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Summary Expression Gene Literature (48) GO Terms (22) Nucleotides (196) Proteins (48) Interactants (714) Wiki
XB-GENEPAGE-1194371

Papers associated with foxh1

Search for foxh1 morpholinos using Textpresso

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8 paper(s) referencing morpholinos

Results 1 - 48 of 48 results

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Segregation of brain and organizer precursors is differentially regulated by Nodal signaling at blastula stage., Castro Colabianchi AM, Tavella MB, Boyadjián López LE, Rubinstein M, Franchini LF, López SL., Biol Open. February 25, 2021; 10 (2):                 


Generation of a FOXH1 homozygous knockout human embryonic stem cell line by CRISPR/Cas9 system., Zhang T, Huang W, Xue X., Stem Cell Res. December 10, 2020; 50 102121.  


Sox17 and β-catenin co-occupy Wnt-responsive enhancers to govern the endoderm gene regulatory network., Mukherjee S, Chaturvedi P, Rankin SA, Rankin SA, Fish MB, Wlizla M, Paraiso KD, MacDonald M, Chen X, Weirauch MT, Blitz IL, Cho KW, Zorn AM., Elife. January 1, 2020; 9                       


Transcriptome profiling reveals male- and female-specific gene expression pattern and novel gene candidates for the control of sex determination and gonad development in Xenopus laevis., Piprek RP, Damulewicz M, Tassan JP, Kloc M, Kubiak JZ., Dev Genes Evol. January 1, 2019; 229 (2-3): 53-72.        


Morpholinos Do Not Elicit an Innate Immune Response during Early Xenopus Embryogenesis., Paraiso KD, Blitz IL, Zhou JJ, Cho KWY., Dev Cell. January 1, 2019; 49 (4): 643-650.e3.        


Endodermal Maternal Transcription Factors Establish Super-Enhancers during Zygotic Genome Activation., Paraiso KD, Blitz IL, Coley M, Cheung J, Sudou N, Taira M, Cho KWY., Cell Rep. January 1, 2019; 27 (10): 2962-2977.e5.                          


Evolution of cis-regulatory modules for the head organizer gene goosecoid in chordates: comparisons between Branchiostoma and Xenopus., Yasuoka Y, Tando Y, Kubokawa K, Taira M., Zoological Lett. January 1, 2019; 5 27.                


Retinoic acid-induced expression of Hnf1b and Fzd4 is required for pancreas development in Xenopus laevis., Gere-Becker MB, Pommerenke C, Lingner T, Pieler T., Development. January 1, 2018; 145 (12):                                   


Conservatism and variability of gene expression profiles among homeologous transcription factors in Xenopus laevis., Watanabe M, Yasuoka Y, Mawaribuchi S, Kuretani A, Ito M, Kondo M, Ochi H, Ogino H, Fukui A, Taira M, Kinoshita T., Dev Biol. June 15, 2017; 426 (2): 301-324.                          


Eomesodermin-At Dawn of Cell Fate Decisions During Early Embryogenesis., Probst S, Arnold SJ., Curr Top Dev Biol. January 1, 2017; 122 93-115.


A gene regulatory program controlling early Xenopus mesendoderm formation: Network conservation and motifs., Charney RM, Paraiso KD, Blitz IL, Cho KWY., Semin Cell Dev Biol. January 1, 2017; 66 12-24.    


FoxH1 mediates a Grg4 and Smad2 dependent transcriptional switch in Nodal signaling during Xenopus mesoderm development., Reid CD, Steiner AB, Yaklichkin S, Lu Q, Wang S, Hennessy M, Kessler DS., Dev Biol. January 1, 2016; 414 (1): 34-44.                  


At new heights - endodermal lineages in development and disease., Ober EA, Grapin-Botton A., Development. June 1, 2015; 142 (11): 1912-1917.  


Predicting Variabilities in Cardiac Gene Expression with a Boolean Network Incorporating Uncertainty., Grieb M, Burkovski A, Sträng JE, Kraus JM, Groß A, Palm G, Kühl M, Kestler HA., PLoS One. January 1, 2015; 10 (7): e0131832.        


Genome-wide view of TGFβ/Foxh1 regulation of the early mesendoderm program., Chiu WT, Charney Le R, Blitz IL, Fish MB, Li Y, Biesinger J, Xie X, Cho KW., Development. December 1, 2014; 141 (23): 4537-47.                                  


Inference of the Xenopus tropicalis embryonic regulatory network and spatial gene expression patterns., Zheng Z, Christley S, Chiu WT, Blitz IL, Xie X, Cho KW, Nie Q., BMC Syst Biol. January 8, 2014; 8 3.                  


RAB8B is required for activity and caveolar endocytosis of LRP6., Demir K, Kirsch N, Beretta CA, Erdmann G, Ingelfinger D, Moro E, Argenton F, Carl M, Niehrs C, Boutros M., Cell Rep. September 26, 2013; 4 (6): 1224-34.                    


Klf4 is required for germ-layer differentiation and body axis patterning during Xenopus embryogenesis., Cao Q, Zhang X, Lu L, Yang L, Gao J, Gao Y, Ma H, Cao Y., Development. November 1, 2012; 139 (21): 3950-61.                  


Comparative gene expression analysis and fate mapping studies suggest an early segregation of cardiogenic lineages in Xenopus laevis., Gessert S, Kühl M., Dev Biol. October 15, 2009; 334 (2): 395-408.          


Oct25 represses transcription of nodal/activin target genes by interaction with signal transducers during Xenopus gastrulation., Cao Y, Siegel D, Oswald F, Knöchel W., J Biol Chem. December 5, 2008; 283 (49): 34168-77.                


Ectodermal factor restricts mesoderm differentiation by inhibiting p53., Sasai N, Yakura R, Kamiya D, Nakazawa Y, Sasai Y., Cell. May 30, 2008; 133 (5): 878-90.                        


Negative regulation of Activin/Nodal signaling by SRF during Xenopus gastrulation., Yun CH, Choi SC, Park E, Kim SJ, Chung AS, Lee HK, Lee HJ, Han JK., Development. February 1, 2007; 134 (4): 769-77.              


FoxD3 regulation of Nodal in the Spemann organizer is essential for Xenopus dorsal mesoderm development., Steiner AB, Engleka MJ, Lu Q, Piwarzyk EC, Yaklichkin S, Lefebvre JL, Walters JW, Pineda-Salgado L, Labosky PA, Kessler DS., Development. December 1, 2006; 133 (24): 4827-38.                    


XCR2, one of three Xenopus EGF-CFC genes, has a distinct role in the regulation of left-right patterning., Onuma Y, Yeo CY, Whitman M., Development. January 1, 2006; 133 (2): 237-50.                                      


Selective inhibition of TGF-beta responsive genes by Smad-interacting peptide aptamers from FoxH1, Lef1 and CBP., Cui Q, Lim SK, Zhao B, Hoffmann FM., Oncogene. June 2, 2005; 24 (24): 3864-74.


Identification of novel genes affecting mesoderm formation and morphogenesis through an enhanced large scale functional screen in Xenopus., Chen JA, Voigt J, Gilchrist M, Papalopulu N, Amaya E., Mech Dev. March 1, 2005; 122 (3): 307-31.                                                                                                                      


Of Fox and Frogs: Fox (fork head/winged helix) transcription factors in Xenopus development., Pohl BS, Knöchel W., Gene. January 3, 2005; 344 21-32.      


New roles for FoxH1 in patterning the early embryo., Kofron M, Puck H, Standley H, Wylie C, Old R, Whitman M, Heasman J., Development. October 1, 2004; 131 (20): 5065-78.              


Regulation of the Lim-1 gene is mediated through conserved FAST-1/FoxH1 sites in the first intron., Watanabe M, Rebbert ML, Andreazzoli M, Takahashi N, Toyama R, Zimmerman S, Whitman M, Dawid IB., Dev Dyn. December 1, 2002; 225 (4): 448-56.


Molecular regulation of vertebrate early endoderm development., Shivdasani RA., Dev Biol. September 15, 2002; 249 (2): 191-203.      


A novel Xenopus Smad-interacting forkhead transcription factor (XFast-3) cooperates with XFast-1 in regulating gastrulation movements., Howell M, Inman GJ, Hill CS., Development. June 1, 2002; 129 (12): 2823-34.    


The role of a Williams-Beuren syndrome-associated helix-loop-helix domain-containing transcription factor in activin/nodal signaling., Ring C, Ogata S, Meek L, Song J, Ohta T, Miyazono K, Cho KW., Genes Dev. April 1, 2002; 16 (7): 820-35.    


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, Silvestri C, Izzi L, Labbé E., Mol Cell Endocrinol. June 30, 2001; 180 (1-2): 3-11.


Mesendoderm induction and reversal of left-right pattern by mouse Gdf1, a Vg1-related gene., Wall NA, Craig EJ, Labosky PA, Kessler DS., Dev Biol. November 15, 2000; 227 (2): 495-509.              


Fast1 is required for the development of dorsal axial structures in zebrafish., Sirotkin HI, Gates MA, Kelly PD, Schier AF, Talbot WS., Curr Biol. September 7, 2000; 10 (17): 1051-4.


Homeodomain and winged-helix transcription factors recruit activated Smads to distinct promoter elements via a common Smad interaction motif., Germain S, Howell M, Esslemont GM, Hill CS., Genes Dev. February 15, 2000; 14 (4): 435-51.                


FAST-1 is a key maternal effector of mesoderm inducers in the early Xenopus embryo., Watanabe M, Whitman M., Development. December 1, 1999; 126 (24): 5621-34.


Characterization of zebrafish smad1, smad2 and smad5: the amino-terminus of smad1 and smad5 is required for specific function in the embryo., Müller F, Blader P, Rastegar S, Fischer N, Knöchel W, Strähle U., Mech Dev. October 1, 1999; 88 (1): 73-88.  


The role of FAST-1 and Smads in transcriptional regulation by activin during early Xenopus embryogenesis., Yeo CY, Chen X, Whitman M., J Biol Chem. September 10, 1999; 274 (37): 26584-90.


Dominant-negative Smad2 mutants inhibit activin/Vg1 signaling and disrupt axis formation in Xenopus., Hoodless PA, Tsukazaki T, Nishimatsu S, Attisano L, Wrana JL, Thomsen GH., Dev Biol. March 15, 1999; 207 (2): 364-79.


A molecular basis for Smad specificity., Lagna G, Hemmati-Brivanlou A., Dev Dyn. March 1, 1999; 214 (3): 269-77.


Alternatively spliced variant of Smad2 lacking exon 3. Comparison with wild-type Smad2 and Smad3., Yagi K, Goto D, Hamamoto T, Takenoshita S, Kato M, Miyazono K., J Biol Chem. January 8, 1999; 274 (2): 703-9.


A mouse homologue of FAST-1 transduces TGF beta superfamily signals and is expressed during early embryogenesis., Weisberg E, Winnier GE, Chen X, Farnsworth CL, Hogan BL, Whitman M., Mech Dev. December 1, 1998; 79 (1-2): 17-27.        


Determinants of specificity in TGF-beta signal transduction., Chen YG, Hata A, Lo RS, Wotton D, Shi Y, Pavletich N, Massagué J., Genes Dev. July 15, 1998; 12 (14): 2144-52.


Characterization of human FAST-1, a TGF beta and activin signal transducer., Zhou S, Zawel L, Lengauer C, Kinzler KW, Vogelstein B., Mol Cell. July 1, 1998; 2 (1): 121-7.


Smad4 and FAST-1 in the assembly of activin-responsive factor., Chen X, Weisberg E, Fridmacher V, Watanabe M, Naco G, Whitman M., Nature. September 4, 1997; 389 (6646): 85-9.


A transcriptional partner for MAD proteins in TGF-beta signalling., Chen X, Rubock MJ, Whitman M., Nature. October 24, 1996; 383 (6602): 691-6.

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