Papers associated with anatomical group (and tgfb1)

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	Time-resolved quantitative proteomic analysis of the developing Xenopus otic vesicle reveals putative congenital hearing loss candidates., Baxi AB., iScience. September 15, 2023; 26 (9): 107665.
	HMCES modulates the transcriptional regulation of nodal/activin and BMP signaling in mESCs., Liang T., Cell Rep. July 12, 2022; 40 (2): 111038.
	Acute multidrug delivery via a wearable bioreactor facilitates long-term limb regeneration and functional recovery in adult Xenopus laevis., Murugan NJ., Sci Adv. January 28, 2022; 8 (4): eabj2164.
	Secreted inhibitors drive the loss of regeneration competence in Xenopus limbs., Aztekin C., Development. June 1, 2021; 148 (11):
	More Than Just a Bandage: Closing the Gap Between Injury and Appendage Regeneration., Kakebeen AD., Front Physiol. January 1, 2019; 10 81.
	microRNAs associated with early neural crest development in Xenopus laevis., Ward NJ., BMC Genomics. January 18, 2018; 19 (1): 59.
	Early development of the neural plate: new roles for apoptosis and for one of its main effectors caspase-3., Juraver-Geslin HA., Genesis. February 1, 2015; 53 (2): 203-24.
	MiR-142-3p controls the specification of definitive hemangioblasts during ontogeny., Nimmo R., Dev Cell. August 12, 2013; 26 (3): 237-49.
	The developing Xenopus limb as a model for studies on the balance between inflammation and regeneration., King MW, King MW., Anat Rec (Hoboken). October 1, 2012; 295 (10): 1552-61.
	Identification and developmental expression of Xenopus laevis SUMO proteases., Wang Y., PLoS One. December 11, 2009; 4 (12): e8462.
	Tumor necrosis factor-receptor-associated factor-4 is a positive regulator of transforming growth factor-beta signaling that affects neural crest formation., Kalkan T., Mol Biol Cell. July 1, 2009; 20 (14): 3436-50.
	Identification of a novel negative regulator of activin/nodal signaling in mesendodermal formation of Xenopus embryos., Cheong SM., J Biol Chem. June 19, 2009; 284 (25): 17052-60.
	FAM/USP9x, a deubiquitinating enzyme essential for TGFbeta signaling, controls Smad4 monoubiquitination., Dupont S., Cell. January 9, 2009; 136 (1): 123-35.
	The pro-domain of the zebrafish Nodal-related protein Cyclops regulates its signaling activities., Tian J., Development. August 1, 2008; 135 (15): 2649-58.
	TGF-beta signaling is required for multiple processes during Xenopus tail regeneration., Ho DM., Dev Biol. March 1, 2008; 315 (1): 203-16.
	The evolutionally conserved activity of Dapper2 in antagonizing TGF-beta signaling., Su Y., FASEB J. March 1, 2007; 21 (3): 682-90.
	Kinesin-mediated transport of Smad2 is required for signaling in response to TGF-beta ligands., Batut J., Dev Cell. February 1, 2007; 12 (2): 261-74.
	The MH1 domain of Smad3 interacts with Pax6 and represses autoregulation of the Pax6 P1 promoter., Grocott T., Nucleic Acids Res. January 1, 2007; 35 (3): 890-901.
	Smurf1 regulates neural patterning and folding in Xenopus embryos by antagonizing the BMP/Smad1 pathway., Alexandrova EM., Dev Biol. November 15, 2006; 299 (2): 398-410.
	Unique players in the BMP pathway: small C-terminal domain phosphatases dephosphorylate Smad1 to attenuate BMP signaling., Knockaert M., Proc Natl Acad Sci U S A. August 8, 2006; 103 (32): 11940-5.
	Inhibitor-resistant type I receptors reveal specific requirements for TGF-beta signaling in vivo., Ho DM., Dev Biol. July 15, 2006; 295 (2): 730-42.
	deltaEF1 and SIP1 are differentially expressed and have overlapping activities during Xenopus embryogenesis., van Grunsven LA., Dev Dyn. June 1, 2006; 235 (6): 1491-500.
	XCR2, one of three Xenopus EGF-CFC genes, has a distinct role in the regulation of left-right patterning., Onuma Y., Development. January 1, 2006; 133 (2): 237-50.
	TGF-beta signaling potentiates differentiation of embryonic stem cells to Pdx-1 expressing endodermal cells., Shiraki N., Genes Cells. June 1, 2005; 10 (6): 503-16.
	Germ-layer specification and control of cell growth by Ectodermin, a Smad4 ubiquitin ligase., Dupont S., Cell. April 8, 2005; 121 (1): 87-99.
	DRAGON, a bone morphogenetic protein co-receptor., Samad TA., J Biol Chem. April 8, 2005; 280 (14): 14122-9.
	Molecular and cellular insights into the coxsackie-adenovirus receptor: role in cellular interactions in the stem cell niche., Hauwel M., Brain Res Rev. April 1, 2005; 48 (2): 265-72.
	GATA4, 5 and 6 mediate TGFbeta maintenance of endodermal gene expression in Xenopus embryos., Afouda BA., Development. February 1, 2005; 132 (4): 763-74.
	Developmental analysis of activin-like kinase receptor-4 (ALK4) expression in Xenopus laevis., Chen Y, Chen Y., Dev Dyn. February 1, 2005; 232 (2): 393-8.
	ALK4 functions as a receptor for multiple TGF beta-related ligands to regulate left-right axis determination and mesoderm induction in Xenopus., Chen Y., Dev Biol. April 15, 2004; 268 (2): 280-94.
	Effects of TGF-beta on hyaluronan anabolism in fibroblasts derived from the synovial membrane of the rabbit temporomandibular joint., Tanimoto K., J Dent Res. January 1, 2004; 83 (1): 40-4.
	Gene profiling during neural induction in Xenopus laevis: regulation of BMP signaling by post-transcriptional mechanisms and TAB3, a novel TAK1-binding protein., Muñoz-Sanjuán I., Development. December 1, 2002; 129 (23): 5529-40.
	The role of TGF beta signaling in the formation of the dorsal nervous system is conserved between Drosophila and chordates., Rusten TE., Development. August 1, 2002; 129 (15): 3575-84.
	Nuclear exclusion of Smad2 is a mechanism leading to loss of competence., Grimm OH., Nat Cell Biol. July 1, 2002; 4 (7): 519-22.
	Smad10 is required for formation of the frog nervous system., LeSueur JA., Dev Cell. June 1, 2002; 2 (6): 771-83.
	Meeting report: signaling schemes for TGF-beta., Roberts AB., Sci STKE. December 18, 2001; 2001 (113): pe43.
	TGF-beta signalling pathways in early Xenopus development., Hill CS., Curr Opin Genet Dev. October 1, 2001; 11 (5): 533-40.
	The transcriptional role of Smads and FAST (FoxH1) in TGFbeta and activin signalling., Attisano L., Mol Cell Endocrinol. June 30, 2001; 180 (1-2): 3-11.
	Origins of inner ear sensory organs revealed by fate map and time-lapse analyses., Kil SH., Dev Biol. May 15, 2001; 233 (2): 365-79.
	Visualization of endogenous BMP signaling during Xenopus development., Kurata T., Differentiation. February 1, 2001; 67 (1-2): 33-40.
	Association of Smads with lymphoid enhancer binding factor 1/T cell-specific factor mediates cooperative signaling by the transforming growth factor-beta and wnt pathways., Labbé E., Proc Natl Acad Sci U S A. July 18, 2000; 97 (15): 8358-63.
	Regulation of gut and heart left-right asymmetry by context-dependent interactions between xenopus lefty and BMP4 signaling., Branford WW., Dev Biol. July 15, 2000; 223 (2): 291-306.
	Transforming growth factor-beta5 expression during early development of Xenopus laevis., Kondaiah P., Mech Dev. July 1, 2000; 95 (1-2): 207-9.
	The lefty-related factor Xatv acts as a feedback inhibitor of nodal signaling in mesoderm induction and L-R axis development in xenopus., Cheng AM., Development. March 1, 2000; 127 (5): 1049-61.
	TGF-beta signaling by Smad proteins., Miyazono K., Adv Immunol. January 1, 2000; 75 115-57.
	A two-step model for the fate determination of presumptive endodermal blastomeres in Xenopus embryos., Yasuo H., Curr Biol. August 26, 1999; 9 (16): 869-79.
	Sequence and expression of myoglianin, a novel Drosophila gene of the TGF-beta superfamily., Lo PC., Mech Dev. August 1, 1999; 86 (1-2): 171-5.
	The role of transcription factors involved in TGFbeta superfamily signaling during development., Watanabe M., Cell Mol Biol (Noisy-le-grand). July 1, 1999; 45 (5): 537-43.
	Identification of two Smad4 proteins in Xenopus. Their common and distinct properties., Masuyama N., J Biol Chem. April 23, 1999; 274 (17): 12163-70.
	Dominant-negative Smad2 mutants inhibit activin/Vg1 signaling and disrupt axis formation in Xenopus., Hoodless PA., Dev Biol. March 15, 1999; 207 (2): 364-79.

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