Results 1 - 50 of 107 results
RAD21 deficiency drives corneal to scleral differentiation fate switching via upregulating WNT9B. , Liu H ., iScience. June 21, 2024; 27 (6): 109875.
Ocular microvasculature in adult Xenopus laevis: Scanning electron microscopy of vascular casts. , Lametschwandtner A., J Morphol. March 1, 2023; 284 (3): e21561.
Tissue-specific expression of carbohydrate sulfotransferases drives keratan sulfate biosynthesis in the notochord and otic vesicles of Xenopus embryos. , Yasuoka Y ., Front Cell Dev Biol. January 1, 2023; 11 957805.
Cellular and molecular profiles of larval and adult Xenopus corneal epithelia resolved at the single-cell level. , Sonam S., Dev Biol. November 1, 2022; 491 13-30.
Cornifelin expression during Xenopus laevis metamorphosis and in response to spinal cord injury. , Torruella-Gonzalez S., Gene Expr Patterns. March 1, 2022; 43 119234.
Ciliogenesis and autophagy are coordinately regulated by EphA2 in the cornea to maintain proper epithelial architecture. , Kaplan N., Ocul Surf. July 1, 2021; 21 193-205.
Understanding cornea epithelial stem cells and stem cell deficiency: Lessons learned using vertebrate model systems. , Adil MT., Genesis. February 1, 2021; 59 (1-2): e23411.
rad21 Is Involved in Corneal Stroma Development by Regulating Neural Crest Migration. , Zhang BN., Int J Mol Sci. October 21, 2020; 21 (20):
Modeling ocular lens disease in Xenopus. , Viet J., Dev Dyn. May 1, 2020; 249 (5): 610-621.
Understanding cornea homeostasis and wound healing using a novel model of stem cell deficiency in Xenopus. , Adil MT., Exp Eye Res. October 1, 2019; 187 107767.
A sclerocornea-associated RAD21 variant induces corneal stroma disorganization. , Zhang BN., Exp Eye Res. August 1, 2019; 185 107687.
Molecular markers for corneal epithelial cells in larval vs. adult Xenopus frogs. , Sonam S., Exp Eye Res. July 1, 2019; 184 107-125.
The role of sensory innervation in cornea- lens regeneration. , Perry KJ., Dev Dyn. July 1, 2019; 248 (7): 530-544.
Uroplakins play conserved roles in egg fertilization and acquired additional urothelial functions during mammalian divergence. , Liao Y., Mol Biol Cell. December 15, 2018; 29 (26): 3128-3143.
A model for investigating developmental eye repair in Xenopus laevis. , Kha CX ., Exp Eye Res. April 1, 2018; 169 38-47.
Frizzled 3 acts upstream of Alcam during embryonic eye development. , Seigfried FA., Dev Biol. June 1, 2017; 426 (1): 69-83.
The lens regenerative competency of limbal vs. central regions of mature Xenopus cornea epithelium. , Hamilton PW., Exp Eye Res. November 1, 2016; 152 94-99.
Functional assessment of SLC4A11, an integral membrane protein mutated in corneal dystrophies. , Loganathan SK., Am J Physiol Cell Physiol. November 1, 2016; 311 (5): C735-C748.
Lens regeneration from the cornea requires suppression of Wnt/ β-catenin signaling. , Hamilton PW., Exp Eye Res. April 1, 2016; 145 206-215.
Xenopus pax6 mutants affect eye development and other organ systems, and have phenotypic similarities to human aniridia patients. , Nakayama T ., Dev Biol. December 15, 2015; 408 (2): 328-44.
Molecular mechanism of CHRDL1-mediated X-linked megalocornea in humans and in Xenopus model. , Pfirrmann T ., Hum Mol Genet. June 1, 2015; 24 (11): 3119-32.
Prolonged in vivo imaging of Xenopus laevis. , Hamilton PW., Dev Dyn. August 1, 2014; 243 (8): 1011-9.
Retinoic acid regulation by CYP26 in vertebrate lens regeneration. , Thomas AG ., Dev Biol. February 15, 2014; 386 (2): 291-301.
Diurnal variation of tight junction integrity associates inversely with matrix metalloproteinase expression in Xenopus laevis corneal epithelium: implications for circadian regulation of homeostatic surface cell desquamation. , Wiechmann AF ., PLoS One. January 1, 2014; 9 (11): e113810.
Comparative expression analysis of cysteine-rich intestinal protein family members crip1, 2 and 3 during Xenopus laevis embryogenesis. , Hempel A., Int J Dev Biol. January 1, 2014; 58 (10-12): 841-9.
Transmembrane water-flux through SLC4A11: a route defective in genetic corneal diseases. , Vilas GL., Hum Mol Genet. November 15, 2013; 22 (22): 4579-90.
The structure and development of Xenopus laevis cornea. , Hu W ., Exp Eye Res. November 1, 2013; 116 109-28.
sox4 and sox11 function during Xenopus laevis eye development. , Cizelsky W., PLoS One. July 1, 2013; 8 (7): e69372.
Expression of pluripotency factors in larval epithelia of the frog Xenopus: evidence for the presence of cornea epithelial stem cells. , Perry KJ., Dev Biol. February 15, 2013; 374 (2): 281-94.
Axonal growth towards Xenopus skin in vitro is mediated by matrix metalloproteinase activity. , Tonge D ., Eur J Neurosci. February 1, 2013; 37 (4): 519-31.
Antagonistic cross-regulation between Wnt and Hedgehog signalling pathways controls post-embryonic retinal proliferation. , Borday C., Development. October 1, 2012; 139 (19): 3499-509.
Regional differences in rat conjunctival ion transport activities. , Yu D., Am J Physiol Cell Physiol. October 1, 2012; 303 (7): C767-80.
Transgenic Xenopus laevis with the ef1-α promoter as an experimental tool for amphibian retinal regeneration study. , Ueda Y., Genesis. August 1, 2012; 50 (8): 642-50.
In situ visualization of protein interactions in sensory neurons: glutamic acid-rich proteins (GARPs) play differential roles for photoreceptor outer segment scaffolding. , Ritter LM., J Neurosci. August 3, 2011; 31 (31): 11231-43.
FGF signaling is required for lens regeneration in Xenopus laevis. , Fukui L ., Biol Bull. August 1, 2011; 221 (1): 137-45.
Transdifferentiation from cornea to lens in Xenopus laevis depends on BMP signalling and involves upregulation of Wnt signalling. , Day RC., BMC Dev Biol. January 26, 2011; 11 54.
Molecular and cellular aspects of amphibian lens regeneration. , Henry JJ ., Prog Retin Eye Res. November 1, 2010; 29 (6): 543-55.
The G-protein-coupled receptor, GPR84, is important for eye development in Xenopus laevis. , Perry KJ., Dev Dyn. November 1, 2010; 239 (11): 3024-37.
Melatonin receptor expression in Xenopus laevis surface corneal epithelium: diurnal rhythm of lateral membrane localization. , Wiechmann AF ., Mol Vis. November 17, 2009; 15 2384-403.
Electric currents in Xenopus tadpole tail regeneration. , Reid B., Dev Biol. November 1, 2009; 335 (1): 198-207.
Retina and lens regeneration in anuran amphibians. , Filoni S., Semin Cell Dev Biol. July 1, 2009; 20 (5): 528-34.
Beyond early development: Xenopus as an emerging model for the study of regenerative mechanisms. , Beck CW ., Dev Dyn. June 1, 2009; 238 (6): 1226-48.
Retinal regeneration in the Xenopus laevis tadpole: a new model system. , Vergara MN., Mol Vis. May 18, 2009; 15 1000-13.
Pleiotropic effects in Eya3 knockout mice. , Söker T., BMC Dev Biol. June 23, 2008; 8 118.
Psf2 plays important roles in normal eye development in Xenopus laevis. , Walter BE., Mol Vis. May 19, 2008; 14 906-21.
The optic vesicle promotes cornea to lens transdifferentiation in larval Xenopus laevis. , Cannata SM., J Anat. May 1, 2008; 212 (5): 621-6.
The lens-regenerating competence in the outer cornea and epidermis of larval Xenopus laevis is related to pax6 expression. , Gargioli C., J Anat. May 1, 2008; 212 (5): 612-20.
Wnt6 expression in epidermis and epithelial tissues during Xenopus organogenesis. , Lavery DL., Dev Dyn. March 1, 2008; 237 (3): 768-79.
Neural retinal regeneration in the anuran amphibian Xenopus laevis post-metamorphosis: transdifferentiation of retinal pigmented epithelium regenerates the neural retina. , Yoshii C., Dev Biol. March 1, 2007; 303 (1): 45-56.
tBid mediated activation of the mitochondrial death pathway leads to genetic ablation of the lens in Xenopus laevis. , Du Pasquier D., Genesis. January 1, 2007; 45 (1): 1-10.