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Spatiotemporally Controlled Mechanical Cues Drive Progenitor Mesenchymal-to-Epithelial Transition Enabling Proper Heart Formation and Function. , Jackson TR., Curr Biol. May 8, 2017; 27 (9): 1326-1335.
A Tissue-Mapped Axolotl De Novo Transcriptome Enables Identification of Limb Regeneration Factors. , Bryant DM., Cell Rep. January 17, 2017; 18 (3): 762-776.
The Lhx9-integrin pathway is essential for positioning of the proepicardial organ. , Tandon P ., Development. March 1, 2016; 143 (5): 831-40.
Ventricular cell fate can be specified until the onset of myocardial differentiation. , Caporilli S., Mech Dev. February 1, 2016; 139 31-41.
A posttranscriptional mechanism that controls Ptbp1 abundance in the Xenopus epidermis. , Méreau A., Mol Cell Biol. February 1, 2015; 35 (4): 758-68.
SHP-2 acts via ROCK to regulate the cardiac actin cytoskeleton. , Langdon Y ., Development. March 1, 2012; 139 (5): 948-57.
Skeletal muscle differentiation and fusion are regulated by the BAR-containing Rho-GTPase-activating protein ( Rho-GAP), GRAF1. , Doherty JT., J Biol Chem. July 22, 2011; 286 (29): 25903-21.
The BMP pathway acts to directly regulate Tbx20 in the developing heart. , Mandel EM ., Development. June 1, 2010; 137 (11): 1919-29.
Functional characterization of two CITED3 homologs (gcCITED3a and gcCITED3b) in the hypoxia-tolerant grass carp, Ctenopharyngodon idellus. , Ng PK., BMC Mol Biol. November 3, 2009; 10 101.
Cardiac differentiation in Xenopus requires the cyclin-dependent kinase inhibitor, p27Xic1. , Movassagh M., Cardiovasc Res. August 1, 2008; 79 (3): 436-47.
Vertebrate CASTOR is required for differentiation of cardiac precursor cells at the ventral midline. , Christine KS ., Dev Cell. April 1, 2008; 14 (4): 616-23.
The myocardin-related transcription factor, MASTR, cooperates with MyoD to activate skeletal muscle gene expression. , Meadows SM., Proc Natl Acad Sci U S A. February 5, 2008; 105 (5): 1545-50.
Transcription enhancer factor-1-dependent expression of the alpha-tropomyosin gene in the three muscle cell types. , Pasquet S., J Biol Chem. November 10, 2006; 281 (45): 34406-20.
Differential expression of tropomyosin during segmental heart development in Mexican axolotl. , Zajdel RW., J Cell Biochem. October 15, 2006; 99 (3): 952-65.
TBX5 is required for embryonic cardiac cell cycle progression. , Goetz SC., Development. July 1, 2006; 133 (13): 2575-84.
Anti-sense-mediated inhibition of expression of the novel striated tropomyosin isoform TPM1kappa disrupts myofibril organization in embryonic axolotl hearts. , Zajdel RW., J Cell Biochem. July 1, 2005; 95 (4): 840-8.
Tbx5 and Tbx20 act synergistically to control vertebrate heart morphogenesis. , Brown DD ., Development. February 1, 2005; 132 (3): 553-63.
Effects of 17beta-estradiol, nonylphenol, and bisphenol-A on developing Xenopus laevis embryos. , Sone K., Gen Comp Endocrinol. September 15, 2004; 138 (3): 228-36.
Xenopus muscle development: from primary to secondary myogenesis. , Chanoine C ., Dev Dyn. January 1, 2003; 226 (1): 12-23.
Activation of cardiac gene expression by myocardin, a transcriptional cofactor for serum response factor. , Wang D., Cell. June 29, 2001; 105 (7): 851-62.
Confocal imaging of early heart development in Xenopus laevis. , Kolker SJ., Dev Biol. February 1, 2000; 218 (1): 64-73.
A novel tropomyosin isoform encoded by the Xenopus laevis alpha- TM gene is expressed in the brain. , Gaillard C., Gene. January 30, 1998; 207 (2): 235-9.
Alpha-tropomyosin gene expression in Xenopus laevis: differential promoter usage during development and controlled expression by myogenic factors. , Gaillard C., Dev Genes Evol. January 1, 1998; 207 (7): 435-45.
Isoform transition of contractile proteins related to muscle remodeling with an axial gradient during metamorphosis in Xenopus laevis. , Nishikawa A., Dev Biol. September 1, 1994; 165 (1): 86-94.
Molecular cloning, sequencing and expression of an isoform of cardiac alpha-tropomyosin from the Mexican axolotl (Ambystoma mexicanum). , Luque EA., Biochem Biophys Res Commun. August 30, 1994; 203 (1): 319-25.
Differential regulation of skeletal muscle myosin-II and brush border myosin-I enzymology and mechanochemistry by bacterially produced tropomyosin isoforms. , Fanning AS., Cell Motil Cytoskeleton. January 1, 1994; 29 (1): 29-45.
Monoclonal antibodies against chicken tropomyosin isoforms: production, characterization, and application. , Lin JJ., Hybridoma. January 1, 1985; 4 (3): 223-42.