Assignment of Transforming Growth Factor beta 1 and beta 3 and a Third New Ligand to the Type I Receptor ALK-1*

Andreas LuxDagger §, Liliana Attisanoparallel , and Douglas A. MarchukDagger **

From the Dagger  Department of Genetics, Duke University Medical Center, Durham, North Carolina 27710 and the  Department of Anatomy and Cell Biology, University of Toronto, Toronto, Ontario M5S 1A8, Canada

    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Germ line mutations in one of two distinct genes, endoglin or ALK-1, cause hereditary hemorrhagic telangiectasia (HHT), an autosomal dominant disorder of localized angiodysplasia. Both genes encode endothelial cell receptors for the transforming growth factor beta  (TGF-beta ) ligand superfamily. Endoglin has homology to the type III receptor, betaglycan, although its exact role in TGF-beta signaling is unclear. Activin receptor-like kinase 1 (ALK-1) has homology to the type I receptor family, but its ligand and corresponding type II receptor are unknown. In order to identify the ligand and type II receptor for ALK-1 and to investigate the role of endoglin in ALK-1 signaling, we devised a chimeric receptor signaling assay by exchanging the kinase domain of ALK-1 with either the TGF-beta type I receptor or the activin type IB receptor, both of which can activate an inducible PAI-1 promoter. We show that TGF-beta 1 and TGF-beta 3, as well as a third unknown ligand present in serum, can activate chimeric ALK-1. HHT-associated missense mutations in the ALK-1 extracellular domain abrogate signaling. The ALK-1/ligand interaction is mediated by the type II TGF-beta receptor for TGF-beta and most likely through the activin type II or type IIB receptors for the serum ligand. Endoglin is a bifunctional receptor partner since it can bind to ALK-1 as well as to type I TGF-beta receptor. These data suggest that HHT pathogenesis involves disruption of a complex network of positive and negative angiogenic factors, involving TGF-beta , a new unknown ligand, and their corresponding receptors.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Hereditary hemorrhagic telangiectasia (HHT),1 or Osler-Rendu-Weber disease, is an autosomal dominant disorder characterized by localized angiodysplasia (1). Mutations have been identified in two genes, endoglin and ALK-1 that can cause HHT (2, 3). The scope and variety of mutations identified in the endoglin gene (2, 4-8) and the ALK-1 gene (3, 9, 10), as well as RNA and protein expression analyses, suggest that the majority of these represent null alleles and that the disease phenotype is the result of inherited haploinsufficiency for either endoglin or ALK-1.

By sequence homologies, endoglin and ALK-1 are thought to be endothelial cell receptors for members of the TGF-beta superfamily. The TGF-beta superfamily (TGF-beta s, activins, bone morphogenetic proteins (BMPs), and Müllerian-inhibiting substance) constitutes a family of multifunctional cytokines that regulate many aspects of cellular function such as proliferation, differentiation, adhesion, migration, and extracellular matrix formation (11-14). Signaling occurs via different ligand-induced heteromeric receptor complexes consisting of type I and type II transmembrane serine/threonine kinase receptors.

Models for TGF-beta and activin signaling have been proposed by several authors (15-17). TGF-beta or activin initially binds the constitutively phosphorylated type II receptor, thereby recruiting the type I receptor into the ligand-type II receptor complex. The type I receptor is subsequently phosphorylated by the type II receptor on serine and threonine residues in its cytoplasmic juxtamembrane GS domain (15, 18). The type I receptor then phosphorylates downstream signaling mediators such as members of the recently identified Smad family (reviewed in Refs. 19-21).

Currently, seven mammalian type I receptors have been cloned. For the majority of these, ligands and corresponding type II receptors have been identified. ALK-4 is an activin type I receptor, ActR-IB (22-24). ALK-3 and ALK-6 are the BMP type I receptors BMPR-IA and BMPR-IB, respectively (24, 25). ALK-2 is an activin and BMP type I receptor (13, 26). ALK-5 is the TGF-beta type I receptor, Tbeta R-I (27). ALK-7 is predominantly expressed in the central nervous system and can complex with type II receptors for both TGF-beta and activin (28, 29). However, in functional assays neither ligand was able to elicit a signal.

The ligand and corresponding type II receptor(s) for ALK-1 are also unknown. In the presence of the TGF-beta type II receptor (Tbeta R-II), ALK-1 binds TGF-beta 1, whereas in the presence of the activin type II receptor (ActR-II), ALK-1 binds activin A (22, 30, 31). However, neither of these complexes elicits a signal, as determined by a number of outcomes including proliferation response, an alteration in fibronectin expression, or the ability to activate a PAI-1 promoter-based reporter gene in the mink cell line Mv1Lu. Nonetheless, this does not exclude TGF-beta and activin as ALK-1 ligands, as ALK-1 signaling initiated by these cytokines might activate other cellular responses. Unfortunately, the lack of a signaling assay prohibits further analysis of ALK-1 signal transduction and its role in the pathogenesis of HHT.

Signaling assays have been devised for other receptors in this superfamily. In Mv1Lu cells, Tbeta R-I and ActR-IB are able to mediate TGF-beta or activin-induced activation of the p3TP-Lux reporter construct, which contains the ligand-inducible portion of the PAI-1 promoter (22, 32). By using chimeric receptors, several investigators have shown that signal specificity is determined by the intracellular domain of a chimeric type I receptor, together with the appropriate type II receptor, independent of the ligand binding specificity of the extracellular domain (33-37). We hypothesized that the same would hold true for the domains of ALK-1 if provided with the correct ligand/type II receptor combination. Therefore, we constructed chimeric receptors with the ALK-1 extracellular domain and the cytoplasmic domain of Tbeta R-I or ActR-IB to create an ALK-1 signaling assay.

Endoglin is thought to be a TGF-beta type III receptor based on its sequence homology to the proteoglycan betaglycan (38-40). Betaglycan presents the ligands to Tbeta R-II and Tbeta R-I increasing the signaling activity of the type I receptor (41). Because of its sequence homology to betaglycan, a similar function is proposed for endoglin. We will present here data that endoglin is the binding partner for ALK-1 suggesting a role for endoglin in modulating signaling via ALK-1.

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Cell Lines-- All cell media and fetal bovine serum (FBS) were obtained by Life Technologies, Inc. COS-1 cells, a gift by Dr. B. Cullen (Duke University, Durham, NC), were cultured in modified Dulbecco's medium + 5% FBS. R-1B and DR-26 cells were derived in earlier studies by chemical mutagenesis of Mv1Lu cells (42, 43). Cells were maintained in minimal essential medium (MEM) containing nonessential amino acids (NEAA) and 10% FBS. All cell lines were cultured at 37 °C in a 5% CO2 environment.

Antibodies and Cytokines-- Rabbit antiserum against endoglin and ALK-1 was prepared against part of the endoglin extracellular domain, encoded by exons 2-5, and the entire ALK-1 extracellular domain except for the leading sequence. Briefly, the corresponding cDNAs were cloned into the bacterial expression vector pET-15b (Novagen) behind a 6× His tag and expressed in bacteria. Bacteria were lysed, and recombinant proteins were purified over a nickel-nitrilotriacetic acid column (Qiagen). The column-purified recombinant proteins were then separated over a SDS-PAGE, cut out, and electroeluted. The eluted antigen was mixed with Freund's adjuvant and used to immunize rabbits. The anti-endoglin and anti-ALK-1 rabbit serum were tested in Western blots detecting endoglin and ALK-1 only in those cells (COS cells) that were transfected with an endoglin or ALK-1 expression construct. Western blot immunostaining with the rabbit preimmune serum showed no specificity.

Proteins tagged with the HA epitope of the influenza virus hemagglutinin were detected in immunoblots with a monoclonal antibody. The antibody (12CA5) was obtained from the supernatant of a mouse hybridoma cell line expressing and secreting the monoclonal antibody. Polyclonal anti-TGF-beta 1 antibody was obtained from Promega (catalog number G1221), Madison, WI. The monoclonal endoglin antibody P3D1 was obtained from Karen Jensen (University of Iowa).

TGF-beta 1 was obtained from R & D Systems, Minneapolis. TGF-beta 2 and -beta 3 were purchased from Calbiochem, and TGF-beta 2 was also from R & D Systems. BMP-2, BMP-7, and Inhibin A were obtained from the National Hormone and Pituitary Program. For activin A, COS cells were transiently transfected with a pCMV5-activin A expression construct. Transfection was done using the LipofectAMINE method (Life Technologies, Inc.) according to the manufacturer's instruction. After transfection, cells were kept for an additional day in Iscove's modified Dulbecco's medium + 5% FBS. Medium was then exchanged, and cells were incubated an additional 3 days in Iscove's modified Dulbecco's medium + 0.5% FBS. The supernatant was collected and stored at 4 °C and was used in the activin A luciferase reporter assays. The supernatant (IMD medium) of COS cells incubated for 3 days in Iscove's modified Dulbecco's medium + 0.5% FBS was collected and used as a negative control in the activin A luciferase reporter assays. Human serum was purchased from the Nation Blood Institute Blood Center (Cincinnati, OH) and Gemini Biological Products (Calabasas, CA).

Chimeric and Wild-type Receptors-- All cDNAs of the different receptors and chimeric receptors were cloned into the mammalian expression vector pCMV5. All constructs, except for endoglin, have a C-terminal HA epitope tag. Two ALK-1 constructs were used, one with an HA tag and one without, which will be indicated in the text. The ALK-1, Tbeta R-I, ActR-IB, ALK-3 (BMPR-IA), Tbeta R-II, and ActR-II constructs were described previously (22, 44). The endoglin cDNA was obtained from the American Type Culture Collection (ATCC). Endoglin was cloned into the EcoRI/BamHI sites of pCMV5 (pCMV5-Endowt). The endoglin coding sequence has after the first seven amino acids after the transmembrane domain a convenient MluI site, and 3' prime from this there is a second site in the pCMV5 multiple cloning site. To create the endoglin-truncated version EndoglinDelta cyto pCMV5-Endowt was digested with MluI which cuts out the endoglin cytoplasmic domain and then subsequently religated, resulting in pCMV5-EndoDelta cyto.

To construct the chimeric type I receptors that were swapped in the GS domain, we had to introduce a new unique restriction site, AccIII, in each receptor cDNA sequence, which does not alter the amino acid sequence in the GS domain. The receptor cDNAs ALK-1, Tbeta R-I, ActR-IB, and ALK-3 were first cloned in pUC18 or pUC19, respectively. The new restriction site was introduced with the TransformerTM Site-directed Mutagenesis Kit (CLONTECH), using sequence-specific oligonucleotides (numbers 1-4) for the GS domains of the different receptors, containing the AccIII recognition sequence in the middle of the primer. The new AccIII sites were verified by sequencing. The constructs were then digested with the restriction enzyme AccIII and an appropriate second enzyme that allowed us to cut out the C-domain of the different type I receptors. The resulting DNA fragments were gel-purified (QIAEX Gel Extraction Kit, Qiagen) and used for ligations to create the different chimeric receptors. These chimeras are assigned a name with the addition -GS, i.e. ALK-1/Tbeta R-I(GS). The correct reading frame around the AccIII site was verified by DNA sequencing. The chimeric cDNAs were then cloned back into the pCMV5 vector.

A second set of chimeric receptors was constructed, containing the extracellular domain of ALK-1 or ALK-3 and the transmembrane domain and cytoplasmic domain of Tbeta R-I, ALK-1/Tbeta R-I(TM) (ALK-1(TM)), and ALK-3/Tbeta R-I(TM) (ALK-3(TM)). The chimeric receptors were constructed using PCR with a 1/5 mixture of Vent polymerase (New England Biolabs)/Taq polymerase (Life Technologies, Inc.). Specifically, the Tbeta R-I cDNA in pUC18 was used as template in the PCRs. To create ALK-1(TM) the entire Tbeta R-I transmembrane/cytoplasmic domain encoding sequence was amplified using, as the 5'-primer, an oligonucleotide (oligonucleotide 5) containing the last 11 nucleotides of the ALK-1 extracellular domain, with the ALK-1 unique MscI site, followed by the first 23 nucleotides of the Tbeta R-I transmembrane domain. As the 3'-primer the M13 reverse primer was used, amplifying part of the pUC18 multiple cloning site, which allows cutting the PCR products at their 3'-end with BamHI for subsequent cloning. To create ALK-3(TM) the same approach was employed. For the 5'-primer an oligonucleotide (number 6) was used, containing the last 12 nucleotides of the ALK-3 extracellular domain, with the ALK-3 unique BsmI site, followed by the first 21 nucleotides of the Tbeta R-I transmembrane domain. For the 3'-end the M13 reverse primer was used. The resulting PCR products were purified with the QIAquick PCR Purification Kit (Qiagen), digested with MscI/BamHI or BsmI/BamHI, gel-purified, and then ligated to the extracellular domain of ALK-1 or ALK-3. The correct sequence and reading frame were verified by DNA sequencing. All chimeras were transiently transfected in COS cells, and their expression was verified by Western blot analysis using the HA antibody since all constructs have a C-terminal HA tag.

Extracellular HHT patient mutations were introduced in the ALK-1/Tbeta R-I(TM) chimeric receptor by site-directed mutagenesis using the QuickChangeTM mutagenesis Kit (Stratagene). The following constructs were made with the following oligonucleotide pair combinations: ALK-1(TM)insG140 (number 7/8), ALK-1(TM)W50C (number 9/10), ALK-1(TM)C51Y (number 11/12), ALK-1(TM)R67Q (number 13/14).

Immunoprecipitation and Western Blot-- COS cells were cultured in 6-well plates to 70-80% confluence. The LipofectAMINE method was used for transfections according to the manufacturer's instruction (Life Technologies, Inc.). Briefly, cells were transfected with the following: (a) 2 µg of pCMV5; (b) 1 µg of receptor cDNA and 1 µg of pCMV5; or (c) in co-transfections of two different receptor cDNAs 1 µg of each. After 2 days post-transfection, cells were lysed in 500 µl of lysis buffer (50 mM Tris-HCl (pH 7.5), 150 mM NaCl, 0.5% Nonidet P-40, 50 mM NaF, 1 mM Na3VO4, 1 mM dithiothreitol, 1 mM phenylmethylsulfonyl fluoride, 2.5 µg/ml leupeptin, 2.5 µg/ml aprotinin, 1 mM benzamidine, 10 µg/ml trypsin inhibitor) at 4 °C for 30 min. The lysate was then clarified by centrifugation in a microcentrifuge, and 20 µl were stored away for later analysis. The remaining cell lysate was precleared with 50 µl of protein A-Sepharose (Amersham Pharmacia Biotech (resolved in lysis buffer (w/v)) for 3 h. The precleared lysate was incubated at 4 °C with 10 µl of polyclonal antibody (endoglin or ALK-1 rabbit anti-serum) or 20 µl of monoclonal antibody (cell culture supernatant). After at least 3 h 20 µl of protein A-Sepharose was added for additional 3 h. The protein A-Sepharose immunocomplex was then washed three times in 500 µl of lysis buffer and resolved in 15 µl of Laemmli buffer. The precipitated proteins were separated by SDS-PAGE and blotted to a nitrocellulose membrane (BioBlot-NC, Costar) for immunodetection with the indicated antibody. Immunodetection was performed with the ECLTM Western blotting analysis system (Amersham Pharmacia Biotech) according to the manufacturer's instruction.

Luciferase Reporter Assay-- For luciferase expression assays, the R-1B and DR-26 cells were transiently transfected with p3TP-Lux (32), the indicated receptor cDNA in pCMV5, pCMV5 alone, or both. The pSV-beta -galactosidase vector (pSV-beta ) (Promega) was always included to normalize the luciferase activity for the different transfections. Cells were plated on 60-mm dishes and grown to 80% confluence. Prior to transfection, cells were washed once with serum-free medium. Cells were transfected in 3 ml of serum-free medium containing 6 µg of total DNA in the following combinations: (a) 2 µg of p3TP-Lux, 3 µg of pCMV5, and 1 µg of pSV-beta ; (b) 2 µg of p3TP-Lux with either 2 µg of type I receptors or type I chimeras, 1 µg of pCMV5, and 1 µg of pSV-beta . The transfections also included 0.1 mM chloroquine/ml and 0.125 mg/ml DEAE-dextran in phosphate-buffered saline. In assays where two type I receptors were co-transfected, 1.5 µg of each receptor cDNA were used. In assays where the activity for cells co-transfected with two receptors had to be compared with the activity of single receptor transfected cells, the second receptor was substituted with 1.5 µg of pCMV5 DNA in the single receptor transfected cells. After 3 h incubation at 37 °C, cells were shocked with 10% Me2SO in phosphate-buffered saline for 2 min and allowed to recover overnight in MEM/NEAA + 10% FBS. The following day, cells were trypsinized and replated into a 24-well plate and incubated for at least 3 h in MEM/NEAA + 10% FBS to allow the cells to reattach. Prior to the luciferase reporter induction, cells were incubated for 2 h in MEM/NEAA + 0.2% FBS. Medium was then exchanged for fresh MEM/NEAA + 0.2% FBS with the addition of the different cytokines to induce the luciferase reporter. After 16 h incubation, cells were washed with phosphate-buffered saline and lysed for 15 min in 40 µl of lysis buffer. 10 µl were used to measure the luciferase activity using the luciferase assay system (Promega) in a Berthold Lumat LB 9501 luminometer. The remaining 30-µl lysates were used to measure the LacZ activity as described previously (45). Luciferase activity was corrected for LacZ activity.

Primers-- The following primers were used in the constructions: 1 (ALK-1Acc3), 5'-GGGAGTGGCTCCGGACTCCCCTTCC-3'; 2 (TbR-IAcc3), 5'-GGTTCTGGCTCCGGATTACCATTGC-3'; 3 (ActR-IBAcc3), 5'-GGGTCTGGCTCCGGATTACCCCTCT-3'; 4 (ALK-3Acc3), 5'-GTAGTGGGTCCGGACTACCT-3'; 5 (ALK-1MscI/TbR-I), 5'-CAGATGGCCA(G/C)TGGCAGCTGTCATTGCTGGACC-3'; 6 (ALK-3BsmI/TbR-I), 5'-GGCAGCATTCG(A/C)TGGCAGCTGTCATTGCTGGA; 7, 5'-CTACCTGCCGGGGGGGCCTGGTGCAC-'3; 8, 5'-GTGCACCAGGCCCCCCCGGCAGGTAG-'3; 9, 5'-CGGGGGGCCTGTTGCACAGTAGTGCTG-'3; 10, 5'-CAGCACTACTGTGCAACAGGCCCCCCG-'3; 11, 5'-CGGGGGGCCTGGTACACAGTAGTGC-'3; 12, 5'-GCACTACTGTGTACCAGGCCCCCCG-'3; 13, 5'-CCGCAGCCCTGATGTTCCTG-'3; 14, 5'-CAGGAACATCAGGGCTGCGG-'3.

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Test of the Chimeric Receptor Signaling Assay-- Since the ligand and type II receptor for ALK-1 are not known, a signaling assay for ALK-1 activity is not currently available. We sought to develop a signaling assay involving chimeric receptors. As an initial test, we created chimeric receptors which we surmised would be able to transmit a signal. ALK-3 is the receptor for BMP-2 and to a lesser extent BMP-7, but does not signal in the p3TP-Lux reporter assay. Thus we created a chimeric ALK-3 receptor by exchanging the ALK-3 cytoplasmic domain with the corresponding Tbeta R-I and ActR-IB domains. Three chimeras were constructed; two were exchanged in the GS domain, ALK-3/Tbeta R-I(GS) and ALK-3/ActR-IB(GS), and one within the transmembrane (TM) domain, ALK-3/Tbeta R-I(TM) (Fig. 1). In order to eliminate signaling through endogenous TGF-beta receptors, the chimeric receptors were transfected into one of two mink lung cell derivatives, R-1B or DR-26, which are deficient for Tbeta R-I and Tbeta R-II, respectively (32, 42). We observed that in transiently transfected R-1B or DR-26 cells, all ALK-3 chimeric receptors were able to induce a significant increase of luciferase activity over basal level after incubation with either BMP-2 or BMP-7. The highest activity was observed in DR-26 cells with the ALK-3/ActRIB chimera (Fig. 2A).


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Fig. 1.   Schematic illustration of chimeric type I receptors. The extracellular and intracellular domains were exchanged either in the GS domain or just adjacent to the transmembrane domain (TM). Chimeric receptors were tested for their ability to activate the luciferase reporter construct p3TP-Lux in mink lung cells upon the induction of different ligands.


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Fig. 2.   BMP and activin A-induced signaling in DR-26 cells via chimeric receptors. DR-26 cells were transiently transfected with the indicated chimeric receptors or the empty expression vector pCMV5. A fixed amount of the reporter p3TP-Lux was included in all transfections. Luciferase activity in cell lysates was plotted as the average and standard deviation for transfections done in triplicate. Only data from the chimeras exchanged in the GS domain are shown. A, cells were incubated overnight with either 15 nM BMP-2 or 15 nM BMP-7 or without BMP (w/o). B, cells were incubated overnight without ligand (w/o), or with 150 µl of conditioned medium (activin) of COS cells transfected with an activin A expression construct, or with 150 µl of conditioned medium (IMD medium) of COS cells not transfected with the activin A expression construct.

Effect of BMP and Activin A on the ALK-1 Chimeric Receptors-- Since the BMPs could induce a signal via the ALK-3 chimeras, we next examined BMP-induced signaling with chimeras containing the extracellular domain of ALK-1 (Fig. 1). None of the ALK-1 constructs were able to transmit a signal in either R-1B cells (not shown) or DR-26 cells (Fig. 2A). However, the ALK-1 chimeras, even in the absence of any ligand, exhibited a 2-3-fold increase in basal luciferase activity. This ligand-independent high basal activity was observed in nearly all subsequent experiments with the ALK-1 chimeras. Despite this background, the lack of BMP-2 or BMP-7-induced signaling for the ALK-1 chimeras indicates that neither are ligands for ALK-1.

We next examined activin A-induced signaling in the assay. Mock-transfected cells (empty vector) showed a 4-fold increase of luciferase activity after activin A incubation (Fig. 2B), presumably due to the presence of the endogenous ActR-IB receptor (23). Despite this background level of activity, cells transfected with wild-type ActR-IB showed a 12-fold increase over background, and the ActR-IB/Tbeta R-I chimera showed a 21-fold increase in activity (Fig. 2B). When we tested activin A-induced signaling activity for the two ALK-1 chimeras ALK-1/ActR-IB(GS) and ALK-1/Tbeta R-I(GS), there was an increase of only 3-4-fold over the ALK-1 chimera basal level. This level was no more than the endogenous background level observed with vector alone. These data indicate that activin A is not a ligand for ALK-1.

Effect of TGF-beta 1, -2, and -3 on the ALK-1 Chimeric Receptors-- We next examined the ability of TGF-beta ligand to induce signaling through the ALK-1 chimeras. As a positive control we tested Tbeta R-I-transfected R-1B cells, which lack endogenous Tbeta R-I. These transfectants responded to TGF-beta 1, TGF-beta 2, or TGF-beta 3 with a significant increase of luciferase activity compared with mock-transfected cells (Fig. 3). Despite the high background, the ALK-1/Tbeta R-I(GS) chimera also showed a clear response to TGF-beta 1 and TGF-beta 3, although only half that of Tbeta R-I. Significantly, the chimera did not respond to TGF-beta 2. The ALK-1/Tbeta R-I(TM) chimera also showed a similar ligand-specific response although the magnitude of the response was lower (data not shown). This response was specific to the ALK-1 extracellular domain as ALK-3/Tbeta R-I(GS) showed no response to any of the TGF-beta ligands (data not shown). These combined results indicate that TGF-beta 1 and -beta 3 can induce a specific signal via the ALK-1 chimeras. The binding specificity for the TGF-beta isoforms resembles that of endoglin (46), consistent with the idea that endoglin and ALK-1 are in the same signaling pathway.


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Fig. 3.   TGF-beta 1 and -beta 3 induced ALK-1/Tbeta R-I(GS) signaling in R-1B cells. Cells were transiently transfected with p3TP-Lux and either the TGF-beta type I receptor, the ALK-1 chimeric receptor ALK-1/Tbeta R-I(GS), or pCMV5. Cells were incubated overnight with 4 ng/ml TGF-beta 1, -beta 2, -beta 3, or without TGF-beta (w/o). Luciferase activity in cell lysates was plotted as the average and standard deviation for transfections done in triplicate.

One of the controls, Tbeta R-I/ActR-IB, did not respond to any of the TGF-beta s (Fig. 3), although the chimeric protein was expressed. This was surprising, since the exchanged ActR-IB kinase domain is nearly identical to the kinase domain of Tbeta R-I, particularly in the L45 region of kinase subdomains IV and V, which are responsible for the TGF-beta specificity (47). These results suggest that the type I receptor is not solely responsible for the signaling specificity and that another requirement may be the correct combination of type I and II receptors in the complex. Consistent with this, Persson and colleagues (34) showed that the chimeric Tbeta R-I/BMPR-IB receptor is able to signal in combination with the chimeric Tbeta R-II/ActR-IIB receptor upon TGF-beta addition but not with the wild-type TGF-beta type II receptor Tbeta R-II.

Receptor Complexes with Endoglin and ALK-1-- Since endoglin and ALK-1 show the same TGF-beta ligand specificity, we determined whether they could form a receptor complex. We also determined whether ALK-1 can form a ligand-independent complex with either Tbeta R-II or ActR-II, which might explain the high basal level of luciferase activity for the ALK-1 chimeras, even in the absence of any ligand. COS cells were co-transfected with endoglin and ALK-1 (HA-tagged), lysed, and immunoprecipitated with either the monoclonal HA antibody or rabbit anti-endoglin sera. The immunoprecipitations were separated by SDS-PAGE and immunostained with the reciprocal antibody. Fig. 4, A and B, shows that endoglin and ALK-1 can be immunoprecipitated in a ligand-independent complex. However, a different anti-endoglin antibody, P1D3, did not co-immunoprecipitate ALK-1, although endoglin was immunoprecipitated (data not shown). P1D3 is directed against an epitope encoded by exons 2 and 3 (48). This region may also be critical for the endoglin/ALK-1 interaction, which may be blocked by P1D3.


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Fig. 4.   Ligand-independent endoglin/type I receptor and ALK-1/type II receptor complex formation. A, ligand-independent endoglin/ALK-1 interaction revealed by type I receptor immunoprecipitation. COS cells were transiently transfected with the indicated combinations of endoglin and different type I receptors (HA-tagged). Cells were lysed, and type I receptors were immunoprecipitated with the monoclonal HA antibody. Precipitates were resolved by SDS-PAGE and blotted, and co-precipitated endoglin was visualized by immunoblot staining with rabbit anti-endoglin sera. To assess the type I receptor precipitation efficiency, the blot was restained with the monoclonal HA antibody. To assess the transfection efficiency, an aliquot of the cell lysates prior to the precipitation was resolved by SDS-PAGE, blotted, and the expressed receptors were visualized by immunoblot staining with the appropriate antibody. B, ligand-independent endoglin/ALK-1 interaction revealed by anti-endoglin immunoprecipitation. COS cells were transiently transfected as in A. Cell lysates were immunoprecipitated using anti-endoglin serum and electrophoretically resolved and visualized as in A. C, ligand-independent ALK-1/Tbeta R-II and ALK-1/ActR-II interaction. COS cells were transiently transfected with the indicated receptor combinations. Tbeta R-II and ActR-II are HA-tagged. Cells were lysed and ALK-1 was immunoprecipitated with rabbit anti-ALK-1 sera. Precipitates were resolved by SDS-PAGE and blotted, and the co-precipitated type II receptors were visualized by immunoblot staining with the monoclonal HA antibody.

Similar immunoprecipitations with endoglin and Tbeta R-I or ActR-IB demonstrate that these two type I receptors are also able to co-immunoprecipitate endoglin, although these interactions were weaker than for ALK-1 (Fig. 4A). Co-immunoprecipitations for endoglin and the type II receptors Tbeta R-II and ActR-II did not reveal any interactions among these receptors (data not shown).

In order to identify ALK-1 interactions with type II receptors, cells were co-transfected with combinations of either ALK-1 and Tbeta R-II or ALK-1 and ActR-II. Immunoprecipitation for ALK-1 brought down both type II receptors (Fig. 4C). Reciprocal immunoprecipitations for the type II receptors brought down ALK-1 (data not shown). These results confirm that ALK-1 and these type II receptors are in a ligand-independent receptor complex and suggest that Tbeta R-II and ActR-II can both act as type II receptors for ALK-1.

Human Serum Contains an Unknown Ligand for ALK-1-- In an effort to identify a ligand for ALK-1, we also examined human serum as a source of ligand in the signaling assay. All three ALK-1 chimeras transfected into either R-1B or DR-26 cells showed a dosage-dependent increase in induction of luciferase activity which reaches a plateau at 20% serum (Fig. 5A). In order to determine if this response was due to TGF-beta present in the serum, R-1B cells were transfected with Tbeta R-I or ALK-1/Tbeta R-I(GS) and incubated with either TGF-beta 1 or 20% human serum in the presence or absence of a TGF-beta 1 neutralizing antibody. The neutralizing antibody reduced the level of luciferase activity by more than half for Tbeta R-I-transfected cells incubated with TGF-beta 1 (Fig. 5B). However, it had no effect on the human serum-induced signaling activity of the ALK-1/Tbeta R-I(GS) transfectants.


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Fig. 5.   Human serum-induced ALK- 1 chimera signaling in R-1B and DR-26 cells. Luciferase activity in cell lysates was plotted as the average and standard deviation for transfections done in triplicate. A, R-1B cells were transiently transfected with p3TP-Lux and the indicated receptor or pCMV5. Cells were incubated overnight with the indicated amount of heat-inactivated human serum or without serum (w/o). B, R-1B cells were transiently transfected as in A. Cells were incubated overnight with either 4 ng/ml TGF-beta 1 or 20% heat-inactivated human serum, or without ligand (w/o). Neutralizing antibody to TGF-beta 1 was added where indicated at 1 µg/ml. C, DR-26 cells were transiently transfected with p3TP-Lux and the indicated receptors or pCMV5. Cells were incubated overnight with either 4 ng/ml TGF-beta 1, 20% heat-inactivated human serum, or without ligand (w/o). D, inhibin A does not induce ALK-1 chimera signaling. R-1B cells were transiently transfected with p3TP-Lux and the indicated receptor or pCMV5. Cells were incubated overnight with either the indicated amount of recombinant human inhibin A or without ligand (w/o). Luciferase activity in cell lysates was plotted as the average and standard deviation for transfections done in triplicate.

In addition, when DR-26 cells were transfected only with Tbeta R-II, they responded strongly to TGF-beta 1 incubation yet showed no induction with the human serum (Fig. 5C). R-1B cells transfected with ActR-IB or the ALK-3 chimeras also showed no response to the human serum (data not shown). These combined data show that the serum-induced reporter activity observed with ALK-1 chimera-transfected cells is not due to the presence of TGF-beta , activin A, or BMP in the serum.

Inhibin A is similar to activin, present in serum, and binds to ActR-II (49-51). Since we have shown that ActR-II can be found in a complex with ALK-1, and DR-26 cells express the endogenous activin type II receptor, the observed serum response may be induced by inhibin A via an ActR-II·ALK-1 chimera receptor complex. However, inhibin A was also unable to induce signaling via the ALK-1 chimeras (Fig. 5D).

Effect of HHT-associated Patient Mutations on ALK-1 Signaling-- To examine further the presence of an ALK-1 ligand in serum, we tested the effect of ALK-1 chimeras harboring mutations that have been identified in HHT patients. Mutations introduced include one insertional mutation, insG140 (10), and three base substitutions causing amino acid changes, W50C, C51Y, and R67Q (9, 10). These mutations were introduced into the extracellular domain of the ALK-1/Tbeta R-I(TM) chimera, and their effect on the serum-induced signaling activity was determined. The insertional mutation served as a negative control as it introduces a frameshift early in the extracellular (ligand binding) domain, leading to a premature stop codon. Examination of serum-induced luciferase activity demonstrated that the insG140 and C51Y mutations both showed no measurable signaling (Fig. 6). The signaling activity for the W50C and R67Q mutations was almost completely abolished, with only a slight increase upon serum induction (Fig. 6). Significantly, for all of the mutations, the usually high basal level of luciferase activity for the ALK-1 chimeras was comparable to the basal level of mock-transfected cells. The W50C and R67Q amino acid substitutions were also examined for TGF-beta 1-dependent induction of the luciferase reporter. The signaling activity of these mutant ALK-1 chimeras was also abrogated (data not shown). These data are the first demonstration that any of the ALK-1 missense mutations identified in HHT patients have deleterious consequences for ALK-1 signaling.


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Fig. 6.   Effect of HHT-associated mutations on ALK-1 signaling. R-1B cells were transiently transfected with p3TP-Lux and the indicated receptors or pCMV5. Cells were incubated overnight with either 20% heat-inactivated human serum or without ligand (w/o).

ALK-1 Signaling Interferes with TGF-beta -induced Tbeta R-I Signaling-- Although ALK-1 and Tbeta R-I bind TGF-beta 1 and TGF-beta 3 and can form a ligand-independent complex with endoglin, they do not activate the same genes (22, 25, 31). Thus, we hypothesized that wild-type ALK-1 may have an opposing effect on TGF-beta signaling through Tbeta R-I. In order to induce ALK-1 signaling independent of TGF-beta addition, we designed a constitutively active form of ALK-1. For other type I receptors, the substitution of either Glu or Asp for a critical residue in the kinase domain creates a constitutively active type I receptor able to signal without ligand or corresponding type II receptor (18, 44). Therefore, we created an "activated" form of ALK-1 by replacing Gln (wild type) with Asp at the equivalent position in ALK-1 (ALK-1Q201D). The effect of the activated ALK-1 receptor in the luciferase assay was determined.

Co-expression of Tbeta R-I and wild-type ALK-1 yielded a 20% decrease of TGF-beta -induced signaling in comparison to Tbeta R-I alone (Fig. 7A). This effect is seen both for TGF-beta 1 and -beta 2. Furthermore, when activated ALK-1 is co-expressed with Tbeta R-I, TGF-beta -induced signaling is decreased by 33% in comparison to Tbeta R-I alone. Since constitutively activated receptors do not always signal with the same intensity as the wild-type receptor when induced by ligand, we determined whether serum-activated ALK-1 might have a more potent effect on Tbeta R-I signaling through TGF-beta 1. R-1B cells were co-transfected with Tbeta R-I and ALK-1 and incubated with either TGF-beta 1 or TGF-beta 1 plus human serum. The resulting signaling data were compared with cells transfected with Tbeta R-I alone. Co-incubation of Tbeta R-I-transfected cells with TGF-beta 1 and serum shows a 31% reduction in signaling compared with TGF-beta 1 alone (Fig. 7B). This may be due to serum components that bind to TGF-beta 1 and sequester it or otherwise inhibit its function. The ALK-1 and Tbeta R-I co-transfection showed a 10% reduction in luciferase activity after TGF-beta 1 induction. However, the TGF-beta 1 plus human serum co-incubation resulted in a 70% reduction in signaling (Fig. 7B). These data demonstrate that in this system, ALK-1 signaling opposes the Tbeta R-I-induced pathway. It is unclear whether ALK-1-mediated signaling actively inhibits the PAI-1 promoter or if the ALK-1-induced pathway is competing for components of the Tbeta R-I-signaling pathway, such as Smad4.


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Fig. 7.   Effect of ALK-1 signaling on TGF-beta -induced Tbeta R-I signaling. Luciferase activity in cell lysates was plotted as the average and standard deviation for transfections done in triplicate. A, R-1B cells were transiently transfected with p3TP-Lux and the indicated receptors or pCMV5. Cells were incubated overnight with either 4 ng/ml TGF-beta 1, 4 ng/ml TGF-beta 2, or without ligand (w/o). B, R-1B cells were transiently transfected with p3TP-Lux and the indicated receptors or pCMV5. Cells were incubated overnight with either 4 ng/ml TGF-beta 1, 20% heat-inactivated human serum (h.serum), or 4 ng/ml TGF-beta 1 and 20% heat-inactivated human serum (beta1+h.serum), or without ligand (w/o).


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The autosomal dominant vascular disorder HHT is characterized by the development of localized vascular arteriovenous malformations. Human genetic studies have shown that HHT can be caused by mutations in one of two genes, endoglin or ALK-1. Endoglin is a TGF-beta 1- and -beta 3-binding protein expressed primarily on the surface of endothelial cells, and ALK-1 is a type I TGF-beta superfamily receptor also expressed on the surface of endothelial cells. However, the role of these receptors in the pathogenesis of HHT is unclear.

TGF-beta is known to play a key role in angiogenesis, especially after injury or inflammation (56-58). In addition, the phenotypes of the TGF-beta 1 (ligand) and the Tbeta R-II (receptor) knock-out mice suggest a critical role in early yolk sac vasculogenesis and hematopoiesis (59, 60). Intriguingly, the vascular defects in the TGF-beta 1 null mice share some histological similarities to the vascular lesions seen in HHT patients (59). ALK-1 expression in the developing mouse embryo parallels that of TGF-beta 1 (61), and ALK-1 knock-out mice are also embryonic-lethal due to defects in yolk sac vasculogenesis and hematopoiesis.2 The data from these mouse mutations might suggest that ALK-1 and endoglin act in the same angiogenic pathway involving TGF-beta .

However, additional data suggest complications to this simple interpretation. Although Tbeta R-I and ActR-IB signal in mink lung cells through the PAI-1 promoter reporter system, ALK-1 does not signal in a TGF-beta 1- or activin A-specific manner (22). Furthermore, ALK-1 does not mediate TGF-beta 1-like responses such as growth inhibition or elevated expression of extracellular matrix proteins (23, 25, 31). These data suggest distinct roles for ALK-1- and TGF-beta -mediated signaling.

Through the use of a chimeric receptor signaling assay based on the inducible PAI-1 reporter construct, we have shown that activin A, BMP-2, BMP-7, and inhibin A are unable to activate ALK-1 signaling. The negative result for activin A was surprising since activin A binds to ALK-1 in the presence of the activin type II receptor (22), and our data and that of others (25, 31) show ALK-1 and ActR-II present in a ligand-independent complex. However, we created two distinct ALK-1 chimeras, containing either the ActRI-B or Tbeta R-I kinase domains, and neither exhibited any evidence of signaling in our reporter system. Furthermore, a positive control chimera, ActR-IB/Tbeta R-I(GS), demonstrated an even higher activin-induced signaling activity than the natural activin type I receptor ActR-IB. Thus, we conclude that activin A is not a signaling ligand for ALK-1.

The ALK-1 chimeras show increased signaling activity after TGF-beta 1 and TGF-beta 3 incubation but not with TGF-beta 2. This ligand specificity parallels that of endoglin (46). Both ALK-1 and endoglin are also expressed in trophoblasts during early stages of placenta development (61, 62). These data and our endoglin/ALK-1 and ALK-1/Tbeta R-II co-immunoprecipitation results suggest that ALK-1 and endoglin are part of a TGF-beta signaling receptor complex. The TGF-beta -induced ALK-1 signaling in R-1B cells is only half that of the Tbeta R-I controls. This might be due to a lower affinity of ALK-1 to TGF-beta or due to the presence of two different type II receptor binding partners for ALK-1. The second type II receptor might be able to sequester ALK-1 resulting in reduced ligand-induced signaling activity. Our serum and co-immunoprecipitation data show that ALK-1 is able to use two different type II receptors, both present in R-1B cells.

Additional but indirect evidence for the importance of endoglin is provided by Matsuzaki et al. (64), who reported intrinsic ligand-independent interactions among type III and I TGF-beta receptors and also among type II and I receptors but not among type III and II receptors, which were ligand-dependent. Similarly, we observed ligand-independent complexes of endoglin/ALK-1 (a type III-I interaction), as well ALK-1/Tbeta R-II and ALK-1/ActR-II (a type I-II interaction) but not for endoglin/Tbeta R-II or endoglin/ActR-II (a type III-II interaction). They also tested the phosphorylation status of the Tbeta R-I·Tbeta R-II receptor complex after TGF-beta addition and found an increase in Tbeta R-I and Tbeta R-II phosphorylation. When betaglycan was added to this complex they observed an additional increase of phosphorylation for both. The transmembrane and cytoplasmic domain of endoglin is highly conserved among different species and shows high homology (71%) to the corresponding region of the TGF-beta type III receptor betaglycan (38-40, 46, 52, 53). The combined data suggest that type III receptors (either betaglycan or endoglin) promote efficient type I receptor signaling.

TGF-beta cross-linking studies in porcine aortic endothelial cells and pre-B leukemic cells have demonstrated endoglin in a complex with Tbeta R-I and Tbeta R-II (52, 65). In both studies the immunoprecipitation was performed with either an endoglin- or Tbeta R-II-specific antibody after TGF-beta 1 cross-linking and resulted in the co-precipitation of a protein of approximately 70 kDa, the predicted size for a type I receptor. The authors concluded that this was the TGF-beta type I receptor. However, since ALK-1 is expressed in endothelial cells, the co-precipitated type I receptor in porcine aortic endothelial cells may actually have been ALK-1. One possibility is that ALK-1 and Tbeta R-I are expressed on different subsets of cells which would allow for unique and specific responses to TGF-beta . This hypothesis has also been proposed by Panchenko et al. (66). They showed that the rat ALK-1 is highly expressed in adult lung, whereas Tbeta R-I is not, and that the two receptors are also differentially expressed in the fetal lung. Therefore, it is possible that some of the well documented endothelial responses to TGF-beta (56-58) are due to signaling through ALK-1 and not Tbeta R-I.

A component of serum, which seems to be not one of the "common" TGF-beta family members, can act as a third signaling ligand for ALK-1. Although TGF-beta 1- and beta 3-induced ALK-1 signaling occurs via Tbeta R-II, signaling induced by the "serum ligand" does not, since serum-induced signaling via ALK-1 chimeras was observed in cells lacking either Tbeta R-I or Tbeta R-II. An extensive PCR screen with degenerate oligonucleotides for type II receptors could not identify any novel type II receptor in endothelial cells.3 Thus, the serum ligand may instead signal through ActR-II. Although we cannot exclude unknown candidates, these data suggest Tbeta R-II and ActR-II are the major type II receptors for ALK-1.

The existence of a third unknown ligand for ALK-1 complicates our understanding of the function of ALK-1 in endothelial cells. Previous studies have shown that ALK-1 does not mediate growth inhibition or elevated expression of extracellular matrix proteins such as fibronectin or PAI-1 after TGF-beta incubation (23). We have shown that ALK-1 signaling is able to oppose TGF-beta -induced PAI-1 promoter activity, although we cannot conclude if this is a direct inhibitory effect of ALK-1 signaling on the PAI-1 promoter or if the Tbeta R-I and ALK-1 pathways overlap and therefore compete for common signaling mediators. In future studies of TGF-beta signaling, it will be critical to differentiate ALK-1 versus Tbeta R-I signaling, particularly in cells that co-express both receptors.

We are still a long way from understanding the roles of ALK-1 and endoglin in angiogenesis and their role in the pathogenesis of HHT. Nonetheless, the cumulative data suggest a basic outline for the role of the two receptors in these processes. With few exceptions, the endothelial cell turnover in a healthy adult organism is very low. The maintenance of this quiescent state is thought to be regulated by endogenous negative regulators. During angiogenesis the balance between negative and positive regulators is shifted, and positive regulators dominate. Studies have shown that TGF-beta (particularly TGF-beta 1) can be either a positive or negative regulator (reviewed in Ref. 56). A biphasic effect of TGF-beta on angiogenesis is dependent on TGF-beta concentration (67). Therefore, endothelial response to TGF-beta may also be concentration-dependent (68). This biphasic effect may be established by the use of two different receptors such as Tbeta R-I and ALK-1, which may have different affinities for TGF-beta . Endoglin might be required as a receptor-partner for both type I receptors in order to maintain the balance between negative and positive regulation of angiogenesis. This picture is complicated by the identification of a third unknown ligand. ALK-1 antagonistic activity could be induced by the ligand at different time points. Alternatively, ALK-1 signaling via this novel ligand may result in other angiogenic responses that are TGF-beta -independent. Future studies are required to identify the ligand present in serum and to dissect the ALK-1/endoglin signaling pathway and its role in angiogenesis and the pathogenesis of HHT.

    ACKNOWLEDGEMENTS

We thank D. Klaus for technical assistance; T. Stenzel (Duke University) for making the endoglin polyclonal antibody; B. Cullen (Duke University) for the gift of the COS cell line; and H. Esche (Universitätsklinikum Essen, Germany) for the gift of the monoclonal HA hybridoma. Inhibin A was obtained from A. F. Parlow (Harbor-UCLA Medical Center) through the National Hormone and Pituitary Program.

    FOOTNOTES

* This work was supported in part by National Institutes of Health Grant HL 49171 (to D. A. M.) and by a Medical Research Council grant (to L. A.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ Supported by the Deutsche Forschungsgemeinschaft.

parallel Medical Research Council (Canada) scholar.

** Established Investigator Award of the American Heart Association. To whom correspondence should be addressed. Tel.: 919-684-3290; Fax: 919-681-9193; E-mail: march004{at}mc.duke.edu.

2 En Li, personal communication.

3 D. W. Johnson and D. A. Marchuk, unpublished data.

    ABBREVIATIONS

The abbreviations used are: HHT, hereditary hemorrhagic telangiectasia; ALK-1, activin receptor-like kinase 1; TGF-beta , transforming growth factor beta ; PAI, plasminogen activator inhibitor; Tbeta R-I or Tbeta R-II, type I or type II TGF-beta receptor; ActR-I or ActR-II, type I or type II activin receptor; BMP, bone morphogenetic protein; BMPR-I or II, type I or type II bone morphogenetic protein receptor; GS, glycine-serine domain; TM, transmembrane domain; PAGE, polyacrylamide gel electrophoresis; HA, hemagglutinin; ins, insertion; PCR, polymerase chain reaction; FBS, fetal bovine serum; MEM, minimal essential medium; NEAA, nonessential amino acids.

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ABSTRACT
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RESULTS
DISCUSSION
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