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Lens regeneration from the cornea requires suppression of Wnt/ β-catenin signaling. , Hamilton PW., Exp Eye Res. April 1, 2016; 145 206-215.
Generation of BAC transgenic tadpoles enabling live imaging of motoneurons by using the urotensin II-related peptide (ust2b) gene as a driver. , Bougerol M., PLoS One. February 6, 2015; 10 (2): e0117370.
The need of MMP-2 on the sperm surface for Xenopus fertilization: its role in a fast electrical block to polyspermy. , Iwao Y ., Mech Dev. November 1, 2014; 134 80-95.
Embryological manipulations in the developing Xenopus inner ear reveal an intrinsic role for Wnt signaling in dorsal- ventral patterning. , Forristall CA ., Dev Dyn. October 1, 2014; 243 (10): 1262-74.
Kinetochore- microtubule attachment throughout mitosis potentiated by the elongated stalk of the kinetochore kinesin CENP-E. , Vitre B., Mol Biol Cell. August 1, 2014; 25 (15): 2272-81.
Dissection of a Ciona regulatory element reveals complexity of cross-species enhancer activity. , Chen WC., Dev Biol. June 15, 2014; 390 (2): 261-72.
Retinoic acid regulation by CYP26 in vertebrate lens regeneration. , Thomas AG ., Dev Biol. February 15, 2014; 386 (2): 291-301.
A truncated form of rod photoreceptor PDE6 β-subunit causes autosomal dominant congenital stationary night blindness by interfering with the inhibitory activity of the γ-subunit. , Manes G., PLoS One. January 1, 2014; 9 (4): e95768.
Nudel/NudE and Lis1 promote dynein and dynactin interaction in the context of spindle morphogenesis. , Wang S., Mol Biol Cell. November 1, 2013; 24 (22): 3522-33.
Light-activation of the Archaerhodopsin H(+)-pump reverses age-dependent loss of vertebrate regeneration: sparking system-level controls in vivo. , Adams DS ., Biol Open. March 15, 2013; 2 (3): 306-13.
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.
Spinal cord regeneration in Xenopus tadpoles proceeds through activation of Sox2-positive cells. , Gaete M ., Neural Dev. April 26, 2012; 7 13.
Generation of a genetically encoded marker of rod photoreceptor outer segment growth and renewal. , Willoughby JJ., Biol Open. January 15, 2012; 1 (1): 30-6.
The expression of αA- and βB1-crystallin during normal development and regeneration, and proteomic analysis for the regenerating lens in Xenopus laevis. , Zhao Y., Mol Vis. March 23, 2011; 17 768-78.
The N-terminal coiled-coil of Ndel1 is a regulated scaffold that recruits LIS1 to dynein. , Zyłkiewicz E., J Cell Biol. February 7, 2011; 192 (3): 433-45.
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.
COP-binding sites in p24delta2 are necessary for proper secretory cargo biosynthesis. , Strating JR., Int J Biochem Cell Biol. July 1, 2009; 41 (7): 1619-27.
Spinal cord is required for proper regeneration of the tail in Xenopus tadpoles. , Taniguchi Y., Dev Growth Differ. February 1, 2008; 50 (2): 109-20.
Regulation of gating and rundown of HCN hyperpolarization-activated channels by exogenous and endogenous PIP2. , Pian P., J Gen Physiol. November 1, 2006; 128 (5): 593-604.
Protein kinase A, which regulates intracellular transport, forms complexes with molecular motors on organelles. , Kashina AS., Curr Biol. October 26, 2004; 14 (20): 1877-81.
The XMAP215-family protein DdCP224 is required for cortical interactions of microtubules. , Hestermann A., BMC Cell Biol. June 8, 2004; 5 24.
Conservation of the heterochronic regulator Lin-28, its developmental expression and microRNA complementary sites. , Moss EG ., Dev Biol. June 15, 2003; 258 (2): 432-42.
Fluorescent labeling of endothelial cells allows in vivo, continuous characterization of the vascular development of Xenopus laevis. , Levine AJ., Dev Biol. February 1, 2003; 254 (1): 50-67.
The gene for the intermediate chain subunit of cytoplasmic dynein is essential in Drosophila. , Boylan KL., Genetics. November 1, 2002; 162 (3): 1211-20.
Interactions and regulation of molecular motors in Xenopus melanophores. , Gross SP., J Cell Biol. March 4, 2002; 156 (5): 855-65.
Transcription factors of the anterior neural plate alter cell movements of epidermal progenitors to specify a retinal fate. , Kenyon KL ., Dev Biol. December 1, 2001; 240 (1): 77-91.
Molecular targets of vertebrate segmentation: two mechanisms control segmental expression of Xenopus hairy2 during somite formation. , Davis RL., Dev Cell. October 1, 2001; 1 (4): 553-65.
foxD5a, a Xenopus winged helix gene, maintains an immature neural ectoderm via transcriptional repression that is dependent on the C-terminal domain. , Sullivan SA., Dev Biol. April 15, 2001; 232 (2): 439-57.
Ectopic pigmentation in Xenopus in response to DCoH/ PCD, the cofactor of HNF1 transcription factor/pterin-4alpha-carbinolamine dehydratase. , Pogge v Strandmann E., Mech Dev. March 1, 2000; 91 (1-2): 53-60.
The fate of cells in the tailbud of Xenopus laevis. , Davis RL., Development. January 1, 2000; 127 (2): 255-67.
Pax6 induces ectopic eyes in a vertebrate. , Chow RL., Development. October 1, 1999; 126 (19): 4213-22.
Animal-vegetal asymmetries influence the earliest steps in retina fate commitment in Xenopus. , Moore KB ., Dev Biol. August 1, 1999; 212 (1): 25-41.
Localization of the kinesin-like protein Xklp2 to spindle poles requires a leucine zipper, a microtubule-associated protein, and dynein. , Wittmann T., J Cell Biol. November 2, 1998; 143 (3): 673-85.
Programmed cell death during Xenopus development: a spatio-temporal analysis. , Hensey C., Dev Biol. November 1, 1998; 203 (1): 36-48.
Basic fibroblast growth factor ( FGF-2) induced transdifferentiation of retinal pigment epithelium: generation of retinal neurons and glia. , Sakaguchi DS ., Dev Dyn. August 1, 1997; 209 (4): 387-98.
Xenopus Pax-6 and retinal development. , Hirsch N ., J Neurobiol. January 1, 1997; 32 (1): 45-61.
A complex of NuMA and cytoplasmic dynein is essential for mitotic spindle assembly. , Merdes A., Cell. November 1, 1996; 87 (3): 447-58.
Spatial, temporal and hormonal regulation of programmed muscle cell death during metamorphosis of the frog Xenopus laevis. , Nishikawa A., Differentiation. November 1, 1995; 59 (4): 207-14.
Hormonal regulation of programmed cell death during amphibian metamorphosis. , Tata JR ., Biochem Cell Biol. January 1, 1994; 72 (11-12): 581-8.
Homeogenetic neural induction in Xenopus. , Servetnick M ., Dev Biol. September 1, 1991; 147 (1): 73-82.
Changes in neural and lens competence in Xenopus ectoderm: evidence for an autonomous developmental timer. , Servetnick M ., Development. May 1, 1991; 112 (1): 177-88.
Expression and segregation of nucleoplasmin during development in Xenopus. , Litvin J., Development. January 1, 1988; 102 (1): 9-21.