Modulation of noncanonical TGF-β signaling prevents cleft palate in Tgfbr2 mutant mice
Jun-ichi Iwata, … , Mark Urata, Yang Chai
Jun-ichi Iwata, … , Mark Urata, Yang Chai
Published February 13, 2012
Citation Information: J Clin Invest. 2012;122(3):873-885. https://doi.org/10.1172/JCI61498.
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Modulation of noncanonical TGF-β signaling prevents cleft palate in Tgfbr2 mutant mice

Abstract

Patients with mutations in either TGF-β receptor type I (TGFBR1) or TGF-β receptor type II (TGFBR2), such as those with Loeys-Dietz syndrome, have craniofacial defects and signs of elevated TGF-β signaling. Similarly, mutations in TGF-β receptor gene family members cause craniofacial deformities, such as cleft palate, in mice. However, it is unknown whether TGF-β ligands are able to elicit signals in Tgfbr2 mutant mice. Here, we show that loss of Tgfbr2 in mouse cranial neural crest cells results in elevated expression of TGF-β2 and TGF-β receptor type III (TβRIII); activation of a TβRI/TβRIII-mediated, SMAD-independent, TRAF6/TAK1/p38 signaling pathway; and defective cell proliferation in the palatal mesenchyme. Strikingly, Tgfb2, Tgfbr1 (also known as Alk5), or Tak1 haploinsufficiency disrupted TβRI/TβRIII-mediated signaling and rescued craniofacial deformities in Tgfbr2 mutant mice, indicating that activation of this noncanonical TGF-β signaling pathway was responsible for craniofacial malformations in Tgfbr2 mutant mice. Thus, modulation of TGF-β signaling may be beneficial for the prevention of congenital craniofacial birth defects.

Authors

Jun-ichi Iwata, Joseph G. Hacia, Akiko Suzuki, Pedro A. Sanchez-Lara, Mark Urata, Yang Chai

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Figure 4

TβRII is crucial in regulating TAK1/p38 MAPK activity.

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TβRII is crucial in regulating TAK1/p38 MAPK activity. (A) Immunoblottin...
(A) Immunoblotting analysis of indicated molecules in primary MEPM cells from Tgfbr2fl/fl control mice treated with control or Tgfbr2 siRNA and cultured with (+; w/) or without (–; w/o) TGF-β2 (10 ng/ml) for 30 minutes. The bar graphs show the ratios of phosphorylated TAK1 relative to TAK1 and phosphorylated p38 relative to p38 after quantitative densitometry analysis of immunoblotting data. Three samples were analyzed for each experiment. Error bars represent SD. *P < 0.05; ***P < 0.001. (B) Immunoblotting analysis with indicated antibodies of untreated Tgfbr2fl/fl;Wnt1-Cre MEPM cells (Untreat) or empty vector treated Tgfbr2fl/fl;Wnt1-Cre MEPM cells (Mock) or cells after reintroduction of Tgfbr2 (Tgfbr2 vector). (C) Immunoblotting analysis with anti-K63 ubiquitin (K63 Ub) antibody after immunoprecipitation by anti-TRAF6 or anti-TAK1 antibody of extracts from MEPM cells from Tgfbr2fl/fl (F/F) and Tgfbr2fl/fl;Wnt1-Cre (F/F;Wnt1) mice. (D) Schematic diagram depicts our model of the mechanism of p38 MAPK activation in the Tgfbr2fl/fl;Wnt1-Cre palate, leading to craniofacial malformations. TGF-β2 is upregulated and binds to TβRIII (RIII), followed by assembly with TβRI (RI) and β-spectrin. TRAF6 activates TAK1 ubiquitination (Ub) and phosphorylation (P) after TGF-β2 binding. Finally, p38 and 14-3-3 proteins are phosphorylated, leading to downstream signaling and cell proliferation defect. RII, TβRII.