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Summary Anatomy Item Literature (37) Expression Attributions Wiki
XB-ANAT-732

Papers associated with gut epithelium

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Amphibian (Xenopus laevis) Tadpoles and Adult Frogs Differ in Their Antiviral Responses to Intestinal Frog Virus 3 Infections., Hauser KA., Front Immunol. January 1, 2021; 12 737403.                

Iron nanoparticle bio-interactions evaluated in Xenopus laevis embryos, a model for studying the safety of ingested nanoparticles., Bonfanti P., Nanotoxicology. March 1, 2020; 14 (2): 196-213.                        

Expression of hyaluronan synthases upregulated by thyroid hormone is involved in intestinal stem cell development during Xenopus laevis metamorphosis., Fujimoto K., Dev Genes Evol. December 1, 2018; 228 (6): 267-273.

Heparanase 2, mutated in urofacial syndrome, mediates peripheral neural development in Xenopus., Roberts NA., Hum Mol Genet. August 15, 2014; 23 (16): 4302-14.                              

Jun N-terminal kinase maintains tissue integrity during cell rearrangement in the gut., Dush MK., Development. April 1, 2013; 140 (7): 1457-66.                      

Thyroid hormone regulation of adult intestinal stem cell development: mechanisms and evolutionary conservations., Sun G., Int J Biol Sci. January 1, 2012; 8 (8): 1217-24.      

Amphibian organ remodeling during metamorphosis: insight into thyroid hormone-induced apoptosis., Ishizuya-Oka A., Dev Growth Differ. February 1, 2011; 53 (2): 202-12.

Direct activation of Shroom3 transcription by Pitx proteins drives epithelial morphogenesis in the developing gut., Chung MI., Development. April 1, 2010; 137 (8): 1339-49.              

Origin of the adult intestinal stem cells induced by thyroid hormone in Xenopus laevis., Ishizuya-Oka A., FASEB J. August 1, 2009; 23 (8): 2568-75.

Sfrp5 coordinates foregut specification and morphogenesis by antagonizing both canonical and noncanonical Wnt11 signaling., Li Y., Genes Dev. November 1, 2008; 22 (21): 3050-63.                        

Sonic hedgehog and bone morphogenetic protein-4 signaling pathway involved in epithelial cell renewal along the radial axis of the intestine., Ishizuya-Oka A., Digestion. January 1, 2008; 77 Suppl 1 42-7.

Regulation of adult intestinal epithelial stem cell development by thyroid hormone during Xenopus laevis metamorphosis., Ishizuya-Oka A., Dev Dyn. December 1, 2007; 236 (12): 3358-68.            

Cloning and expression of xP1-L, a new marker gene for larval surface mucous cells of tadpole stomach in Xenopus laevis., Ikuzawa M., Gene Expr Patterns. December 1, 2007; 8 (1): 12-8.    

Sox17 and Sox4 differentially regulate beta-catenin/T-cell factor activity and proliferation of colon carcinoma cells., Sinner D., Mol Cell Biol. November 1, 2007; 27 (22): 7802-15.                

Regeneration of the amphibian intestinal epithelium under the control of stem cell niche., Ishizuya-Oka A., Dev Growth Differ. February 1, 2007; 49 (2): 99-107.            

FGF signal transduction and the regulation of Cdx gene expression., Keenan ID., Dev Biol. November 15, 2006; 299 (2): 478-88.    

Regulatory interaction between CFTR and the SLC26 transporters., Shcheynikov N., Novartis Found Symp. January 1, 2006; 273 177-86; discussion 186-92, 261-4.

Molecular mechanisms for thyroid hormone-induced remodeling in the amphibian digestive tract: a model for studying organ regeneration., Ishizuya-Oka A., Dev Growth Differ. December 1, 2005; 47 (9): 601-7.        

A consensus Oct1 binding site is required for the activity of the Xenopus Cdx4 promoter., Reece-Hoyes JS., Dev Biol. June 15, 2005; 282 (2): 509-23.              

Requirement for matrix metalloproteinase stromelysin-3 in cell migration and apoptosis during tissue remodeling in Xenopus laevis., Ishizuya-Oka A., J Cell Biol. September 4, 2000; 150 (5): 1177-88.                      

Regional gene expression in the epithelia of the Xenopus tadpole gut., Chalmers AD., Mech Dev. August 1, 2000; 96 (1): 125-8.    

Xenopus NK cells identified by novel monoclonal antibodies., Horton TL., Eur J Immunol. February 1, 2000; 30 (2): 604-13.

The Xenopus tadpole gut: fate maps and morphogenetic movements., Chalmers AD., Development. January 1, 2000; 127 (2): 381-92.                  

A possible role for the high mobility group box transcription factor Tcf-4 in vertebrate gut epithelial cell differentiation., Lee YJ., J Biol Chem. January 15, 1999; 274 (3): 1566-72.  

Alcohol dehydrogenases in Xenopus development: conserved expression of ADH1 and ADH4 in epithelial retinoid target tissues., Hoffmann I., Dev Dyn. November 1, 1998; 213 (3): 261-70.        

Effects of forced expression of an NH2-terminal truncated beta-Catenin on mouse intestinal epithelial homeostasis., Wong MH., J Cell Biol. May 4, 1998; 141 (3): 765-77.              

Anteroposterior gradient of epithelial transformation during amphibian intestinal remodeling: immunohistochemical detection of intestinal fatty acid-binding protein., Ishizuya-Oka A., Dev Biol. December 1, 1997; 192 (1): 149-61.                  

Is Xenopus IgX an analog of IgA?, Mussmann R., Eur J Immunol. December 1, 1996; 26 (12): 2823-30.

Differentiation-associated antimicrobial functions in human colon adenocarcinoma cell lines., Bernet-Camard MF., Exp Cell Res. July 10, 1996; 226 (1): 80-9.

Thyroid hormone-dependent regulation of the intestinal fatty acid-binding protein gene during amphibian metamorphosis., Shi YB, Shi YB., Dev Biol. January 1, 1994; 161 (1): 48-58.              

GATA-4 is a novel transcription factor expressed in endocardium of the developing heart., Kelley C., Development. July 1, 1993; 118 (3): 817-27.                

Involvement of a neutral glycolipid in differential cell adhesion in the Xenopus blastula., Turner AP., EMBO J. November 1, 1992; 11 (11): 3845-55.

The distribution of E-cadherin during Xenopus laevis development., Levi G., Development. January 1, 1991; 111 (1): 159-69.                

XlHbox 8: a novel Xenopus homeo protein restricted to a narrow band of endoderm., Wright CV., Development. April 1, 1989; 105 (4): 787-94.          

Temporal pattern of appearance and distribution of cholecystokinin-like peptides during development in Xenopus laevis., Scalise FW., Gen Comp Endocrinol. November 1, 1988; 72 (2): 303-11.    

Development of the connective tissue in the digestive tract of the larval and metamorphosing Xenopus laevis., Ishizuya-Oka A., Anat Anz. January 1, 1987; 164 (2): 81-93.

The appearance and distribution of intermediate filament proteins during differentiation of the central nervous system, skin and notochord of Xenopus laevis., Godsave SF., J Embryol Exp Morphol. September 1, 1986; 97 201-23.              

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