling by preventing type I-type II receptor complex formation. Glycosaminoglycan modifications alter betaglycan function

Transforming growth factor (TGF)-beta is a multifunctional growth factor with important roles in development, cell proliferation, and matrix deposition. It signals through the sequential activation of two serine/threonine kinase receptors, the type I and type II receptors. A third cell surface receptor, betaglycan, serves as a co-receptor for TGF-beta in some cell types, enhancing TGF-beta-mediated signaling. We have examined the function of betaglycan in renal epithelial LLC-PK1 cells that lack endogenous betaglycan. We demonstrate that the expression of betaglycan in LLC-PK1 cells results in inhibition of TGF-beta signaling as measured by reporter gene expression, thymidine incorporation, collagen production, and phosphorylation of the downstream signaling effectors Smad2 and Smad3. In comparison, the expression of betaglycan in L6 myoblasts enhances TGF-beta signaling, which is consistent with the published literature. The effects of betaglycan in LLC-PK1 cells are not mediated by ligand sequestration or increased production of a soluble form of the receptor, which has been reported to serve as a ligand antagonist. We demonstrate instead that in LLC-PK1 cells, unlike L6 cells, expression of betaglycan prevents association between the type I and type II TGF-beta receptors, which is required for signaling. This is a function of the glycosaminoglycan modifications of betaglycan. Betaglycan in LLC-PK1 cells exhibits higher molecular weight glycosaminoglycan (GAG) chains than in L6 cells, and a GAG- betaglycan mutant does not inhibit TGF-beta signaling or type I/type II receptor association in LLC-PK1 cells. Our data indicate that betaglycan can function as a potent inhibitor of TGF-beta signaling by a novel mechanism and provide support for an essential but complex role for proteoglycan co-receptors in growth factor signaling.     

Cloning, sequencing and expression of human TSH receptor

Complementary cDNA clones encoding the TSH (thyroid stimulatory hormone) receptor were isolated from a human thyroid lambda gt10 library using Iow stringency hybridization with LH/hCG (luteinizing hormone-human choriogonadotropic hormone) receptor probes. Sequencing of the clones showed a 764 amino acid open reading frame. The first 21 amino acids probably correspond to a signal peptide, the mature protein thus contains 743 amino acids (calculated molecular weight: 84,501 daltons). Its putative structure consists of a 394 amino acid extracellular domain, a 266 amino acid membrane spanning domain with 7 putative transmembrane segments and a 83 amino acid intracellular domain. A high degree of homology is observed with LH/hCG receptor suggesting the definition of a new subfamily of G-protein coupled receptors. Computer search showed the presence in the putative third intracellular loop of a motif resembling that described in the non receptor type protein tyrosine kinases (c-src, c-yes, c-fgr, etc...). RNA blots showed that the receptor messenger RNA consists of two major species of 4300 and 3900 nucleotides. The cDNA was inserted into an expression vector and after transfection into COS 7 cells it was shown to produce a functional TSH receptor.     

Betaglycan induces TGF-beta signaling in a ligand-independent manner, through activation of the p38 pathway

Betaglycan, a cell surface heparan sulphate proteoglycan, is traditionally thought to function by binding transforming growth factor type beta (TGF-beta) via its core protein and then transferring the growth factor to its signaling receptor, the type II receptor. However, there is increasing evidence that the function of betaglycan is more complex. Here, we have evaluated the role of betaglycan through adenoviral expression (Adv-BG) in myoblasts and fibroblasts and found that in Adv-BG-infected cells, the activity of p3TP-Lux and pCTGF-Luc reporter after transient transfection, as well as fibronectin synthesis, all of which are target processes for TGF-beta, were highly increased in the absence of TGF-beta. It is known that this cytokine strongly inhibits myogenin induction in myoblasts. In Adv-BG-infected myoblasts, the activity of pMyo-Luc reporter after transient transfection was strongly inhibited in the absence of TGF-beta. These effects were not precluded by applying TGF-beta-blocking antibodies, the soluble TGF-beta type II receptor, or soluble betaglycan to sequester TGF-beta present in the cell medium. Furthermore, the data suggest that the cytoplasmic domain of betaglycan is required for this TGF-beta-independent response, giving further support to a ligand-independent signaling effect for betaglycan. The process also seemed independent of Smad-2 phosphorylation, although Adv-BG infection induced p38 phosphorylation, and SB239063, an inhibitor of the p38 pathway, inhibited p3TP-Lux-driven activity. These results suggest a novel signaling mechanism for betaglycan, which is independent of the canonical TGF-beta signal pathway although it involves TGF-beta receptors and takes place through p38 pathways.     

Functional roles for the cytoplasmic domain of the type III transforming growth factor beta receptor in regulating transforming growth factor beta signaling

Transforming growth factor beta (TGF-beta) signals through three high affinity cell surface receptors, TGF-beta type I, type II, and type III receptors. The type III receptor, also known as betaglycan, binds to the type II receptor and is thought to act solely by "presenting" the TGF-beta ligand to the type II receptor. The short cytoplasmic domain of the type III receptor is thought to have no role in TGF-beta signaling because deletion of this domain has no effect on association with the type II receptor, or with the presentation role of the type III receptor. Here we demonstrate that the cytoplasmic domains of the type III and type II receptors interact specifically in a manner dependent on the kinase activity of the type II receptor and the ability of the type II receptor to autophosphorylate. This interaction results in the phosphorylation of the cytoplasmic domain of the type III receptor by the type II receptor. The type III receptor with the cytoplasmic domain deleted is able to bind TGF-beta, to bind the type II receptor, and to enhance TGF-beta binding to the type II receptor but is unable to enhance TGF-beta2 signaling, determining that the cytoplasmic domain is essential for some functions of the type III receptor. The type III receptor functions by selectively binding the autophosphorylated type II receptor via its cytoplasmic domain, thus promoting the preferential formation of a complex between the autophosphorylated type II receptor and the type I receptor and then dissociating from this active signaling complex. These studies, for the first time, elucidate important functional roles of the cytoplasmic domain of the type III receptor and demonstrate that these roles are essential for regulating TGF-beta signaling.     

Molecular cloning and expression of the murine interleukin-5 receptor

Murine interleukin-5 (IL-5) is known to play an essential role in Ig production of B cells and proliferation and differentiation of eosinophils. Here, we have isolated cDNA clones encoding a murine IL-5 receptor by expression screening of a library prepared from a murine IL-5 dependent early B cell line. A cDNA library was expressed in COS7 cells and screened by panning with the use of anti-IL-5 receptor monoclonal antibodies. The deduced amino acid sequence analysis demonstrates that the receptor is a glycoprotein of 415 amino acids (Mr 45,284), including an N-terminal hydrophobic region (17 amino acids), a glycosylated extracellular domain (322 amino acids), a single transmembrane segment (22 amino acids) and a cytoplasmic tail (54 amino acids). COS7 cells transfected with the cDNA expressed a 60 kd protein that bound IL-5 with a single class of affinity (KD = 2-10 nM). FDC-P1 cells transfected with the cDNA for murine IL-5 receptor showed the expression of IL-5 binding sites with both low (KD = 6 nM) and high affinity (KD = 30 pM) and acquired responsiveness to IL-5 for proliferation, although parental FDC-P1 cells did not show any detectable IL-5 binding. In addition, several cDNA clones encoding soluble forms of the IL-5 receptor were isolated. Northern blot analysis showed that two species of mRNAs (5.0 kb and 5.8 kb) were detected in cell lines that display binding sites for murine IL-5. Homology search for the amino acid sequence of the IL-5 receptor reveals that the IL-5 receptor contains a common motif of a cytokine receptor family that is recently identified.     

Molecular cloning and binding properties of the human type II activin receptor.

A full-length cDNA for the type II human activin receptor was cloned by hybridization from a human testis cDNA library. The sequence encodes a 513 amino acid protein that is 99% identical, at the amino acid level, with the mouse type II activin receptor. The type II human activin receptor consists of an extracellular domain that specifically binds activin A with a Kd of 360 pM, a single-membrane spanning domain, and an intracellular kinase domain with predicted serine/threonine specificity.     

A kinase subdomain of transforming growth factor-beta (TGF-beta) type I receptor determines the TGF-beta intracellular signaling specificity.

Transforming growth factor-beta (TGF-beta) signals through a heteromeric complex of related type I and type II serine/threonine kinase receptors. In Mv1Lu cells the type I receptor TbetaRI mediates TGF-beta-induced gene expression and growth inhibition, while the closely related type I receptors Tsk7L and TSR1 are inactive in these responses. Using chimeras between TbetaRI and Tsk7L or TSR1, we have defined the structural requirements for TGF-beta signaling by TbetaRI. The extracellular/transmembrane or cytoplasmic domains of TbetaRI and Tsk7L were functionally not equivalent. The juxtamembrane domain, including the GS motif, and most regions in the kinase domain can functionally substitute for each other, but the alphaC-beta4-beta5 region from kinase subdomains III to V conferred a distinct signaling ability. Replacement of this sequence in TbetaRI by the corresponding domain of Tsk7L inactivated TGF-beta signaling, whereas its introduction into Tsk7L conferred TGF-beta signaling. The differential signaling associated with this region was narrowed down to a sequence of eight amino acids, the L45 loop, which is exposed in the three-dimensional kinase structure and diverges highly between TbetaRI and Tsk7L or TSR1. Replacement of the L45 sequence in Tsk7L with that of TbetaRI conferred TGF-beta responsiveness to the Tsk7L cytoplasmic domain in Mv1Lu cells. Thus, the L45 sequence between kinase subdomains IV and V specifies TGF-beta responsiveness of the type I receptor.     

Molecular cloning and expression of mouse GD1alpha/GT1aalpha/GQ1balpha synthase (ST6GalNAc VI) gene

A novel member of the mouse CMP-NeuAc:beta-N-acetylgalactosaminide alpha2,6-sialyltransferase (ST6GalNAc) subfamily, designated ST6GalNAc VI, was identified by BLAST analysis of expressed sequence tags. The sequence of the cDNA clone of ST6GalNAc VI encoded a type II membrane protein with 43 amino acids composing the cytoplasmic domain, 21 amino acids composing the transmembrane region, and 269 amino acids composing the catalytic domain. The predicted amino acid sequence showed homology to the previously cloned ST6GalNAc III, IV, and V, with common amino acid sequences in sialyl motif L and S among these four enzymes. A fusion protein with protein A and extracts from L cells transfected with ST6GalNAc VI in an expression vector showed enzyme activity of alpha2,6-sialyltransferase for GM1b, GT1b, and GD1a but not toward glycoproteins. Thin layer chromatography-immunostaining revealed that the products were GD1alpha, GQ1balpha, and GT1aalpha. Northern blotting revealed that this gene was expressed in a wide range of mouse tissues such as colon, liver, heart, spleen, and brain. It is concluded that this enzyme is a novel sialyltransferase involved in the synthesis of alpha-series gangliosides in the nervous tissues and many other tissues.     

The mannose 6-phosphate/insulin-like growth factor-II receptor is a substrate of type V transforming growth factor-beta receptor.

The type V transforming growth factor beta (TGF-beta) receptor (TbetaR-V) is a ligand-stimulated acidotropic Ser-specific protein kinase that recognizes a motif of SXE/S(P)/D. This motif is present in the cytoplasmic domain of the mannose 6-phosphate/insulin-like growth factor-II (Man-6-P/IGF-II) receptor. We have explored the possibility that the Man-6-P/IGF-II receptor is a substrate of TbetaR-V. Purified bovine Man-6-P/IGF-II receptor was phosphorylated by purified bovine TbetaR-V in the presence of [gamma-32P]ATP and MnCl2 with an apparent Km of 130 nM. TGF-beta stimulated the phosphorylation of the Man-6-P/IGF-II receptor at 0 degrees C in mouse L cells overexpressing the Man-6-P/IGF-II receptor and in wild-type mink lung epithelial (Mv1Lu cells) metabolically labeled with [32P]orthophosphate. The in vitro and in vivo phosphorylation of the Man-6-P/IGF-II receptor occurred at the putative phosphorylation sites as revealed by phosphopeptide mapping and amino acid sequence analysis. TGF-beta stimulated Man-6-P/IGF-II receptor-mediated uptake (approximately 2-fold after 12 h treatment) of exogenous beta-glucuronidase in Mv1Lu cells and type II TGF-beta receptor (TbetaR-II)-defective mutant cells (DR26 cells) but not in type I TGF-beta receptor (TbetaR-I)-defective mutant cells (R-1B cells) and human colorectal carcinoma cells (RII-37 cells) expressing TbetaR-I and TbetaR-II but lacking TbetaR-V. These results suggest the Man-6-P/IGF-II receptor serves as an in vitro and in vivo substrate of TbetaR-V and that both TbetaR-V and TbetaR-I may play a role in mediating the TGF-beta-stimulated uptake of exogenous beta-glucuronidase.     

The inducible blood--brain barrier specific molecule HT7 is a novel immunoglobulin-like cell surface glycoprotein.

The unique properties of brain endothelial cells, which form the blood-brain barrier, are reflected by the expression of specific cell surface molecules. We report here the purification, cloning and expression of one such molecule which is recognized by HT7 monoclonal antibodies. The HT7 antigen is a highly glycosylated 45-52 kd protein localized in brain endothelial cells, kidney epithelial cells and erythroblasts. The protein was purified to homogeneity from plasma membrane proteins isolated from all three sources using immunoaffinity chromatography and reverse phase HPLC. The amino-terminal amino acid sequences of the proteins were found to be identical. Based on amino acid sequence information, specific primers were designed and the polymerase chain reaction was used to obtain a full length cDNA clone. The nucleotide sequence encoded a novel glycoprotein with two C2-like immunoglobulin related domains, one transmembrane domain and a cytoplasmic tail. Expression of the transfected cDNA in COS cells resulted in the appearance of the HT7 antigen on the surface of these cells. On the basis of our results we propose that the protein may be a receptor involved in cell surface recognition at the blood-brain barrier.     

Identification of two amino acid residues in the epsilon subunit that promote mammalian muscle acetylcholine receptor assembly in COS cells

We have used a species difference in epsilon subunits of the acetylcholine receptor (AChR) to investigate regions of the subunit protein that are important in receptor assembly. Upon transient transfection of COS cells, mouse epsilon subunit cDNA is approximately 10 times more effective than that of the rat in supporting expression of surface AChRs when the other subunits are from either mouse or rat. In cells transfected with only alpha and epsilon subunit cDNAs, the formation of an alpha epsilon heterodimer, a presumed assembly intermediate, is also less efficient with rat than with mouse epsilon subunit. By site-directed mutagenesis, we have found that these differences can be accounted for by 2 amino acid differences in the N-terminal domain at positions 106 and 115 of the rat and mouse epsilon subunits, suggesting that the region near these 2 amino acid residues is important for AChR assembly.     

Expression cloning of a receptor for human granulocyte-macrophage colony-stimulating factor.

Two cDNA clones encoding a receptor for human granulocyte-macrophage colony-stimulating factor (hGM-CSF-R) were isolated by expression screening of a library made from human placental mRNA. Pools of recombinant plasmid DNA were electroporated into COS cells which were then screened for their capacity to bind radioiodinated hGM-CSF using a sensitive microscopic autoradiographic approach. The cloned GM-CSF-R precursor is a 400 amino acid polypeptide (Mr 45,000) with a single transmembrane domain, a glycosylated extracellular domain and a short (54 amino acids) intracytoplasmic tail. It does not contain a tyrosine kinase domain nor show homology with members of the immunoglobulin super gene family, but does show some significant sequence homologies with receptors for several other haemopoietic growth factors, including those for interleukin-6, erythropoietin and interleukin-2 (beta-chain) and also to the prolactin receptor. When transfected into COS cells the cloned cDNA directed the expression of a GM-CSF-R showing a single class of affinity (KD = 2(-8) nM) and specificity for human GM-CSF but not interleukin-3. Messenger RNA coding for this receptor was detected in a variety of haemopoietic cells known to display hGM-CSF binding, and cross-linking experiments revealed a similar size for the glycosylated receptors in transfected COS and haemopoietic cells.