MEKK-1, a Component of the Stress (Stress-activated Protein Kinase/c-Jun N-terminal Kinase) Pathway, Can Selectively Activate Smad2-mediated Transcriptional Activation in Endothelial Cells*

Jonathan D. BrownDagger §, Maria R. DiChiara, Keith R. AndersonDagger , Michael A. Gimbrone Jr.Dagger , and James N. Topperparallel

From the Dagger  Vascular Research Division, Department of Pathology, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts 02115 and the  Cardiovascular Division, Department of Medicine, Stanford University School of Medicine, Stanford, California 94305-5406

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ABSTRACT
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EXPERIMENTAL PROCEDURES
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Smad proteins are essential components of the intracellular signaling pathways utilized by members of the transforming growth factor-beta (TGF-beta ) superfamily of growth factors. Certain Smad proteins (e.g. Smad1, -2, and -3) can act as regulated transcriptional activators, a process that involves phosphorylation of these proteins by activated TGF-beta superfamily receptors. We demonstrate that the intracellular kinase mitogen-activated protein kinase kinase kinase-1 (MEKK-1), an upstream activator of the stress-activated protein kinase/c-Jun N-terminal kinase pathway, can participate in Smad2-dependent transcriptional events in cultured endothelial cells. A constitutively active form of MEKK-1 but not mitogen-activated protein kinase kinase-1 (MEK-1) or TGF-beta -activated kinase-1, two distinct intracellular kinases, can specifically activate a Gal4-Smad2 fusion protein, and this effect correlates with an increase in the phosphorylation state of the Smad2 protein. These effects do not require the presence of the C-terminal SSXS motif of Smad2 that is the site of TGF-beta type 1 receptor-mediated phosphorylation. Activation of Smad2 by active MEKK-1 results in enhanced Smad2-Smad4 interactions, nuclear localization of Smad2 and Smad4, and the stimulation of Smad protein-transcriptional coactivator interactions in endothelial cells. Overexpression of Smad7 can inhibit the MEKK-1-mediated stimulation of Smad2 transcriptional activity. A physiological level of fluid shear stress, a known activator of endogenous MEKK-1 activity in endothelial cells, can stimulate Smad2-mediated transcriptional activity. These data demonstrate a novel mechanism for activation of Smad protein-mediated signaling in endothelial cells and suggest that Smad2 may act as an integrator of diverse stimuli in these cells.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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The transforming growth factor-beta (TGF-beta )1 superfamily of growth factors and cytokines is involved in a wide variety of physiological and pathophysiological processes in the cardiovascular system, and the signaling mechanisms utilized by this class of effectors are rapidly being elucidated. The discovery of Smad proteins and the demonstration that they can mediate many of the transcriptional effects of these growth factors has been an important advance (1-3). The central roles of these proteins in mediating TGF-beta responses in cells is highlighted by the demonstration that mutations in Smads 2, 3, and 4 have been causally linked to specific malignancies, and disruption of the Smad2 and Smad4 genes in mice results in early embryonic lethality (4, 5). As the detailed molecular mechanisms of Smad protein signaling have emerged a number of functional interactions between these proteins and other signaling pathways have been reported. For instance, recent work has demonstrated that the classic mitogen-activated protein kinase pathway (MAPK/ERK) can negatively regulate bone morphogenic protein/Smad1-dependent transcriptional responses. This appears to occur as a result of the phosphorylation of Smad1 by a member of the Erk kinases and subsequent translocation of Smad1 out of the nucleus (6). In contrast to this inhibitory effect, the stress-activated protein kinase pathway (i.e. the SAPK/JNK pathway) has been implicated as a positive regulator of certain Smad-dependent effects. Previous data from several groups have documented the importance of AP-1 and related transcriptional effectors in some TGF-beta -mediated transcriptional responses, and a recent report demonstrated a direct functional interaction between Smad3 and c-Fos/c-Jun in mediating TGF-beta -dependent transcription (7, 8).

Recently, signals derived from growth factor receptors containing tyrosine kinase activities were shown to be capable of modulating Smad-dependent effects. This was suggested to occur as a result of activation of a kinase downstream of MEK-1, an upstream activator of the classic MAPK/ERK kinase pathway, resulting in the phosphorylation of Smad2 (9). In addition, a variety of other kinases have been implicated in TGF-beta signaling, such as TAK-1 and TAB, although their precise roles have not been elucidated (10-12). Taken together, these data indicate that multiple signal transduction cascades may modulate Smad signaling in cells and begin to provide possible mechanisms by which signals derived from non-TGF-beta family members may impact TGF-beta superfamily responses. Furthermore, these data suggest that Smad proteins may be involved in the transduction of diverse signals in cells. In this report we demonstrate that MEKK-1, a MAPK kinase kinase that is an upstream activator of the SAPK/JNK pathway, is capable of selectively activating Smad2-dependent transcriptional activity independently of TGF-beta in cultured endothelial cells. These data demonstrate a functional interaction between the SAPK/JNK and Smad signaling pathways and suggest that Smad protein signaling may be modulated by MEKK-1 or related kinases in endothelial cells.

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Cells, Reagents, and Constructs-- Primary bovine aortic endothelial cells (BAEC) were isolated as described and cultured in Dulbecco's modified Eagle's media supplemented with 10% heat-inactivated bovine calf serum, 2 mM L-glutamine, 250 units/ml penicillin G, and 250 µg/ml streptomycin (13). These were utilized at passages 3-12. COS-7 cells were maintained in the same medium. The p3TP promoter, Smad protein expression constructs, Smad-GAL4/VP16 fusion constructs, and CBP fusion constructs have been described previously (14). The plasminogen activator inhibitor-1 promoter (P800) was provided by David Loskutoff, dominant negative MEKK-1 by Roger Davis, and activated TAK-1 expression plasmid by Eisuke Nishida. The active MEKK-1, MEK-1, and protein kinase A expression plasmids were obtained from Stratagene. The activated MEKK-1 construct consists of amino acids 380-672 of MEKK-1. The activated MEK-1 construct consists of the 2218/E222 derivative that has had amino acids 32-51 deleted. The c-Jun and Elk1 fusion proteins consist of amino acids 1-223 of c-Jun and 307-427 of Elk1 fused to the Gal4 DNA binding domain, respectively. The CRE, AP-1, and NF-kappa B-dependent promoters consist of four tandem CRE sites (AGCCTGACGTCAGAG), seven tandem AP-1 sites (TGACTAA), or four tandem NFKB sites (TGGGGACTTTCCGC) cloned upstream of a minimal TATA box and luciferase reporter gene. The Smad2 mutants pMSmad2*P and pMSmad2C*P have been described previously (14). For the labeling experiments, a Flag epitope replaced the Gal4 binding domain, and these were subcloned into the expression vector pCI (Promega).

Transfections, Reporter Assays, and Immunoprecipitations-- For transient transfections, cells were seeded at 50-70% confluence and transfected using LipofectAMINE (Life Technologies, Inc.) for 5 h. The cells were allowed to recover overnight in media containing 0.2% serum. Following approximately 18 h of incubation, luciferase and beta -galactosidase activity were measured (Tropix). All results are reported as luciferase activity (relative light unit) normalized to cotransfected beta -galactosidase activity (expressed from cotransfected, constitutive expression constructs, e.g. cytomegalovirus beta -galactosidase, phosphoglycerol kinase beta -galactosidase) and are representative of at least three independent experiments. A typical transfection utilized 0.25-0.5 µg of reporter gene plasmid and 5 ng of active kinase (e.g. MEKK-1 and MEK-1) expression plasmid. Total DNA and total amount of expression plasmid were equalized by the addition of appropriate control plasmids.

Antibodies directed against the epitopes used in the immunoprecipitations and Western blots were obtained from commercial suppliers (Boehringer Mannheim, Santa Cruz Biotechnology, Eastman Kodak Co.). The anti-CBP/P300, MEKK-1, and MEK-1 antisera were obtained from Santa Cruz Biotechnology. Cell lysates were made approximately 24 h after transfection in 1% Triton X-100, 150 mM NaCl, 50 mM Tris-HCl, pH 8.0, with protease inhibitors, and immunoprecipitations were performed overnight at 4 °C. Proteins were resolved on 10-12% SDS-polyacrylamide denaturing gels, transferred to nitrocellulose by electroblotting, and probed with appropriate antisera at 1/1000-1/2000 as indicated in the figures. Individual proteins were detected with a secondary antibody coupled to peroxidase and visualized with chemiluminescence (ECL).

Metabolic Labeling-- COS-7 cells were transfected as above, allowed to recover overnight, and subsequently incubated in low phosphate media containing [32P]orthophosphate (500 µCi/ml) for 3 h at 37 °C. For the TGF-beta stimulation, active TGF-beta at 5 ng/ml (R & D Systems) was added for the final 30 min. The cells were washed, lysed, and immunoprecipitated with anti-epitope antisera as above. Proteins were resolved on a 10% denaturing acrylamide gel and electroblotted to nitrocellulose, and autoradiography was performed. Western blots with anti-epitope antisera were performed to control for protein levels.

Immunofluorescence-- BAEC were transfected as above. The confluent monolayers were then washed and fixed in 2% paraformaldehyde for 10 min and permeabilized with 1% Nonidet P-40 for 1 min. After pre-blocking with nonspecific goat serum, the primary (anti-epitope) antibodies were applied at 1/500 for 1 h. The monolayers were then washed and incubated with appropriate secondary antibodies coupled to fluorescein isothiocyanate. The monolayers were visualized with a Nikon Microphot-FXA fluorescence microscope and imaged with a Power Macintosh-based image analysis system (Oncor).

Shear Stress Stimulation-- BAEC were exposed to a steady laminar shear stress stimulus utilizing a modified cone-plate flow system that has been described in detail previously and is a well validated method for exposing cultured cells to defined fluid mechanical stimuli (15, 16). For these experiments the BAEC were transfected as described above and subsequently plated to 12 individual "coverslips" (per experiment) that were simultaneously subjected to the LSS (flow) stimulus for 18 h. LSS at approximately 10 dynes/cm2 was achieved by utilizing a 0.5° cone rotating at a rate of 100 rpm. Identical coverslips maintained under standard (static) culture conditions served as controls. All flow experiments utilized the same culture medium as the static experiments.

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MEKK-1 Selectively Activates Smad-dependent Transcription-- To investigate the role of non-receptor kinases in the regulation of Smad signaling in endothelial cells, we examined the ability of constitutively activated forms of MEK-1, MEKK-1, and TAK-1 to regulate two TGF-beta responsive promoters, the plasminogen activator inhibitor-1 promoter (P800) and p3TP. MEK-1 is an activator of the classic MAPK/ERK pathway, and MEKK-1 is an activator of the stress or SAPK/JNK pathway (17, 18). TAK-1 is a kinase that has been implicated in TGF-beta signaling and is capable of activating components of the SAPK/JNK pathway, but its precise role is unknown (12). In preliminary titration experiments in cultured bovine aortic endothelial cells (BAEC), a ratio of active kinase to reporter gene plasmid of 1 to 100 was found to be sufficient to reproducibly activate transcription, and under these conditions only MEKK-1 was reproducibly capable of activating the TGF-beta -responsive promoters P800 and p3TP. Comparable levels of active MEK-1 or active or wild type TAK were unable to reproducibly activate these promoters, although active TAK-1 could stimulate the P800 promoter when expressed at very high levels (data not shown). Fig. 1 demonstrates the response of the p3TP and P800 promoters to coexpression of active MEKK-1, active MEK-1, or a constitutively active TGF-beta type-1 receptor (actTbeta R1). Both promoters are induced significantly by the active TGF-beta 1 receptor and active MEKK-1 but not by active MEK-1. When these kinases are expressed in combination with the activated TGF-beta receptor, MEKK-1 appears to stimulate the activity of both promoters in a manner additive to the TGF-beta receptor, whereas MEK-1 has little effect. To explore the mechanisms of these effects in more detail, the p3TP promoter was stimulated with either active Tbeta R1 or active MEKK-1, and the effects of coexpression of a dominant negative form of MEKK-1 or Smad7, an inhibitory Smad protein, was examined. As shown in Fig. 1C, the induction of p3TP by the active TGF-beta receptor was partially inhibited by the dominant negative MEKK-1 and was potently inhibited by coexpression of Smad7. Similarly, the induction of p3TP by active MEKK-1 was inhibited by coexpression of both dominant negative MEKK-1 and Smad7. Fig. 1E is a series of Western blots demonstrating the expression levels of the activated kinases utilized in these experiments. At the level of expression plasmids used (5 ng) we reproducibly observed a level of activated MEKK-1 or MEK-1 protein approximately 3-5 times that of the corresponding endogenous protein, and the relative levels of the two overexpressed active kinases (MEKK-1 and MEK-1) appeared comparable. Taken together, these results suggest that maximal transcriptional induction of the P800 and p3TP promoters by the active TGF-beta 1 receptor requires the action of MEKK-1 as well as Smad proteins. In addition, the observation that Smad7 can block active MEKK-1-mediated stimulation of these promoters suggests that Smad proteins are playing a role in the MEKK-1-mediated transcriptional stimulation.


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Fig. 1.   MEKK-1-mediated stimulation of TGF-beta -responsive promoters in cultured endothelial cells. A and B, bovine aortic endothelial cells (BAEC) were transfected with the plasminogen activator inhibitor-1 promoter (P800) or p3TP-lux promoter, together with the indicated combinations of activated receptor and or kinases, and reporter gene activity was assayed 18 h later. All results are expressed as luciferase activity normalized to cotransfected, constitutively expressed beta -galactosidase measured in the same sample. All transfection conditions were normalized to contain the same quantity of expression plasmid to control for nonspecific effects. C and D, the p3TP promoter was induced by active TGF-beta receptor or active MEKK-1, and the ability of increasing amounts (1:1, 1:2.5, 1:5) of dominant negative MEKK-1 (MEKKDN) or Smad7 expression to inhibit induction was assessed. Error bars represent ± 1 S.D. of the mean for independent replicates, and the experiments shown are representative of at least three independent experiments. E, Western blots demonstrating the relative levels of active MEKK-1, MEK-1, T bR1, and TAK-1 typically achieved in these transient transfection experiments. Lanes 1, 3, 5, and 7 are untransfected controls, and lanes 2, 4, 6, and 8 have been transfected with the active MEKK-1, MEK-1, Tbeta R1, or TAK-1 constructs, respectively. In lanes 1 and 2 the endogenous MEKK-1 is seen as is the truncated active kinase. The lower molecular weight band seen in lane 1 is a nonspecific band that does not compete off with MEKK-1 peptide (data not shown). In lanes 3 and 4 both the endogenous and active MEK-1 kinases are seen. In lanes 5-8, the active Tbeta R1 or active TAK-1 proteins are visualized by probing with the anti-hemagglutinin epitope antibody that does not detect the endogenous proteins. These blots all contain equivalent amounts of protein and were developed for comparable amounts of time.

To investigate this hypothesis directly, we utilized a Gal4-based transcriptional system. We have previously shown that this system faithfully recapitulates ligand (TGF-beta )-induced, Smad-dependent activation of transcription in cultured endothelial cells (14). Bovine aortic endothelial cells (BAEC) were cotransfected with constructs encoding fusion proteins between the Gal4 DNA binding domain and either full-length or C-terminal MH2 domains of Smad2, -4, -6, and -7 together with a Gal4-dependent luciferase reporter gene and constitutively activated forms of MEKK-1 or MEK-1. As shown in Fig. 2, MEKK-1 markedly stimulates Smad2-dependent transcription in this system. The low basal level of luciferase activity observed in the absence of MEKK-1 probably reflects a small amount of endogenous TGF-beta activation in the endothelial culture system. Smad4 demonstrates a reproducibly lower level of basal transcriptional activity in this system, and this is not enhanced in the presence of MEKK-1. Gal4 constructs containing only the C-terminal MH2 domain (along with the linker region) of these proteins (pM2C and pM4C) demonstrated significantly increased basal levels of transcriptional activity and were also markedly stimulated by MEKK-1. This observation is consistent with previous data demonstrating that the transcriptional activation domain is contained within the C-terminal half of the Smad protein (MH2 domain) and indicates that MEKK-1 can stimulate Smad2- and Smad4-dependent transcription in the absence of the inhibitory MH1 domain. In contrast to Smad2 and Smad4, neither Smad6 nor Smad7 demonstrated any significant basal or MEKK-1-induced transcriptional activity in endothelial cells. Moreover, overexpression of a constitutively activated form of MEK-1 does not stimulate the transcriptional activity of any Smad construct tested in this system (Fig. 2A). Fig. 2B demonstrates that the MEKK-1-mediated stimulation of GAL4-Smad2 (pM2)-mediated transcription is inhibited by coexpression of either the dominant negative MEKK-1 or Smad7. Taken together, these results indicate that MEKK-1 appears capable of selectively stimulating Smad2-dependent transcriptional activity in BAEC and that Smad7 can interfere with this process.


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Fig. 2.   MEKK-1 can stimulate Smad-dependent transcription in cultured endothelial cells. A, BAEC were transfected with various human Smad proteins fused to the Gal4 DNA binding domain (e.g. pM2, pM4, etc.) together with a Gal4-dependent promoter and the indicated active kinases. Gal4-Smad2-dependent transcription is markedly stimulated by coexpression of active MEKK-1, as is the activity of the C-terminal half of Smad2 fused to Gal4 BD (pM2C). B, Gal4-Smad2 (pM2) was stimulated with active MEKK-1, and the ability of increasing coexpression of a dominant negative form of MEKK-1 (MEKKDN) or Smad7 to inhibit this activation is assessed. All Gal4-Smad fusion proteins are expressed at comparable levels in this system as assessed by anti-Gal4 Western blot (data not shown).

MEKK-1 has been reported to modulate the activity of a number of signal transduction pathways in addition to the SAPK/JNK pathway such as NF-kappa B/Ikappa B and p53-mediated events (19-21). To examine the selectivity of our endothelial cell system, we performed a number of controls to assess the specificity of the observed MEKK-1-mediated stimulation. Conditioned media from endothelial cells expressing active MEKK-1 consistently failed to stimulate p3TP or GAL4-Smad2-mediated transcription, and inclusion of a neutralizing antibody to soluble TGF-beta in the media of the transfection studies (in quantities sufficient to inhibit the activity of exogenously added active TGF-beta 1 at 1.0 ng/ml) did not inhibit MEKK-1-mediated stimulation of Smad-dependent transcription (data not shown). These results indicate that MEKK-1 is not inducing the expression of TGF-beta which can then act in a paracrine manner.

To ensure that MEKK-1 activation of Smad2 and Smad4 was not the result of promiscuous signaling or indiscriminate stimulation of the general transcriptional apparatus in this overexpression system, we examined the response of a series of well characterized control promoters and transcriptional effectors. As shown in Fig. 3, both constitutively activated kinases (MEKK-1 and MEK-1) demonstrated a selective pattern of promoter activation when expressed at these levels in BAEC (see Fig. 1E). Active MEKK-1 potently stimulated a coexpressed AP-1-dependent promoter, whereas an NF-kappa B-dependent promoter was also stimulated but to much lesser degree. Active MEKK-1 was unable to significantly stimulate a CRE-dependent promoter, as compared with a constitutively activated form of protein kinase A, a known activator of CRE-dependent transcription (Fig. 3). Thus, expression of active MEKK-1 appears to be eliciting the expected pattern of promoter specificity in this endothelial cell context. To examine further the selectivity of transcription factor activation in our system, we examined the ability of active MEKK-1 and MEK-1 to stimulate the activity of fusion constructs between the Gal4 DNA binding domain and the activation domains of the transcription factors c-Jun, Elk-1, and VP-16 (pMJun, pMElk-1, and pMVP16, respectively). Active MEKK-1 markedly stimulated the transcriptional activity of pMJun but, at best, was only a modest activator of pMElk-1 in our system (Fig. 3). Conversely, active MEK-1 overexpression potently activated pMElk-1 but not pMJun, consistent with the role of MEK-1 as an activator of the classic MAPK (ERK) signal transduction pathway. Neither of these kinases had a significant effect on the high basal transcriptional activity of the GAL4-VP16 fusion protein. Taken together, these data demonstrate that when carefully expressed at relatively low levels in cultured endothelial cells, constitutively activated forms of both MEKK-1 and MEK-1 consistently demonstrate a pattern of promoter and transcription factor activation that is selective, and under these conditions, only MEKK-1 appears capable of significantly stimulating Smad2-dependent transcription.


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Fig. 3.   Overexpression of active MEKK-1 or MEK-1 results in a selective pattern of promoter and transcription factor activation in cultured endothelial cells. A, the indicated active kinases were cotransfected into BAEC with an AP-1, NF-kappa B, or CRE-dependent promoter, and the activation of transcription was assessed by reporter gene assay. MEKK-1 potently activates the AP-1-dependent promoter (approximately 10-fold) while activating the NF-kappa B-containing promoter to a lesser degree (2-3-fold). Active MEK-1 did not activate any of the promoters to a significant degree. B, the ability of active MEKK-1 and MEK-1 to activate c-Jun, ELK-1, or the VP16 activation domains was assessed in a Gal4-based assay. These proteins were fused to the Gal4 DNA binding domain and coexpressed with the kinase and a Gal4-dependent promoter. Active MEKK-1 potently activates c-Jun, and to a lesser degree ELK-1 under these conditions. Active MEK-1 can activate ELK1-mediated transcription. Neither kinase has a significant effect on VP16-mediated transcription under these conditions.

MEKK-1 Transcriptional Stimulation Correlates with a Change in the Phosphorylation State of Smad2-- Considerable experimental evidence supports a model of Smad signaling that involves phosphorylation of certain Smad proteins (e.g. Smad2) on a series of C-terminal serines (termed the SSXS motif) by the kinase present in TGF-beta family type 1 receptors (22, 23). To investigate the role of this C-terminal SSXS motif of Smad2 in the transcriptional response to active MEKK-1 described above, we generated two mutant Gal4-Smad2 fusion constructs (pM2*P and pM2C*P) that lack these serine residues. We have previously shown that the full-length Smad2 mutant (pM2*P) is unresponsive to TGF-beta in BAEC, whereas the truncated Smad2 mutant (pM2C*P) retains considerable transcriptional activation ability (14). When these constructs were cotransfected into BAEC together with a constitutively activated form of MEKK-1, the full-length mutant Smad2 was not stimulated (Fig. 4). In contrast, pM2C*P possessed a significant basal level of transcriptional activity that was markedly enhanced by MEKK-1 (Fig. 4). MEK-1 overexpression resulted in no significant stimulation of either Smad2 mutant (Fig. 4).


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Fig. 4.   Transcriptional activation of Smad2 by MEKK-1 correlates with a change in the phosphorylation state of Smad2 and does not require the C-terminal SSXS motif. A, Gal4 fusion proteins of Smad2 with the C-terminal SSXS motif deleted (pM2*P) or the MH2 domain of Smad2 with the SSXS deleted (pM2C*P) were examined for their transcriptional response to active MEK-1 or MEKK-1. The latter is significantly stimulated by active MEKK-1 expression. B, wild type Smad2 or mutant Smad2 lacking the SSXS motif (Smad2*P) tagged with a Flag epitope were expressed by transient transfection, and the cells were subsequently metabolically labeled with [32P]orthophosphate. Stimuli consisted of soluble TGF-beta (5 ng/ml) for 30 min or cotransfection of the indicated activated receptor or kinases. Smad2 phosphorylation was assessed by immunoprecipitation with anti-Flag antiserum and autoradiography. The No tx lane is a no transfection control; the control lane is no treatment. The bottom panels confirm comparable protein expression of Flag-Smad2. The bar graphs represent quantification of phosphorylation by densitometry of the autoradiograms and corresponding Western blots. These results are representative of two independent experiments.

To determine if MEKK-1 stimulation of Smad2 transcriptional activity also correlated with a change in its phosphorylation state, we performed a series of in vivo labeling experiments. Cells were transfected with epitope-tagged Smad2 expression constructs along with constitutively activated forms of the TGF-beta type I receptor (Tbeta RI), MEKK-1, or MEK-1 and metabolically labeled in the presence of [32P]orthophosphate. As shown in Fig. 4, Smad2 demonstrated a basal level of phosphorylation when overexpressed. In the presence of either soluble TGF-beta or active Tbeta RI, the phosphorylation state of Smad2 increases although the soluble TGF-beta ligand stimulus consistently results in a lower level of Smad2 phosphorylation in this system. This is in agreement with previous data describing the role of the TGF-beta type I receptor kinase in the phosphorylation of Smad2 (22). In the presence of MEKK-1, the phosphorylation state of Smad2 significantly increases as compared with either Tbeta RI or the untreated control, whereas active MEK-1 only modestly increased Smad2 phosphorylation.

To determine if the MEKK-1-mediated increase in the phosphorylation state of Smad2 occurs on the SSXS motif known to be the substrate for the TGF-beta type I receptor, we examined the phosphorylation of the Smad2 mutant in which the SSXS motif has been deleted (Smad2*P). As with wild type Smad2, when Smad2*P was overexpressed there is a low but detectable level of basal phosphorylation. In contrast to wild type Smad2, however, the phosphorylation state of Smad2*P was not significantly altered by either soluble TGF-beta or coexpression of the active Tbeta RI but is enhanced by coexpression of active MEKK-1. These results suggest that MEKK-1 activity can result in the phosphorylation of Smad2 (either by MEKK-1 itself or a yet to be defined kinase) and that this phosphorylation event can occur at a site or sites distinct from the C-terminal SSXS motif that is the site of type 1 receptor kinase-mediated phosphorylation. Given the ability of active MEKK-1 to stimulate the transcriptional activity of Gal4 Smad2C and Smad2C*P (Figs. 2A and 4A), the sites of MEKK-1-induced phosphorylation likely reside in the linker region or the C-terminal MH2 domain of Smad2. Although the SSXS motif appears to be dispensable for the MEKK-1-mediated stimulation of Smad2 demonstrated here, these data do not exclude some role for this site in the wild type Smad2 protein stimulated with active MEKK-1.

MEKK-1 Stimulates Smad-Smad Interactions, Nuclear Localization of Smad Proteins, and Interaction of Smad2 with a Required Transcriptional Coactivator-- Homo- and heterotypic interactions between Smad2 and Smad4 are thought to be critical for nuclear localization and subsequent stimulation of transcriptional events in response to TGF-beta (1-3). To determine if MEKK-1 can regulate Smad-Smad interactions, we employed mammalian two-hybrid and coimmunoprecipitation approaches. In the mammalian two-hybrid system, protein-protein interactions are detected by fusing one test protein to the Gal4 DNA binding domain, fusing a second test protein to the strong transcriptional activation domain of the VP16 protein, and coexpressing these with the GAL4-dependent reporter. An interaction between these two proteins results in activation of a Gal4-dependent luciferase reporter by the VP16 activation domain. By using Gal4 and VP16 fusion constructs of Smad2 and Smad4, we investigated the ability of MEKK-1 to regulate Smad-Smad interactions in endothelial cells. As shown in Fig. 5A, this system demonstrates some basal level of interaction between Smad2 and itself, as well as with Smad4, in the absence of any stimulation (see "control" condition in pM2 with VP-Smad2 or VP-Smad4 compared with pVP alone). This result likely reflects both an increased association between the Smad proteins due to overexpression and the presence of small amounts of TGF-beta in the culture system. However, the constitutively activated form of MEKK-1 markedly enhances both homotypic Smad2-Smad2 and heterotypic Smad2-Smad4 interactions. Interestingly, active MEKK-1 did not significantly stimulate Smad4-Smad4 interactions in this assay (data not shown). Expression of active MEK-1, which did not stimulate the transcriptional activity of Smad2 or Smad4, had no effect on Smad-Smad interactions in this endothelial two-hybrid system (Fig. 5A).


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Fig. 5.   Active MEKK-1 can stimulate homotypic Smad2-Smad2 and heterotypic Smad2-Smad4 interactions in BAEC. A, two-hybrid analysis of the ability of Gal4-Smad2 to interact with either Smad2 or Smad4 fused to the VP16 activation domain, respectively (VP-Smad2, VP-Smad4), when coexpressed in endothelial cells with the indicated active kinases. MEKK-1 can stimulate Smad2-Smad2 interactions and Smad2-Smad4 interactions in this system. (Note: these experiments are typically performed with 1/10th to 1/50th the amount of Gal4 fusion expression plasmid to minimize any background transcriptional activity of the Gal4 fusion proteins themselves.) B, both active TGF-beta receptor (actTbeta bR1) and active MEKK-1, but not active MEK-1, can stimulate Smad2 and Smad4 to interact as assessed by coimmunoprecipitation (IP) in BAEC. Smad4 tagged with a hemagglutinin epitope and Smad 2 tagged with a Flag epitope were coexpressed with the indicated kinases, and precipitations were performed with antibodies against the Flag epitope. Coprecipitating Smad4 was detected by Western blot with the anti-hemagglutinin antibody (upper panel). The lower two panels confirm comparable protein expression.

To demonstrate Smad-Smad interactions in cell extracts, we performed a series of coimmunoprecipitations. Epitope-tagged Smad2 and Smad4 were coexpressed with active Tbeta R1, MEK-1, TAK-1, or MEKK-1 in endothelial cells, and the interactions between Smad2 and Smad4 were assessed by immunoprecipitating Smad2 and probing the immunocomplexes for Smad4. As can been seen in Fig. 5, there is no detectable interaction between these two proteins in this assay in the absence of stimulation (control), but in the presence of a constitutively activated form of the TGF-beta type I receptor (Tbeta RI), significant amounts of Smad4 coimmunoprecipitate with Smad2. This is consistent with previous data demonstrating TGF-beta receptor-stimulated interaction between these two Smad proteins (22). As shown in Fig. 5, active MEKK-1 also stimulates this interaction between Smad2 and Smad4, whereas active MEK-1 or TAK did not stimulate any detectable Smad2-Smad4 association under these conditions. These data are consistent with the mammalian two-hybrid data presented above and demonstrate that MEKK-1 can selectively and specifically stimulate homotypic Smad2-Smad2 and heterotypic Smad2-Smad4 interactions in BAEC.

To determine if MEKK-1 enhancement of Smad2 and Smad4 interactions leads to changes in the subcellular localization of these proteins, we utilized immunofluorescence microscopy. Epitope-tagged Smad2 or Smad4 was transfected into BAEC and visualized by immunofluorescence. As can be seen in Fig. 6, both Smad2 and -4 demonstrate diffuse staining in unstimulated cells, a pattern consistent with a predominantly cytoplasmic localization of these proteins. When a constitutively activated form of MEKK-1 is cotransfected with either Smad2 or Smad4, both proteins exhibit predominant nuclear staining. Cotransfection of active MEK-1 did not significantly alter the pattern of Smad staining in these cells. To ensure that these effects were not simply the result of overexpression of Smad proteins, we expressed Smad7, a distinct Smad that is unresponsive to MEKK-1 transcriptional stimulation (Fig. 2). As shown in Fig. 6, Smad7 exhibits diffuse, predominantly cytoplasmic staining, which is unaltered in the presence of active MEKK-1.


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Fig. 6.   Coexpression of active MEKK-1 with Smad proteins in BAEC stimulates the nuclear localization of Smad2 and Smad4 but not Smad7. Immunofluorescence was performed on monolayers of BAEC cotransfected with combinations of Smad expression constructs (indicated on the left) and activated kinases (indicated at the top). The cells were fixed, permeabilized, stained with antibodies against the epitopes on the Smad proteins, and then visualized with secondary antibodies coupled to fluorescein isothiocyanate by fluorescence microscopy. Regions of the confluent monolayer containing representative stained cells are shown (adjacent cells are untransfected and thus appear unstained). Smad2 and Smad4, but not Smad7, demonstrated a predominant nuclear localization in active MEKK-1-expressing cells.

We and others(14, 24, 25) have recently shown that Smad2 and Smad4 are among the growing number of regulated transcriptional activators that interact with the mammalian transcriptional coactivator, CREB-binding protein (CBP). To determine if MEKK-1 could stimulate Smad2 and Smad4 interactions with CBP, we employed the mammalian two-hybrid system. As shown in Fig. 7, MEKK-1 selectively stimulates an interaction between Smad2 and the C-terminal 549 amino acids of CBP. This interaction was specific for Smad2 as MEKK-1 did not significantly stimulate interaction between Smad4 and any region of CBP in this two-hybrid system (data not shown). To confirm these results biochemically, we performed immunoprecipitations with an anti-CBP/P300 antisera on cell extracts derived from endothelial cells expressing tagged Smad constructs and active Tbeta R1, MEKK-1, TAK, or MEK-1. As shown in Fig. 7, in the presence of either active TBR1 or active MEKK-1, both Smad2 and Smad4 can be demonstrated to coimmunoprecipitate with CBP/P300.


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Fig. 7.   Active MEKK-1 stimulates the interaction between Smad2 and the transcriptional coactivator CBP in BAEC. A, two-hybrid analysis of Gal4-Smad2 (pM2) with the five domains of the coactivator CBP fused to VP16 in endothelial cells. Active MEKK-1 specifically stimulates the interaction of Smad2 with the carboxyl domain of CBP in endothelial cells. B, this interaction is confirmed by coimmunoprecipitation (IP) of Smad2 and Smad4 with CBP in the presence of active MEKK-1. Lysates from BAEC expressing Smads 2 and 4 and the indicated active kinases were immunoprecipitated with a pooled anti-CBP/P300 antisera, and coprecipitating Smads were detected by Western blotting. The lower band present in all lanes is the heavy chain of the anti-CBP/P300 antisera (IgH). The bottom panels confirm comparable expression of the Smad2 and -4 proteins in this experiment.

Laminar Shear Stress Can Stimulate Smad2-mediated Transcriptional Activity in Endothelial Cells-- To determine whether endogenous MEKK-1 expressed in endothelial cells is involved in the regulation of Smad2 activity, we examined the ability of steady laminar shear stress, a physiologically relevant fluid mechanical stimulus and a known modulator of endogenous MEKK-1 in endothelial cells (26, 27), to stimulate Smad-2 transcriptional activity. As shown in Fig. 8, 18 h of steady laminar shear stress (LSS) at a magnitude of 10 dynes/cm2 reproducibly stimulated the transcriptional activity of the Gal4-Smad2 construct, and this effect could be almost completely inhibited by coexpression of the dominant negative MEKK-1. LSS also stimulated the transcriptional activity of a Gal4-Jun construct consistent with previous work demonstrating the regulation of this transcription factor by shear stress in endothelial cells. These data indicate that the action of endogenous MEKK-1 is playing an important role in the activation of Smad2 by this biomechanical stimulus (LSS) in endothelial cells and suggest that Smad proteins may be capable of transducing diverse stimuli in these cells.


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Fig. 8.   LSS can stimulate Smad2 and c-Jun-mediated transcriptional activity in endothelial cells. The Gal4-Smad2 or Gal4-Jun constructs together with the Gal4 reporter were cotransfected into BAEC in the presence or absence of varying amounts of the dominant negative MEKK-1 as in Fig. 1. The cells were subsequently stimulated with 18 h of steady laminar shear stress at 10 dynes/cm2 in a well characterized in vitro flow system as described under "Experimental Procedures." The LSS stimulus reproducibly stimulated the transcriptional activity of both Gal4-Smad2 and Gal4-Jun, and this was significantly inhibited by coexpression of increasing amounts of the dominant negative MEKK-1.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The discovery of Smad proteins has been a major advance in our understanding of TGF-beta superfamily signaling. Recent data suggest that these proteins may interact with a variety of other signaling pathways in cells and thus may be involved in the transduction or modulation of other stimuli as well (6, 8, 9, 28). We have demonstrated that a constitutively active form of MEKK-1 can selectively activate Smad-dependent transcription in cultured endothelial cells in the absence of exogenous TGF-beta stimulation. MEKK-1 activation of Smad2-mediated transcription correlated with an increase in phosphorylation of Smad2 even in the absence of the C-terminal SSXS motif of Smad2 that is the site of TGF-beta type-1 receptor-induced phosphorylation, further supporting the fact that MEKK-1 induced activation of Smad2 can occur independently of TGF-beta . Activation of Smad2 by MEKK-1 resulted in an enhanced interaction with Smad4, nuclear localization of both Smad2 and Smad4, and a stimulation of Smad-transcriptional coactivator (CBP) interactions. These data thus describe a novel mechanism for the initiation of Smad protein signaling in endothelial cells.

The functional interactions between the classic mitogen (MAPK/ERK)- and stress (SAPK/JNK)-activated kinase pathways and Smad proteins are likely to be complex. Previous work has demonstrated that both pathways can be implicated in TGF-beta transcriptional responses (29-31). Atfi and colleagues (29, 30) reported that a dominant negative form of MEKK-1 could inhibit TGF-beta -mediated induction of the p3TP promoter in HepG2 cells, and this same group subsequently reported that dominant negative MEKK-1 could inhibit Smad3/4-mediated transcription. Recently Zhang and colleagues (8) demonstrated a direct interaction between Smad3/4 and c-Jun and c-Fos, two transcription factors that are among the targets of the MAPK/SAPK pathways. These data suggest that there are important stimulatory interactions between Smad proteins and the SAPK/JNK pathway in the context of TGF-beta signaling. Our results demonstrating that MEKK-1, a MAPKKK in this pathway, can specifically stimulate Smad2-mediated transcription suggest an additional stimulatory interaction between these pathways. Interestingly, both hepatocyte growth factor and epidermal growth factor that signal through receptor tyrosine kinases have also been reported to activate Smad2-mediated signaling independently of TGF-beta . This effect was demonstrated to be due to a phosphorylation event on Smad2 but did not appear to require the presence of Smad4 (9). Our findings are consistent with a model whereby Smad2 is the target of MEKK-1 or a downstream kinase, and this stimulates Smad2 to interact with Smad4, translocate to the nucleus, interact with the transcriptional coactivators CBP/P300, and activate transcription. In this regard the events downstream of Smad2 activation mediated by active MEKK-1 appear similar to those induced by TGF-beta stimulation. Thus, MEKK-1-mediated stimulation of Smad2 may be an additional or alternate mechanism of activation of Smad-mediated transcriptional events in endothelial cells.

The MEKK-1 mediated stimulation of Smad2-dependent transcription described here is likely due to the direct action of this or another downstream kinase on Smad2 rather that simply due to transcriptional synergy between AP-1 and Smad2 since we have demonstrated a change in the phosphorylation state of Smad2 in active MEKK-1 expressing cells. Furthermore, this correlates with the ability of MEKK-1 to stimulate the transcriptional activity of a mutant form of Smad2 that is not a substrate for TGF-beta type 1 receptor-mediated phosphorylation (Smad2C*P). In addition, expression of active TAK-1 under conditions where this kinase could activate transcription of GAL4-c-Jun fusion proteins or an AP-1 dependent promoter, did not reproducibly activate Smad2-mediated transcription (data not shown). Thus, activation of Smad2-mediated transcription and c-Jun/AP-1-mediated transcription can be dissociated in this endothelial system. Finally, active MEKK-1 selectively stimulated Smad2 interactions with itself and with Smad4 and CBP, but did not stimulate Smad4 homotypic interactions or Smad4-CBP interactions in the endothelial 2-hybrid system (Figs. 5 and 7, and data not shown). Taken together these data suggest that Smad2 is a primary target of this novel intracellular kinase-mediated regulation.

A potential limitation of these studies is the use of constitutively activated forms of signaling kinases that can be associated with nonspecific or promiscuous effects. However, the MEKK-1-mediated activation we observe is selective since active MEK-1, a distinct upstream kinase in the MAPK pathway, or active TAK-1, a kinase implicated in TGF-beta signaling, failed to demonstrate the ability to activate Smad2 when overexpressed at comparable levels as activated forms. TAK-1 was identified as a TGF-beta -activated kinase and has been reported to activate the TGF-beta responsive promoter plasminogen activator inhibitor-1 in mink lung epithelial cells (12). In endothelial cells in our hands this activation required very high levels of active TAK-1 expression, and under these conditions, we observed activation of a variety of other promoters such as the cytomegalovirus and SV-40 promoters. Interestingly, active TAK-1 was able to activate an AP-1-dependent promoter when expressed in endothelial cells (data not shown), consistent with previous data demonstrating the ability of this kinase to stimulate JNK activity (11). However, under these conditions we did not observe reproducible Smad protein activation. Similarly, active MEK-1 could activate ELK-1-dependent transcription but not Smad-dependent transcription in our system. Thus, although these results do not exclude roles for TAK-1 or MEK-1 in Smad-mediated signaling, we were unable to demonstrate selective stimulation of Smad-mediated signaling by these kinases in endothelial cells.

To address the question of whether endogenous MEKK-1 is involved in Smad protein-mediated signaling, we utilized a dominant negative form of the protein to inhibit the action of the endogenous kinase. As shown in Fig. 1, the dominant negative MEKK-1 can partially inhibit TGF-beta -mediated transcriptional induction suggesting that endogenous MEKK-1 is involved in this process. These data are consistent with previous data demonstrating the role of this kinase in TGF-beta signaling (30). To examine the ability of other activators of endogenous MEKK-1 to modulate Smad signaling in endothelial cells, we stimulated the cells with a physiologic fluid mechanical stimulus, steady laminar shear stress, at 10 dynes/cm2. This biomechanical stimulus has been demonstrated to elicit sustained activation of MEKK-1 in endothelial cells in vitro (26, 27). Under these conditions, we observed a reproducible stimulation of Smad2-mediated transcriptional activity that was inhibited by coexpression of the dominant negative MEKK-1. In contrast, when we examined the response to TNF-alpha , a distinct activator of MEKK-1, we failed to see any significant stimulation of Smad2-mediated transcription (data not shown). Taken together, these data suggest that endogenous MEKK-1 is playing a role in Smad2-mediated transcriptional activation in endothelial cells and that the context in which MEKK-1 is activated is likely to be an important determinant of its ability to modulate Smad protein signaling.

The ability of Smad7 to inhibit MEKK-1-mediated stimulation of Smad2-dependent transcriptional activation points to a novel role for this inhibitory Smad. We have previously demonstrated that Smad7 is induced by biomechanical forces such as steady laminar shear stress in endothelial cells and can bind to the activated type 1 TGF-beta receptor and inhibit its ability to phosphorylate Smad2 (13, 32). In the context of active MEKK-1 expressing endothelial cells, Smad7 may be utilizing an analogous mechanism to interact with intracellular kinases and block their ability to phosphorylate Smad2. Furthermore, flow-regulated Smad7 expression may be an important locus of cross-talk between biomechanical stimuli such as fluid shear stresses and cytokine/growth factor stimuli such as TGF-beta and related species in endothelial cells (33).

In summary, we have demonstrated that Smad2-mediated transcriptional activation can be initiated by coexpression of an active form of MEKK-1. These data together with previous data from other groups suggest that multiple mechanisms may exist to modulate Smad protein signaling in cells and that this important family of intracellular signaling molecules may be involved in more than just TGF-beta superfamily signaling. Given the many stimuli that have been demonstrated to activate the SAPK/JNK pathway and MEKK-1 (17, 26, 34), Smad proteins may be involved in modulating the cellular response to diverse signals ranging from humoral effectors such as growth factors, to biomechanical stimuli such as physical stresses. As such, this class of endothelial-expressed signaling proteins may participate importantly in the orchestration of complex biological processes such as atherogenesis, vascular remodeling, angiogenesis, and vascular development.

    ACKNOWLEDGEMENTS

We thank William Atkinson and Kay Case for invaluable technical assistance and Drs. Tucker Collins and Dean Falb for helpful discussions.

    FOOTNOTES

* This work was supported in part by National Institutes of Health Grants P50-HL56985 and R37-HL51150 and an Unrestricted Award for Cardiovascular Research from the Bristol-Myers Squibb Pharmaceutical Research Institute (to M. A. G.).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 a fellowship for medical students from The Stanley J. Sarnoff Endowment for Cardiovascular Science.

parallel Supported by a Howard Hughes Medical Institute Fellowship for Physicians. To whom correspondence should be addressed: Falk Cardiovascular Research Center, Stanford University School of Medicine, 300 Pasteur Dr., Stanford, CA 94305-5406. Tel.: 650-725-6850; Fax: 650-725-1599; E-mail: jtopper{at}leland.stanford.edu.

    ABBREVIATIONS

The abbreviations used are: TGF-beta , transforming growth factor-beta ; MAPK, mitogen-activated protein kinase; ERK, extracellular signal-related kinase; SAPK, stress-activated protein kinase; JNK c-Jun N-terminal kinase, AP-1, activating protein-1; TAK-1, TGF-beta -activated kinase-1; BAEC, bovine aortic endothelial cells; NF-kB, nuclear factor-kappa B; MEK-1, MAPK kinase-1; MEKK-1, MEK kinase-1; CBP, CREB-binding protein; CRE, cyclic AMP response element; LSS, laminar shear stress; Tbeta RI, TGF-beta type I receptor.

    REFERENCES
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ABSTRACT
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RESULTS
DISCUSSION
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