Identification of Smad2, a Human Mad-related Protein in the Transforming Growth Factor beta  Signaling Pathway*

(Received for publication, August 12, 1996, and in revised form, October 30, 1996)

Atsuhito Nakao Dagger §, Eva Röijer , Takeshi Imamura Dagger , Serhiy Souchelnytskyi Dagger , Göran Stenman , Carl-Henrik Heldin Dagger and Peter ten Dijke Dagger

From the Dagger  Ludwig Institute for Cancer Research, Box 595, S-751 24 Uppsala, Sweden and  Laboratory of Cancer Genetics, Department of Pathology, Göteborg University, Sahlgrenska Hospital, S-413 45 Göteborg, Sweden

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES


ABSTRACT

Transforming growth factor-beta (TGF-beta ) superfamily members are multifunctional cytokines that exert their effects via heteromeric complexes of two distinct serine and threonine kinase receptors. Drosophila mothers against decapentaplegic and related genes in Caenorhabditis elegans, Xenopus, and mammals were shown to function downstream in the intracellular signaling pathways of TGF-beta superfamily members. Here we report the cloning of a Mad-related protein, termed Sma- and Mad-related protein 2 (Smad2). TGF-beta stimulated the phosphorylation and nuclear translocation of Smad2 in nontransfected Mv1Lu cells. In addition, we demonstrated that TGF-beta and activin mediated phosphorylation of Smad2 after its overexpression with appropriate type I and II receptors in COS cells. Smad2 and Smad1 were found to be broadly expressed in human tissues. Smad2 is closely linked to DPC4 on chromosome 18q21.1, a region often deleted in human cancers. Cells that lack Smad2 may escape from TGF-beta -mediated growth inhibition and promote cancer progression.


INTRODUCTION

Transforming growth factor beta 1 (TGF-beta 1)1 is the prototype of a family of structurally related cytokines, which also includes activins and bone morphogenetic proteins (BMPs). TGF-beta superfamily members are multifunctional and have been shown to control proliferation, differentiation, migration, and apoptosis of many different cell types (1). Signaling of these proteins occurs via ligand-mediated hetero-oligomerization of type I and II receptors, which are both endowed with intrinsic serine and threonine kinase activities (2). The TGF-beta and activin type II receptors are constitutively active kinases that transphosphorylate their specific type I receptors on association. The type I receptors thereby become activated, which is necessary and sufficient for most signaling responses (3-5). The functionally active receptor complex may be heterotetrameric, consisting of two molecules of each receptor type (6).

Targets downstream of serine and threonine kinase receptors that provide the link with the transcriptionally induced effects of TGF-beta superfamily members are poorly understood. TGF-beta -like signaling pathways are present in Drosophila and Caenorhabditis elegans. Genetic analysis of signaling mediated by decapentaplegic, a member of the TGF-beta superfamily in Drosophila, has led to the identification of mothers against dpp (Mad) (7), a gene the activity of which is controlled by Dpp. Genetic evidence suggests that Mad is an essential downstream component for all Dpp-dependent signaling events (7-10). In addition, Mad homologous genes have recently been identified in C. elegans (sma genes) (11) and Xenopus (12) and mammals (Smad genes) (10, 13-15). A putative tumor suppressor gene function in pancreatic cancer was ascribed to DPC4 (14). The Mad family of proteins lacks known sequence motifs but has conserved N-terminal (MH1) and C-terminal (MH2) domains, which are linked by a sequence rich in serine, threonine and proline residues. Smad1 is phosphorylated and translocated to the nucleus after stimulation of BMP-2 (10). In addition, the C-terminal domain of Smad1 was found to have transcriptional activity when fused to a heterologous DNA binding domain. The whole Smad1 protein was found to be transcriptionally latent and became activated on BMP receptor-mediated phosphorylation (13). In Xenopus, Smad1 induced ventral mesoderm, a BMP-like response, and Smad2 induced dorsal mesoderm, a Vg1- and nodal-like response (12). These results suggest that Mad family members may encode transcription factors that mediate distinct responses to TGF-beta family members.

Here we demonstrate the TGF-beta -induced phosphorylation and nuclear translocation of a ubiquitously expressed human Mad-related protein, Smad2. The chromosomal location of Smad2 is close to DPC4 on chromosome 18q21.1, a region often deleted in cancer, suggesting a putative tumor suppressor function for Smad2.


EXPERIMENTAL PROCEDURES

cDNA Cloning

Smad1 was cloned by reverse transcription-polymerase chain reaction (RT-PCR) from placenta tissue using the primers 5'-TATAACTAGTGCTGTCATTATG-3' and 5'-TGCAAGGCTCAATAGTTTTCCA-3' that were based on the expression sequence tags (ESTs) R19015[GenBank] and R10104[GenBank] from the Washington University-Merck EST Project. Smad2 was identified by RT-PCR from human erythroleukemia cells using a degenerated sense primer, 5'-CCGAATTCTG(TC)AT(CT)AA(CT)CC(ACT)AC-3', and an antisense primer, 5'-CCGGATCC(AG)TT(AGCT)C(GT)(AG)TT(AGCT)AC(AG)TT-3', that were based on regions of sequence similarity between the Drosophila Mad and C. elegans Sma genes. The 0.5-kb insert of the Smad2 PCR recombinant was used as a probe in the screening of a human brain cDNA library, and the sequence of a 2-kb Smad2 cDNA clone was determined.

Northern Blot Analysis

Northern blot filters with mRNAs from different tissues were obtained from Clontech. cDNA restriction fragments encoding complete coding regions of Smad1 and Smad2 were used as probes. The filters were hybridized and washed as described previously (16).

Constructs

Expression constructs for Tbeta R-I, Tbeta R-II, activin type IB receptor (ActR-IB), and activin type II receptor (ActR-II) were previously described (16). Smad1-Flag in pCMV5 was obtained from Dr. J. Wrana (10). For expression of Smad2, its cDNA was subcloned in pcDNA3. The Smad2-His/Flag construct was made by PCR using a sense primer encoding 6 histidine residues and subcloning the PCR product into pcDNA3-Flag.

Cell Lines

COS cells and Mv1Lu mink lung epithelial cells were obtained from the American Type Culture Collection. The R4.2 mutant of Mv1Lu cells was provided by Dr. J. Massagué (Memorial Sloan Kettering Cancer Center, New York). Cells were cultured in Dulbecco's modified Eagle's medium (Life Technologies, Inc.) with 10% fetal bovine serum, 100 units/ml penicillin, and 50 µg/ml streptomycin.

Preparation of Polyclonal Antibody

A synthetic peptide corresponding to amino acid residues 227-244 in Smad2 was coupled to keyhole limpet hemocyanin (Calbiochem) using glutaraldehyde, mixed with Freund's adjuvant, and used to immunize rabbits from which the SED antiserum was obtained.

Transient Transfection, Metabolic Labeling, Immunoprecipitation, and SDS-PAGE

Transfection, metabolic labeling of cells, immunoprecipitation, and SDS-PAGE were performed as described previously (16).

[32P]Orthophosphate Labeling of Cells and Two-dimensional Phosphoamino Acid Analysis

Mv1Lu and COS cells were labeled for 2 h in phosphate-free medium supplemented with 0.5% dialyzed fetal bovine serum, 15 mM HEPES, pH 7.2, and 4.0 mCi/ml or 1 mCi/ml [32P]orthophosphate, respectively. Cells were incubated in the absence or presence of ligand, lysed, and subjected to immunoprecipitation with SED antiserum. The precipitate was analyzed by SDS-PAGE. Phosphorylated Smad2 was cut out from the gel, and the protein was extracted and hydrolyzed. Phosphoamino acids were separated by two-dimensional thin layer electrophoresis on cellulose plates (17).

Nuclear Translocation

Subcellular localization of Smad2 in Mv1Lu cells was determined as previously reported (18). The SED antiserum was used at a 50-100-fold dilution.

Somatic Cell Hybrid and Fluorescence in Situ Hybridization (FISH)

Two panels of human-rodent somatic cell hybrids, mapping panel 2, and the regional mapping panel for chromosome 18 (19) were used to map the Smad2 gene. Southern blots were hybridized with a Smad2 cDNA probe containing the complete coding region. The mapping of Smad2 was also confirmed and refined by FISH. The yeast artificial chromosome (YAC) Y739A3 was cohybridized with a chromosome 18 alpha  satellite probe (D18Z1; Oncor) as described previously (20).

PCR Analysis of YAC DNA

Three Centre d'Etude du Polymorphisme Human YACs, Y747A6, Y945B11, and Y739A3 (obtained from Genome Systems, Inc.), known to contain DPC4 and the Mad-related gene JV18-1 (15, 21), were analyzed by PCR for the presence of Smad2 sequences using two primer pairs (sense primer 1, 5'-TCGAAAAGGATTGCCACAT-3'; antisense primer 1, 5'-AGGGTTTACACATACTTCATCC-3'; and sense primer 2, 5'-CGAAGGCAGACGGTAACA-3'; antisense primer 2, 5'-GCTTGAGCAACGCACTGA-3') corresponding to exons 2 and 11 of Smad2.


RESULTS

cDNA Cloning and mRNA Expression of Smad1 and Smad2

A data base search for mammalian sequences related to the Mad gene revealed the existence of multiple human and mouse ESTs corresponding to different genes. PCR using placenta cDNA with two Mad-related EST primers resulted in the isolation of Smad1 (10, 13). The closely related Smad2 was identified by RT-PCR using human erythroleukemia cell mRNA with two degenerate primers that were based on short stretches of sequence identity between Drosophila Mad (7) and C. elegans Sma genes (11). A cDNA encoding the complete Smad2 protein was obtained from a human brain cDNA library. As reported previously by others (10, 13, 15, 22), the cDNA sequences predict that Smad1 and Smad2 are proteins of 465 and 467 amino acid residues, respectively.

The distribution of Smad1 and Smad2 in various human tissues was determined by Northern blot analysis of mRNA (Fig. 1). One Smad1 transcript of approximately 3.2 kb was detected in all tissues that were examined, except in peripheral blood leukocytes. When reprobing the Northern blots with a Smad2 probe, two major ubiquitously expressed transcripts of approximately 3.4 and 2.9 kb were detected.


Fig. 1. Smad1 and Smad2 are ubiquitously expressed. Northern blots with mRNA prepared from different tissues were hybridized with specific probes for Smad1 and Smad2. Lane 1, pancreas; lane 2, kidney; lane 3, skeletal muscle; lane 4, liver; lane 5, lung; lane 6, placenta; lane 7, brain; lane 8, heart; lane 9, spleen; lane 10, thymus; lane 11, prostate; lane 12, testis; lane 13, ovary; lane 14, small intestine; lane 15, colon; lane 16, peripheral blood leukocyte. Each lane contained 2 µg of mRNA from the indicated tissues. Smad1 and Smad2 transcripts are indicated by arrows. Autoradiographs from the hybridized blots are shown.
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Smad2 Encodes a 58-kDa Protein in Mv1Lu Cells

After transfection of Smad2-Flag/His in COS cells and metabolic labeling with [35S]methionine and [35S]cysteine, a cell extract was prepared and subjected to immunoprecipitation using Flag antiserum or a Smad2 antiserum, termed SED, which was raised against a peptide corresponding to amino acid residues 227-244 in the proline-rich region of Smad2. This region is divergent in sequence among the Smads. With both Flag and SED antisera a component of 62 kDa was specifically immunoprecipitated, which was not seen when preimmune serum was used or when excess cognate SED peptide was added together with the SED antiserum (Fig. 2A). Moreover, it was not detectable in samples derived from untransfected COS cells. When overexpressed in COS cells, Smad1 and DPC4 were not immunoprecipitated with SED antiserum (data not shown), indicating that SED antiserum does not cross-react with these proteins. The SED antiserum precipitated a 58-kDa component from Mv1Lu cells. This component was not observed when preimmune serum was used or when blocking peptide was added together with the SED antiserum. The observed mass of 58 kDa for Smad2 is somewhat higher than the predicted size of 52.5 kDa predicted from the cDNA sequence.


Fig. 2. Smad2 is a 58-kDa protein, which is specifically recognized by anti-Smad2 antiserum. A, COS cells transfected with expression plasmid containing Smad2-His/Flag were metabolically labeled and immunoprecipitated by SED or Flag antisera or preimmune serum. Blocking of the SED antiserum was performed by addition of 10 µg of peptide to the immunoprecipitate reaction. B, cell lysates from metabolically labeled Mv1Lu cells were subjected to precipitation using preimmune serum (pre), or SED antiserum. Blocking of the immune serum was performed with 10 µg of peptide. The migration of Smad2 is indicated by arrows. Precipitates were analyzed by SDS-PAGE and visualized using a Fuji-X Bio Imager (A) or autoradiography (B).
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Ligand-induced Phosphorylation of Smad2

The effect of TGF-beta on the phosphorylation of Smad2 was analyzed using [32P]orthophosphate-labeled Mv1Lu cells. Smad2 was not appreciably phosphorylated in the absence of ligand in Mv1Lu cells. The phosphorylation of Smad2 was strongly induced after stimulation with TGF-beta 1 (Fig. 3A). Significant phosphorylation was observed 15-30 min after addition of TGF-beta 1 and plateaued after about 2 h of incubation at 37 °C (Fig. 3B). Activin A stimulated no (or in some experiments weak) increase in Smad2 phosphorylation in Mv1Lu cells (Fig. 3A). BMP-2 and BMP-7 did not stimulate the phosphorylation of Smad2 in Mv1Lu cells (data not shown). Phosphoamino acid analysis of phosphorylated Smad2 after TGF-beta stimulation revealed that phosphorylation was mainly on serine, little on threonine, and not on tyrosine residue(s) (Fig. 3C).


Fig. 3. Ligand-induced phosphorylation of Smad2. A and B, Mv1Lu cells were labeled with [32P]orthophosphate and treated with 10 ng/ml TGF-beta 1 or 30 ng/ml activin. For kinetics of Smad2 phosphorylation Mv1Lu cells were stimulated with 10 ng/ml TGF-beta 1 for the indicated times. A representative experiment of three experiments is shown. Cell lysates were subjected to immune precipitation with SED antiserum and analyzed by SDS-PAGE. C, phosphorylated Smad2 was subjected to phosphoamino acid analysis. The migration of phosphorylated serine (S), threonine (T), and tyrosine (Y) that were used as standards are shown. D, COS cells transfected with Smad1-Flag, Smad2 alone, or the indicated type I and II receptors were labeled with [32P]orthophosphate, immunoprecipitated with anti-Flag antibodies or SED antiserum, and analyzed by SDS-PAGE. COS cells were treated with 10 ng/ml TGF-beta (T) or 100 ng/ml activin (A) where indicated. In parallel, we confirmed the expression of type I and II receptors and Smads by affinity labeling with iodinated ligands and immunoprecipitation of metabolically labeled cells, respectively (data not shown). Autoradiographs are shown.
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Phosphorylation of Smad2 was also investigated using [32P]orthophosphate-labeled COS cells, transfected with Smad2 alone or cotransfected with Tbeta R-II and Tbeta R-I, in the absence or presence of TGF-beta . Analysis of the Smad2 immunoprecipitates showed that Smad2 in the absence of overexpressed receptor and ligand was not (or weakly) phosphorylated. The observed increase in Smad2 phosphorylation after cotransfection with receptors is most likely due to ligand-independent complex formation of a Tbeta R-I and Tbeta R-II complex induced by their high overexpression. Further receptor activation by TGF-beta addition led to a strong increase in the Smad2 phosphorylation (Fig. 3D). The phosphoamino acid analysis pattern and two-dimensional tryptic phosphopeptide maps of phosphorylated Smad2 from transfected COS cells and Mv1Lu cells were nearly identical.2 In an analogous manner the effect of activation on Smad2 phosphorylation induced by activin was investigated using COS cells transfected with Smad2, ActR-II, and ActR-IB. We found that activin-mediated signaling induced Smad2 phosphorylation. In addition, we found that TGF-beta receptor activation induced the phosphorylation of Smad1 in COS cells, albeit weaker than BMP receptor activation (Fig. 3D).2 Taken together with our unpublished results, which indicate that TGF-beta does not induce Smad1 phosphorylation in Mv1Lu cells,3 these data suggest that overexpression of Smads and receptors in COS cells may lead to interactions that are not physiologically relevant.

Ligand-induced Nuclear Accumulation of Smad2

The subcellular organization of Smad2 in Mv1Lu cells in the absence or presence of ligand was analyzed by immunofluorescence using the SED antiserum. In the absence of ligand, Smad2-specific staining was predominant in the cytoplasm of the cells, whereas after stimulation with TGF-beta 1 for 1 h the staining was concentrated in the nucleus (Fig. 4). Thus, TGF-beta 1 induced a translocation of Smad2 from the cytoplasm to the nucleus.


Fig. 4. Nuclear accumulation of Smad2 is induced by TGF-beta . Mv1Lu cells were incubated in the absence or presence of 10 ng/ml TGF-beta 1 for 1 h. Smad2 was localized in the cells by immunofluorescence using SED antiserum. Staining was predominant in the cytoplasm in the absence of TGF-beta , whereas nuclear staining was observed with TGF-beta stimulation.
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Smad2 and DPC4 are Closely Linked on Chromosome 18q

The chromosomal localization of the Smad2 gene was initially determined by analysis of its segregation in mapping panel 2 (19). The Smad2-specific fragments segregated only with human chromosome 18. Smad2 was subsequently mapped to an interval between 18cen and 18q21.3 by analysis of a regional mapping panel for chromosome 18 (Fig. 5A). This localization places Smad2 in the same region of 18q as the related DPC4 gene (14). To test whether the two genes are closely linked, we analyzed two DPC4-containing YACs, Y747A6 and Y945B11, for the presence of Smad2 sequences by PCR. Both YACs were negative for Smad2, indicating that Smad2 is not located in the immediate vicinity of DPC4. In contrast, YAC Y793A3, which was recently shown to contain the Mad-related gene JV18-1 (15), was positive for Smad2 (data not shown). This YAC was mapped by FISH to 18q21.1 (Fig. 5B). All three YACs are known to map within the Whitehead-MIT YAC contig WC18.4. Based on the sequence tag site map of chromosome 18, Smad2 is located approximately 3 Mb proximal to DPC4 (23).


Fig. 5. Chromosomal location of Smad2 suggests a tumor suppressor gene function. A, ideogram showing the chromosome 18 content of the somatic cell hybrid panel used for mapping of Smad2. The breakpoints in hybrids GM12088 and GM12083 are only approximate (19). This panel allows assignment of genes to at least six different intervals on chromosome 18. Southern blot analysis showed that the presence of Smad2-specific sequences correlated with the presence of the region 18cen right-arrow q21.3. The presence (+) or absence (-) of Smad2 sequences in the hybrid lines are indicated. B, chromosomal sublocalization of Smad2 by FISH using YAC Y739A3 as probe. YAC DNA (green signal) was co-hybridized with a chromosome 18-specific alpha  satellite probe (red signal). Note the presence of Smad2-specific hybridization signals on both chromosomes 18 at q21.1. Chromosomes are counterstained in blue with 4,6-diamino-2-phenylindole.
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DISCUSSION

Recently, a conserved cytoplasmic family of Mad-like proteins, termed Smads, was identified and shown to play a pivotal role in the downstream signal transduction pathway of various TGF-beta superfamily members (24). In the present study we report the identification of a human Mad-related protein, Smad2, which acts in the TGF-beta signaling pathway.

Smad1 and Smad2 have 66% overall sequence identity, with the highest level of similarity in the MH1 and MH2 domains. The proline-rich intervening region is divergent, and a SED peptide derived from this region was successfully used to raise a specific antisera useful in the detection of Smad2 in nontransfected cells. Smad1 and Smad2 were found to be broadly expressed (Fig. 1), suggesting that they may be downstream of TGF-beta superfamily members with effects on many cell types.

TGF-beta specifically stimulated a phosphorylation of Smad2 in nontransfected Mv1Lu cells (Fig. 3). Consistent with the notion that type I receptors appear to act downstream of type II receptors (5), we found that Mv1Lu cells, lacking functional Tbeta R-I, do not phosphorylate Smad2 on TGF-beta challenge (data not shown). The kinetics of our TGF-beta -induced phosphorylation of Smad2 is slower than previously reported for BMP-2-induced phosphorylation of Smad1 (10). It needs to be investigated whether this is due to the use of transfected versus nontransfected cells. TGF-beta and activin induced Smad2 phosphorylation when overexpressed with appropriate type I and II receptors in COS cells. In addition, we observed that TGF-beta induced Smad1 phosphorylation, which is likely to have occurred due to the supraphysiological levels of Tbeta Rs and Smad1 in COS cells. Supportive of this notion, we found that TGF-beta did not induce the phosphorylation of Smad1 in Mv1Lu cells, whereas Smad1 could be immunoprecipitated from metabolically labeled cells using an antisera that recognizes Smad1, but not Smad2.3 Together these data indicate the physiological relevance of using nontransfected cells compared with transfected cells for the biochemical characterization of Smad activation.

Mv1Lu cells were shown to have TGF-beta , activin, and BMP receptors by ligand affinity cross-linking, followed by immunoprecipitation with receptor-specific antiserum, and to be responsive to all three ligand subgroups (16, 26). However, activin did not stimulate (or only weakly stimulated) Smad2 phosphorylation, and BMPs did not induce phosphorylation of Smad2 in Mv1Lu cells (Fig. 3B). In agreement with our results, Eppert et al. (22) recently demonstrated Smad2 regulation by TGF-beta and not BMP, whereas Smad1 has been implicated as a specific downstream target of BMP- but not TGF-beta -mediated signaling (10). Thus the specific signaling pathways autonomously induced by Smad1 (ventral mesoderm) and Smad2 (dorsal mesoderm) in Xenopus (12) resemble the ligand-specific activation of Smad1 and Smad2, as detected by biochemical means.

However, Lechleider et al. (27) and Yingling et al. (28) reported the phosphorylation of endogenous Smad1 (or immunologically related Smads) in response to TGF-beta . The latter result may suggest a functional redundancy of Smads in TGF-beta and BMP signal transduction. Differences may also prevail between different cell types. In addition, there may be a need for multiple Smads in TGF-beta signaling. It will be interesting, therefore, to test whether TGF-beta can induce an association between Smad2 and other Smads, e.g. Smad1 and DPC4. Involvement of multiple Mads in a TGF-beta -like signaling pathway was proposed for the C. elegans MAD homologs, as mutant phenotypes for sma-2, sma-3, and sma-4 all closely resemble the mutant phenotype of daf-4 (11).

TGF-beta stimulated the nuclear accumulation of Smad2 in Mv1Lu cells. Recently, Baker and Harland (29) reported the induction of nuclear localization of Smad2 by activin in Xenopus explants. In addition, they observed that the N-terminally truncated Smad2 is localized in the nucleus in the absence of ligand. It is unclear whether phosphorylation provides the trigger for nuclear accumulation, e.g. by unmasking a nuclear localization signal for active nuclear entry or by inducing the dissociation from a putative cytoplasmic retention protein.

Smad2 was localized to chromosome 18q21.1 by a combination of mapping techniques. Using YACs we could demonstrate that Smad2 and DPC4 are closely linked within a 3-Mb region, with Smad2 being proximal to DPC4. The 18q21 chromosomal region is frequently deleted or rearranged in a variety of human cancers. Recently, DPC4 was found to be frequently homozygously deleted or mutated in pancreatic cancers (14) but only rarely in other types of cancers with chromosome 18q alterations (25). The interesting possibility that Smad2 has a tumor suppressor function in these other cancers or in pancreatic cancer needs to be examined. In agreement with our results, Riggins et al. (15) and Eppert et al. (22) reported the chromosomal assignment of Smad2 to 18q21 by PCR analysis of YAC clones. In addition, both groups found that certain colorectal cancers contain somatic mutations in Smad2.

The elucidation of intracellular signal transduction pathways by which TGF-beta executes its multifunctional effects is of great importance for a better understanding of the (patho)physiological processes in which TGF-beta has been implicated and for future therapeutic interventions. In this respect the identification of Smad2 as an intracellular phosphorylation target in the TGF-beta signaling pathway is an important finding. The identification of the upstream Smad2 activating serine and threonine kinase and the downstream Smad2 nuclear effectors that result in the transcriptional modulation of Smad2 target genes will be the subject of future studies.


FOOTNOTES

*   This work was supported in part by the Swedish Cancer Society. 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.
§   To whom correspondence should be addressed. Tel.: 46-18-160400; Fax: 46-18-160420.
1    The abbreviations used are: TGF-beta , transforming growth factor beta ; ActR, activin receptor; BMP, bone morphogenetic protein; DPC4, deleted in pancreatic carcinoma, locus 4; EST, expression sequence tag; FISH, fluorescence in situ hybridization; Dpp, decapentaplegic; Mad, mothers against dpp; Smad, Sma- and Mad-related protein; MH, Mad homology; PAGE, polyacrylamide gel electrophoresis; RT, reverse transcription; PCR, polymerase chain reaction; Tbeta R, TGF-beta receptor; YAC, yeast artificial chromosome; kb, kilobase.
2    S. Souchelnytskyi, unpublished results.
3    A. Nakao, unpublished results.

Acknowledgments

We thank Kohei Miyazono, Johan de Winter, and our colleagues for stimulating discussions, Susanne Grimsby for excellent technical assistance, and Irie Nakao for encouragement. We also thank Ryutaro Yamada and Yoshio Misumi for the human brain cDNA library, M. Kawabata for pcDNA3-Flag, J. Wrana for Smad1-Flag in pCMV5, H. Ohashi for TGF-beta 1, Y. Eto for activin A, T. K. Sampath for BMP-2 and BMP-7, and J. Massagué for R mutant cells.


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