dSmurf Selectively Degrades Decapentaplegic-activated MAD, and Its Overexpression Disrupts Imaginal Disc Development*

Yao-Yun Liang {ddagger} §, Xia Lin {ddagger} §, Min Liang {ddagger} §, F. Charles Brunicardi {ddagger}, Peter ten Dijke ¶, Zhihong Chen §, Kwang-Wook Choi § || ** and Xin-Hua Feng {ddagger} § {ddagger}{ddagger}

From the {ddagger}Michael E. DeBakey Department of Surgery, §Department of Molecular & Cellular Biology, ||Ophthalmology, **Program of Developmental Biology, Baylor College of Medicine, Houston, Texas 77030 and the Division of Cellular Biochemistry, The Netherlands Cancer Institute, 1066 Cx Amsterdam, the Netherlands

Received for publication, January 21, 2003 , and in revised form, May 12, 2003.


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
MAD plays an important role in decapentaplegic (DPP) signaling throughout Drosophila development. Despite a recent study describing the restriction of DPP signaling via putative ubiquitin E3 ligase dSmurf (1), the molecular mechanisms of how dSmurf affects DPP signaling remain unexplored. Toward this goal we demonstrated the degradation of phosphorylated MAD by dSmurf. dSmurf selectively interacted with MAD, but not Medea and Dad, and the MAD-dSmurf interaction was induced by constitutively active DPP type I receptor thickveins. Wild type dSmurf, but not its C1029A mutant, mediated ubiquitination-dependent degradation of MAD. Silencing of dSmurf using RNA interference stabilized MAD protein in Drosophila S2 cells. Targeted expression of dSmurf in various tissues abolished phosphorylated MAD and disrupted patterning and growth. In contrast, similar overexpression of inactive dSmurf(C1029A) showed no significant effects on development. We conclude that dSmurf specifically targets phosphorylated MAD to proteasome-dependent degradation and regulates DPP signaling during development.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Decapentaplegic (DPP)1 is the Drosophila ortholog of human bone morphogenetic protein (BMP) 2/4, which belongs to the transforming growth factor {beta} (TGF-{beta}) superfamily (24). DPP plays a central role in Drosophila morphogenesis. DPP signals through cell surface receptors and intracellular Smad proteins. In Drosophila, all three classes of Smads, R-Smad (MAD, dSmad2), Co-Smad (Medea), and I-Smad (Dad), have been characterized (2). MAD, the founding member of Smad family (5), transduces the signal of DPP, while dSmad2 mediates TGF-{beta}/Activin signaling (2).

Ubiquitin conjugation is catalyzed by an enzymatic cascade including ubiquitin-activating E1, ubiquitin-conjugating E2, and specific ubiquitin E3 ligase. The specificity of ubiquitination derives from the highly specific protein-protein interaction between E3 ligase and substrate (6, 7). In TGF-{beta} signaling, HECT-class E3 ligases Smurf1 and Smurf2 specifically promote degradation of Smad1, Smad2 (810) and possibly I-Smads and TGF-{beta} type I receptor (11, 12). In Xenopus embryos, Smurf1 showed inhibition of BMP signaling and affected pattern formation (8). Recently, a Drosophila ligase E3 dSmurf has been identified by genetic screen (1); the null mutation of dSmurf resulted in a lethal defect in hindgut organogenesis. However, the mechanisms underlying dSmurf actions in DPP signaling and embryogenesis remain unclear.

In this study, we present biochemical and genetic evidence for the biological functions of dSmurf. The results revealed that dSmurf specifically inhibited DPP signaling by targeting DPP-activated MAD, not dSmad2, Medea, or Dad, for ubiquitination/proteasome-dependent proteolysis. Targeted overexpression of dSmurf in imaginal discs strongly reduces the level of phosphorylated MAD and consequently causes disruption of DPP-dependent patterning of imaginal discs, demonstrating that dSmurf is a negative regulator of DPP signaling in vivo.


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Molecular Cloning—dSmurf were obtained by using PCR with primers (forward: gGAATTC aat aaa ttg gat tac cca cgt and reverse: ttcGTC-GAC tta ctc cac ggc aaa tcc aca) from total fly cDNA (Clontech) or Lack cDNA clone (gift of Scott Hawley), and cloned into the EcoRI and SalI of pXF1F or pXF1M, for making FLAG-tagged or Myc-tagged dSmurf, respectively. His-tagged MAD is made by subcloning into a mammalian expression vector pXF2RH (9). The point mutation of dSmurf of C1029A substitution was generated from two-step PCR. MAD(2SA) mutant was made by mutating the two Ser into Ala in the SVS phosphorylation motif.

Yeast Two-hybrid Assay—A LexA-based yeast two-hybrid assay was performed as described previously (9). MAD, dSmad2, and Dad were obtained by PCR from respective cDNA (gifts of Kohei Miyazono and Richard Padgett) and cloned into a yeast bait vector pEG202. dSmurf wild type and the dSmurf deletion mutants, obtained by PCR, were cloned into prey vector pJG4–5 at sites of EcoRI and SalI. Smurf1 (gift of Jeff Wrana) was also subcloned into pJG4–5. {beta}-Galactosidase activity is measured by liquid assay according to the method of Matchmaker two-hybrid system 2 (Clontech).

Immunoprecipitation and Western Blot—Culture and transfection of human kidney 293T cells and Drosophila Schneider S2 cells, and coupled immunoprecipitation-Western blot assays were carried out as described previously (13, 14).

For degradation assay, copper-inducible pMK33 expression plasmids for MAD, dSmurf, and the constitutively active type I receptor Thickveins (caTKV) (gifts of Richard Padgett) were transfected into Schneider S2 cells by calcium phosphate. In the case of RNA interference experiment (Fig. 4D), cells were cotransfected with synthetic 21-nucleotide duplex RNA (double-stranded RNA) of dSmurf (15). Cells were induced by 0.5 mM CuSO4 for 24 h and then harvested for Western blot analysis.



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FIG. 4.
dSmurf degrades MAD proteins in cells. A, dSmurf induces proteasome-dependent degradation of MAD. Drosophila S2 cells were transfected with indicated MAD, with or without Myc-tagged dSmurf and treated with MG132 as indicated. Cell lysates were subjected to SDS-PAGE and Western blotting analysis using anti-MAD and anti-Myc antibodies. Note that caTKV further promoted dSmurf-induced MAD degradation (lane 4). B, MAD degradation requires the HECT catalytic activity of dSmurf. 293T cells were transfected with expression plasmids for FLAG-tagged MAD and increasing doses of Myc-dSmurf (wild type or C1029A mutant). Cell lysates from transfected cells were subjected to anti-FLAG Western blot to detect MAD and anti-Myc immunostaining to detect dSmurf. C, depletion of dSmurf expression stabilizes MAD. Drosophila S2 cells were transfected with Myc-tagged dSmurf and MAD and treated with increasing doses (20, 40, and 100 nM) of siRNA against dSmurf as indicated. Cell lysates were subjected to SDS-PAGE and Western blotting analysis using anti-MAD and anti-Myc antibodies. D, depletion of dSmurf expression stabilizes pMAD. Drosophila S2 cells were transfected with caTKV and treated with 100 nM si-dSmurf. Level of phospho-MAD was analyzed by Western blotting using anti-P-Smad1 antibody.

 

For ubiquitination assay, 293T cells were cotransfected by His-tagged MAD, HA-tagged ubiquitin, and c-Myc-tagged dSmurf. Proteasome inhibitor MG-132 was added to the transfected cells to prevent degradation of MAD. 48 h after transfection, cell lysates were subjected to precipitation using nickel-NTA-agarose beads and to detect ubiquitinated MAD as described previously (9).

Targeted Expression and Immunocytochemistry—cDNAs for dSmurf and dSmurf(C1029A) were cloned in pUAST-FLAG, a modified pUAST containing a FLAG tag sequence to induce FLAG-tagged proteins.2 Transgenic flies carrying UAS-dSmurf and UAS-dSmurf (C1029A) were generated by P-element-mediated germline transformation (16). For targeted expression, UAS-dSmurf flies were crossed to Gal4 strains. For immunocytochemistry, imaginal discs from the progeny Gal4>UAS larvae were double stained with mouse anti-Flag (1:250) and rabbit anti-pMAD (1:250) with fluorescein isothiocyanate- and Cy3-conjugated fluorescent secondary antibodies as described previously (17).


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
WW2/WW3 Domains of dSmurf Meditates Its Specific Interaction with MAD—By homology probing, we identified dSmurf cDNA that encodes a polypeptide of 1061 amino acid. dSmurf belongs to the HECT-class ubiquitin E3 ligase family (Fig. 1A) and displays a close homology to human Smurf2 (911) and Smurf1 (8). During the course of this study, Podos et al. (1) also identified dSmurf in a genetic screen (1). As a first step to determine whether dSmurf modulates DPP signaling in Drosophila, we investigated the physical interaction of this putative ubiquitin E3 ligase with members of the Smad family in Drosophila. We found that dSmurf only interacted with MAD, but not with dSmad2, Medea, or Dad. (Fig. 1B). Therefore, unlike its mammalian homologs Smurf1/2 that bind to both R-Smads and I-Smads, dSmurf specifically interacts with DPP-specific MAD.



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FIG. 1.
dSmurf specifically interacts with MAD via the WW2/WW3 domains. A, schematic diagram of dSmurf constructs and summary of dSmurf-MAD interaction. C2 domain, three WW domains, and HECT domain are shown. Interaction of these dSmurf variants with MAD in C are summarized. B, Specific interaction of dSmurf and MAD in yeast two-hybrid assay. Yeast EGY48 cells transformed with indicated bait plasmid (pEG202-Smad), the prey plasmid pJG4–5/Smurf, and a {beta}-galactosidase reporter plasmid were grown in liquid culture. {beta}-Galactosidase assay was done as described under "Experimental Procedures." Interaction was scored with yeast culture in medium containing glucose (basal level) or galactose/raffinose (inducible level). C, mapping of MAD-interacting domain. Yeast two-hybrid assays were used to map the domains of dSmurf responsible for MAD-dSmurf interactions. Result is also shown in A.

 

To locate the interacting domains of dSmurf, we generated deletion and point mutations in dSmurf and assessed their interaction of MAD. The result showed that the entire WW2/WW3 region of dSmurf (amino acids 513–602) was required for the interaction with MAD, whereas the WW2 or WW3 domain alone did not interact with MAD (Fig. 1C). Notably, the same WW2/WW3 region with point mutations in WW2 domain (W541F/P544A) completely lost the interaction with MAD. These data suggest that the interaction of dSmurf binds to MAD through the WW2/WW3 domain.

DPP Receptor Activation Augments dSmurf-MAD Interaction—We next assessed the MAD-dSmurf interaction in vivo. To prevent MAD degradation, we used the C1029A mutant of dSmurf to determine its interaction with Smads. The C1029A mutant carries a cysteine-to-alanine substitution at amino acid residue 1029 that is essential for catalysis. As shown in Fig. 2A, dSmurf coimmunoprecipitated with MAD, but not with dSmad2, Medea, and Dad, in agreement with the interaction pattern from yeast two-hybrid analysis. caTKV, constitutively active form of type I receptor Thick-veins (18, 19), enhanced the interaction between MAD and dSmurf (Fig. 2, A and B).



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FIG. 2.
DPP stimulates dSmurf-MAD interaction. A, dSmurf binds to MAD in cells. 293T cells were transfected with plasmids for FLAG-tagged Smad (MAD, dSmad2, Medea, or Dad) and Myc-tagged dSmurf(C1029A). dSmurf complex was immunoprecipitated using anti-Myc antibody, followed by a Western blot to detect dSmurf-associated MAD. Expression levels of dSmurf and Smads in whole cell lysates were shown as indicated. Asterisk indicates a nonspecific band close to the molecular mass of Medea. Note that dSmurf-MAD interaction is stronger in the presence of constitutively active TKV (compared lane 7 with lane 2). B, mutation in the C-terminal phosphorylation sites of MAD abolishes dSmurf-MAD interaction. 293T cells were transfected with indicated plasmids. Immunoprecipitation-Western blotting was similarly carried out to A, except that anti-MAD (Smad1, Santa Cruz Biotechnology) antibody was used for immunoprecipitation and anti-FLAG (dSmurf) for Western blotting to detect MAD-bound dSmurf. MAD(SA) contains point mutations at Ser-453 and Ser-455 into Ala. Expression levels of dSmurf and MAD in whole cell lysates were shown as indicated. Level of pMAD in the immunoprecipitate was also shown. C, endogenous MAD binds to dSmurf. GST-dSmurf-(513–612) was used to pull down endogenous MAD from S2 cell lysates, transfected with caTKV and/or treated with proteasome inhibitor MG-132 (as indicated). dSmurf-bound MAD was detected by anti-Smad1 (upper panels) or anti-phospho-Smad1 (lower panels) antibodies. NS, a nonspecific band. D, dSmurf interacts with activated dSmad2. 293T cells were transfected with indicated plasmids, and immunoprecipitation-Western blotting was similarly carried out as described in the legend to A. caActRIB, constitutively active ActRIB.

 

To examine the importance of the phosphorylation motif SSXS, we generated double mutations in MAD at Ser-433 and Ser-435, which were changed into Ala and presumably unphosphorylatable by TKV. Result in Fig. 2B clearly showed that the interaction between this mutant, named MAD(SA), and dSmurf was not detectable regardless of the presence of caTKV, whereas wild type MAD strongly interacted with dSmurf in the presence of caTKV. Furthermore, dSmurf also had stronger binding to endogenous phospho-MAD, which can be further enhanced by proteasome inhibitor MG-132 (Fig. 2C). Interestingly, dSmurf also interacts with dSmad2 in the presence of caActR1B (Fig. 2D), suggesting that dSmad2 phosphorylation is necessary for its binding to dSmurf (despite the absence of such interaction in yeast two-hybrid assay as shown in Fig. 1). Therefore, data presented in Fig. 2 clearly demonstrate the important involvement of SSXS phosphorylation in Smad interaction with dSmurf.

dSmurf Mediates Ubiquitination of MAD—To dissect the function of dSmurf as a ubiquitin E3 ligase, we tested whether dSmurf stimulated the ubiquitination of MAD. As shown in Fig. 3, wild type dSmurf was capable of enhancing ubiquitination of MAD protein (lane 3), while no ubiquitination was observed with MAD alone (lane 1). Markedly, the C1029A mutant of dSmurf could not conjugate HA-ubiquitin to MAD (lane 4). This suggests that the catalytic activity of dSmurf is required for the ubiquitination of MAD.



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FIG. 3.
dSmurf ubiquitinates MAD. 293T cells were transfected with expression plasmids for His-tagged MAD, HA-tagged ubiquitin, and Myc-dSmurf. His-MAD was pulled down from cell lysates using nickel-NTA-agarose beads (Ni-NTA ppt) and then subjected to SDS-PAGE and Western blotting analysis using anti-HA antibodies to detect the pool of ubiquitinated MAD (upper). Levels of MAD in cells were detected using anti-His antibody (bottom). dSmurf(CA) is the catalytically inactive mutant of dSmurf with C1029A point mutation. Ubiquitinated MAD is marked.

 

dSmurf Promotes Proteolytic Degradation of MAD—Having established that dSmurf mediated MAD ubiquitination, we next examined the MAD degradation in Drosophila S2 and human 293T cells. In S2 cells, the MAD protein level was reduced dramatically by overexpressed dSmurf (Fig. 4A). Similarly, dSmurf degraded MAD in 293T cells in a dose-dependent manner (Fig. 4B). In sharp contrast, the C1029A mutant did not decrease the steady state level of MAD (Fig. 4B).

We next examined the role of phosphorylation of MAD in dSmurf-mediated degradation. It was clear that activated type I receptor further enhanced the degradation of MAD protein in dSmurf-overexpressing cells (Fig. 4A, compare lane 4 with lane 3), consistent with increased phosphorylation level (data not shown). Most notably, addition of proteasome inhibitor MG-132 inhibited MAD degradation caused by dSmurf (Fig. 4A, lane 5).

We then took a loss-of-function approach to examine the MAD degradation by depleting the dSmurf expression. S2 cells were transfected with MAD and Myc-dSmurf and treated with or without a 21-nucleotide double-stranded RNA that targets dSmurf (si-dSmurf). We could detect more MAD protein with increased concentration (20, 40, and 100 nM) of the siRNA (Fig. 4C). Simultaneously, reduced dSmurf protein level was detected by anti-Myc antibody (lower panel, Fig. 4C). Importantly, an increased endogenous phospho-MAD protein level was detected after 100 nM si-dSmurf treatment (Fig. 4D), suggesting the silencing of endogenous dSmurf by si-dSmurf.

Overexpression of dSmurf Leads to Loss of Phospho-MAD and Disruption of Imaginal Disc Development—DPP signaling is essential for patterning of imaginal discs. DPP is expressed along the anterior-posterior border of the wing disc and activated phospho-MAD is expressed in wider area around the AP border. Using UAS-Gal4 targeted expression system (20), we tested whether overexpression of dSmurf along the AP border can reduce or abolish phospho-MAD. As expected, when dSmurf expression was targeted to the AP border using ptc-Gal4, there was a strong reduction of phospho-MAD level in the ptc expression domain (Fig. 5). ptc-Gal4;UAS-dSmurf (ptc>dSmurf) flies failed to eclose due to severe developmental defects. Pharate adult flies removed from the pupal case showed rudimentary wings (Fig. 5L) and truncated legs (not shown), indicating strong reduction of DPP signaling. In contrast, overexpression of catalytically inactive dSmurf in ptc>dSmurf(C1029A) showed no significant defects in appendages. Wing discs from ptc>dSmurf(C1029A) showed slight increases in the level of phospho-MAD (Fig. 5, E–G), suggesting that dSmurfCA may titrate the function of normal dSmurf.



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FIG. 5.
dSmurf degrades MAD in vivo and disrupts wing disc development. Wing discs from wild-type (A–D), ptc>dSmurf(C1029A) (E–H), and ptc>dSmurf (I–L) were stained with anti-{beta}-galactosidase (red) and anti-pMAD (green). A, pMAD is distributed in the medial wing pouch region of the normal disc. Its level is lower in the Ptc domain at the anterior-posterior (AP) border (arrowhead). B and C, schematic of Ptc (red) and pMAD (green) domains in the wing disc. A and P indicate anterior and posterior, respectively. D, wild type adult wing. E–G, overexpression of dSmurf(C1029A) using ptc-Gal4 causes no decrease in pMAD level. Instead, pMAD level is slightly increased in the Ptc domain (arrow, compare the Ptc domains in A and E). H, wings from ptc> dSmurf(C1029A) adult flies are almost normal. I–K, overexpression of dSmurf using ptc-Gal4 results in strong reduction of pMAD along the anterior-posterior border. L, adults with ptc>dSmurf show only rudimentary wings.

 


    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
In this study, we have elucidated the mechanism underlying dSmurf-MAD interaction and characterized the biological function of dSmurf in Drosophila. dSmurf preferentially interacts with phosphorylated MAD (pMAD). The preferential binding of dSmurf to pMAD is similar to a previously reported Smurf2 binding to phosphorylated Smad2 (9). Furthermore, for the first time we demonstrate that mutation in the SSXS motif of MAD abolished its binding to dSmurf, highlighting the important role of MAD phosphorylation in its degradation. This phosphorylation-dependent MAD-dSmurf interaction is contrary to a previously proposed model that Smurfs target non-phosphorylated Smad1/MAD for degradation and thus reduces the cell competence to BMP/DPP signals (1, 8). The phosphorylation-dependent mechanism, as also discussed (21), is consistent to the disappearance of pMAD in dSmurf-overexpressing transgenic flies (Fig. 5) and also agrees with the increased pMAD level in dSmurf-null mutants (1). While at present it is not clear how the phosphorylation controls the dSmurf-mediated MAD degradation, three possible mechanisms can be envisioned. First, phosphorylation of the SSXS motif disrupts the intrinsic MH1-MH2 interaction and results in an exposed PPXY motif in the linker region for dSmurf binding. Second, dSmurf interaction with MAD depends on the nuclear entry of MAD, which is induced by ligand. The third possibility is that the phosphorylated SSXS motif may be directly involved in MAD binding to dSmurf. Besides PPXY motif, phosphoserine (Ser(P)) residues also serves as ligand for WW domain (22). It will be interesting to determine whether one of WW domains of dSmurf can directly bind to the phosphorylated SSXS motif of MAD.

dSmurf also interacts with dSmad2 dependent of receptor activation. The binding specificity of dSmurf is similar to that of its structurally related Smurf2 which binds both BMP- and activin-activated R-Smads in vertebrates (9, 10). One remaining question is whether dSmurf also targets dSmad2 for degradation. Since activin signaling through dSmad2 appears to have no effects on patterning of wing development (23), the hypothetical dSmurf-mediated dSmad2 degradation in the wing imaginal disc should have no contributions to the severe phenotype observed in the dSmurf transgenic flies. It is the disappearance of phophos-MAD that completely shuts down DPP signaling during wing development.

Unlike its vertebrate homologs, dSmurf fails to interact with DAD, the inhibitory Smad in fly. In vertebrates, Smurf1 and Smurf2 can form a strong association with Smad6 and Smad7 (12), which may promote the degradation of TGF-{beta} receptors (11, 12). While the physiological role of mammalian Smurf in controlling receptor homeostasis remains to be clarified, dSmurf has no apparent functions in the proteolytic degradation of DPP receptors.


    FOOTNOTES
 
* This work was supported by American Cancer Society Grants RSG-02-145-01-CCG (to X. L.) and RPG-00-214-01-CCG (to X.-H. F.), Dutch Cancer Society Grant NKI 2000-2217 (to P. t. D.), and National Institutes of Health Grants R01 CA95731 (to F. C. B.), R01 EY11110 (to K.-W. C.), and R01 GM63773 (to X.-H. F.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

{ddagger}{ddagger} To whom correspondence should be addressed: Dept. of Molecular & Cellular Biology, Baylor College of Medicine, One Baylor Plaza, Rm. 137D, Houston, TX 77030. E-mail: xfeng{at}bcm.tmc.edu.

1 The abbreviations used are: DPP, decapentaplegic; BMP, bone morphogenetic protein; TGF{beta}, transforming growth factor {beta}; E1, ubiquitin-activating enzyme; E2, ubiquitin-conjugating enzyme; E3, ubiquitin-protein ligase; HA, hemagglutinin; NTA, nitrilotriacetic acid; sidSmurf, 21-nucleotide double-stranded RNA that targets dSmurf; pMAD, phosphorylated MAD. Back

2 S. Izaddoost and K.-W. Choi, unpublished data. Back


    ACKNOWLEDGMENTS
 
We thank Rik Derynck for critical reading of the manuscript, Kohei Miyazono, Richard Padgett, Scott Hawley, and Jeff Wrana for reagents, and Jianluo Jia for technical assistance.



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 ABSTRACT
 INTRODUCTION
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 RESULTS
 DISCUSSION
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