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	Figure 1. Smurf1 and Smad6 synergistically inhibit endogenous BMP signaling in Xenopus embryos. (A) Smad6 (500 pg) and Smurf1 (500 pg) RNAs were injected near the ventral midline of four-cell embryos. Resultant phenotypes are shown (top, secondary axis; middle panel, hyperdorsalized embryo). When 1000 pg of β-globin RNA was injected, embryos developed normally (bottom). (B) RNAs encoding β-globin (1000 pg), Smurf1 (1000 pg), Smad6 (1000 pg), or Smurf1 (250 pg) and Smad6 (250 pg) were injected near the animal pole of two-cell embryos. Animal caps were isolated from embryos at blastula stage 8 and cultured to stage 23. RNAs were extracted from pooled caps and control embryos and subjected to RT-PCR analysis. WE, whole embryo.
	Figure 2. Smurf1 cooperates with Smad6 in cultured cells. (A) Effects of Smurf1 on the transcriptional activity of c.a.ALK6 in the presence of Smad5(WT) or Smad5(ΔPY) were examined using 3GC2-Lux assay. R mutant Mv1Lu cells were cotransfected with 3GC2-lux luciferase construct and various combinations of c.a.ALK6, Smad5(WT), Smad5(ΔPY), Smad7, and Smurf1 cDNAs. + and ++ are 0.1 and 0.3 μg of DNA, respectively, transfected in R mutant cells. (B) Binding of Smurf1(CA) to Smad5(WT) and Smad5(ΔPY) was examined in transfected COS7 cells. A Smurf1 mutant Smurf1(CA), which has a mutation in the HECT domain and fails to recruit ubiquitin ligase activity, was used for binding assays, including this experiment. COS7 cells were transfected with the indicated plasmids and subjected to FLAG-immunoprecipitation (IP) followed by Myc-immunoblotting (Blot). The top panel shows the interaction and the lower three panels the expression of each protein.
	Figure 3. Smurf1 interacts with BMP type I receptors via I-Smads. Binding of Smurf1 to different type I receptors for BMPs in the presence of Smad6 (A) or Smad7 (B) was examined. COS7 cells were transfected with FLAG-tagged constitutively active forms of type I receptors for the TGF-β superfamily proteins (c.a.ALK2-FLAG, c.a.ALK3-FLAG, and c.a.ALK6-FLAG for BMPs; and c.a.ALK5-FLAG and c.a.ALK4-FLAG for TGF-β and activin) and 6Myc-tagged Smurf1(CA) in the presence or absence of 6Myc-tagged Smad6 (A) or 6Myc-tagged Smad7 (B). Cell lysates were subjected to FLAG-immunoprecipitation (IP) followed by Myc-immunoblotting (Blot). The top panels show the interaction and the lower two panels the expression of each protein.
	Figure 4. Smurf1–I-Smad complexes target ALK6 for ubiquitin-dependent degradation. (A) Smad6 enhances ubiquitination and degradation of ALK6 by Smurf1. Ubiquitination of c.a.ALK6 by Smad6–Smurf1 complexes was examined. 293T cells were transfected with the indicated plasmids and treated with 2.5 μM of lactacystin for 24 h before cell lysis. Lysates from cells were subjected to anti-FLAG immunoprecipitation followed by anti-HA immunoblotting. Polyubiquitination species of constitutively active forms of ALK6 ([FLAG-Ub]n-c.a.ALK6-HA) are indicated in the top panel. (B and C) Smurf1–Smad7 complex induced rapid turnover of ALK6. COS7 cells were transfected with c.a.ALK6-FLAG, FLAG-Smurf1, and/or Myc-Smad7. [35S]methionine- and cysteine-labeled cell lysates were immunoprecipitated by FLAG antibody. Immune complexes were subjected to SDS-PAGE and examined using a Fuji BAS 2500 bio-imaging analyzer. Arrowheads indicate the premature form of ALK6.
	Figure 5. Smad6 recruits BMP-specific R-Smads to Smurf1 and enhances their ubiquitination and degradation. (A) Association of Smad6 with Smad1 is enhanced by treatment with proteasomal inhibitor lactacystin. COS7 cells were transfected with the indicated plasmids and treated with 2.5 μM lactacystin for 24 h before cell lysis. Lysates from cells were subjected to FLAG-immunoprecipitation (IP) followed by Myc-immunoblotting (Blot). (B) Interaction of Smurf1 with Smad5 is enhanced in the presence of Smad6. COS7 cells were transfected with the indicated plasmids, and lysates from cells were subjected to FLAG-IP followed by Blot.
	Figure 6. Smad6/7 enhances ubiquitination and degradation of Smad1/5 by Smurf1. Ubiquitination of Smad1 (A and B) or Smad5 (C) by Smurf1 was examined. 293T cells were transfected with the indicated plasmids and treated with 2.5 μM lactacystin for 24 h before cell lysis. Lysates from cells were subjected to anti-FLAG immunoprecipitation followed by anti-HA immunoblotting (A) or anti-HA immunoprecipitation followed by anti-Myc immunoblotting (B and C). Polyubiquitinated species of Smads, [HA-Ub]n-FLAG-Smad1 (A), [HA-Ub]n-6Myc-Smad1 (B), and [HA-Ub]n-6Myc-Smad5 (C), are indicated in the top panels. Levels of expression of Smad1 or 5, Smad6/7, and Smurf1 were confirmed by immunoblotting and are shown in the bottom two panels.
	Figure 7. Inhibition of BMP signaling by Smurf1 through multiple mechanisms. In the absence of BMP signaling, Smurf1 interacts with BMP-specific R-Smads and induces their degradation to maintain low basal levels of them. In the presence of BMP signaling, Smurf1 targets activated type I receptors and BMP-specific R-Smads for ubiquitin-dependent degradation. I-Smads, induced by BMPs, act as adaptors in this process.

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