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The Spemann organizer of Xenopus is patterned along its anteroposterior axis at the earliest gastrula stage. , Zoltewicz JS ., Dev Biol. December 15, 1997; 192 (2): 482-91.
Localized maternal proteins in Xenopus revealed by subtractive immunization. , Denegre JM., Dev Biol. December 15, 1997; 192 (2): 446-54.
Formation of new plasma membrane during the first cleavage cycle in the egg of Xenopus laevis: an immunocytological study. , Aimar C., Dev Growth Differ. December 1, 1997; 39 (6): 693-704.
Xenopus Pax-2 displays multiple splice forms during embryogenesis and pronephric kidney development. , Heller N., Mech Dev. December 1, 1997; 69 (1-2): 83-104.
The homeobox gene PV.1 mediates specification of the prospective neural ectoderm in Xenopus embryos. , Ault KT., Dev Biol. December 1, 1997; 192 (1): 162-71.
Characterization and early embryonic expression of a neural specific transcription factor xSOX3 in Xenopus laevis. , Penzel R., Int J Dev Biol. October 1, 1997; 41 (5): 667-77.
Progesterone acts through protein kinase C to remodel the cytoplasm as the amphibian oocyte becomes the fertilization-competent egg. , Johnson J., Mech Dev. October 1, 1997; 67 (2): 215-26.
Somatic linker histones cause loss of mesodermal competence in Xenopus. , Steinbach OC., Nature. September 25, 1997; 389 (6649): 395-9.
Developmental expression of the inositol 1,4,5-trisphosphate receptor and localization of inositol 1,4,5-trisphosphate during early embryogenesis in Xenopus laevis. , Kume S., Mech Dev. August 1, 1997; 66 (1-2): 157-68.
Xenopus laevis sperm- egg adhesion is regulated by modifications in the sperm receptor and the egg vitelline envelope. , Tian J ., Dev Biol. July 15, 1997; 187 (2): 143-53.
Xmsx-1 modifies mesodermal tissue pattern along dorsoventral axis in Xenopus laevis embryo. , Maeda R ., Development. July 1, 1997; 124 (13): 2553-60.
Changes in microtubule structures during the first cell cycle of physiologically polyspermic newt eggs. , Iwao Y ., Mol Reprod Dev. June 1, 1997; 47 (2): 210-21.
The organization and animal-vegetal asymmetry of cytokeratin filaments in stage VI Xenopus oocytes is dependent upon F-actin and microtubules. , Gard DL ., Dev Biol. April 1, 1997; 184 (1): 95-114.
New perspectives on the role of the fibroblast growth factor family in amphibian development. , Isaacs HV ., Cell Mol Life Sci. April 1, 1997; 53 (4): 350-61.
Establishment of the dorso- ventral axis in Xenopus embryos is presaged by early asymmetries in beta-catenin that are modulated by the Wnt signaling pathway. , Larabell CA ., J Cell Biol. March 10, 1997; 136 (5): 1123-36.
The Xenopus T-box gene, Antipodean, encodes a vegetally localised maternal mRNA and can trigger mesoderm formation. , Stennard F ., Development. December 1, 1996; 122 (12): 4179-88.
An indelible lineage marker for Xenopus using a mutated green fluorescent protein. , Zernicka-Goetz M., Development. December 1, 1996; 122 (12): 3719-24.
Fertilization stimulates an increase in inositol trisphosphate and inositol lipid levels in Xenopus eggs. , Snow P., Dev Biol. November 25, 1996; 180 (1): 108-18.
The mRNA encoding a beta subunit of heterotrimeric GTP-binding proteins is localized to the animal pole of Xenopus laevis oocyte and embryos. , Devic E., Mech Dev. October 1, 1996; 59 (2): 141-51.
Embryonic expression patterns of Xenopus syndecans. , Teel AL., Mech Dev. October 1, 1996; 59 (2): 115-27.
XFGF-9: a new fibroblast growth factor from Xenopus embryos. , Song J., Dev Dyn. August 1, 1996; 206 (4): 427-36.
Integrin alpha 6 expression is required for early nervous system development in Xenopus laevis. , Lallier TE., Development. August 1, 1996; 122 (8): 2539-54.
Xom: a Xenopus homeobox gene that mediates the early effects of BMP-4. , Ladher R., Development. August 1, 1996; 122 (8): 2385-94.
Xenopus laevis actin-depolymerizing factor/cofilin: a phosphorylation-regulated protein essential for development. , Abe H., J Cell Biol. March 1, 1996; 132 (5): 871-85.
Xenopus poly (A) binding protein maternal RNA is localized during oogenesis and associated with large complexes in blastula. , Schroeder KE., Dev Genet. January 1, 1996; 19 (3): 268-76.
Molecular mechanisms of Spemann's organizer formation: conserved growth factor synergy between Xenopus and mouse. , Watabe T., Genes Dev. December 15, 1995; 9 (24): 3038-50.
Effect of microinjection of rap 2A point mutant proteins on maturation and mottling in Xenopus oocytes. , Carnero A., Biochem Biophys Res Commun. November 22, 1995; 216 (3): 748-54.
The homeobox-containing gene XANF-1 may control development of the Spemann organizer. , Zaraisky AG ., Development. November 1, 1995; 121 (11): 3839-47.
eFGF is expressed in the dorsal midline of Xenopus laevis. , Isaacs HV ., Int J Dev Biol. August 1, 1995; 39 (4): 575-9.
Distinct expression and shared activities of members of the hedgehog gene family of Xenopus laevis. , Ekker SC ., Development. August 1, 1995; 121 (8): 2337-47.
Xwnt-8b: a maternally expressed Xenopus Wnt gene with a potential role in establishing the dorsoventral axis. , Cui Y., Development. July 1, 1995; 121 (7): 2177-86.
The embryonic RNA helicase gene ( ERH): a new member of the DEAD box family of RNA helicases. , Sowden J., Biochem J. June 15, 1995; 308 ( Pt 3) 839-46.
Effect of activin and lithium on isolated Xenopus animal blastomeres and response alteration at the midblastula transition. , Kinoshita K., Development. June 1, 1995; 121 (6): 1581-9.
Regulation of Spemann organizer formation by the intracellular kinase Xgsk-3. , Pierce SB., Development. March 1, 1995; 121 (3): 755-65.
Activin induces the expression of the Xenopus homologue of sonic hedgehog during mesoderm formation in Xenopus explants. , Yokotal C., Biochem Biophys Res Commun. February 6, 1995; 207 (1): 1-7.
Quantal puffs of intracellular Ca2+ evoked by inositol trisphosphate in Xenopus oocytes. , Yao Y., J Physiol. February 1, 1995; 482 ( Pt 3) 533-53.
Patterns of localization and cytoskeletal association of two vegetally localized RNAs, Vg1 and Xcat-2. , Forristall C., Development. January 1, 1995; 121 (1): 201-8.
Calcium puffs in Xenopus oocytes. , Parker I., Ciba Found Symp. January 1, 1995; 188 50-60; discussion 60-5.
Spatial and temporal expression of basic fibroblast growth factor ( FGF-2) mRNA and protein in early Xenopus development. , Song J., Mech Dev. December 1, 1994; 48 (3): 141-51.
A fate map for the 32-cell stage of Rana pipiens. , Saint-Jeannet JP ., Dev Biol. December 1, 1994; 166 (2): 755-62.
The hemispheric functional expression of the thyrotropin-releasing-hormone receptor is not determined by the receptors' physical distribution. , Matus-Leibovitch N., Biochem J. October 1, 1994; 303 ( Pt 1) 129-34.
Novel HOX, POU and FKH genes expressed during bFGF-induced mesodermal differentiation in Xenopus. , King MW , King MW ., Nucleic Acids Res. September 25, 1994; 22 (19): 3990-6.
Provisional bilateral symmetry in Xenopus eggs is established during maturation. , Brown EE ., Zygote. August 1, 1994; 2 (3): 213-20.
The cleavage stage origin of Spemann's Organizer: analysis of the movements of blastomere clones before and during gastrulation in Xenopus. , Bauer DV., Development. May 1, 1994; 120 (5): 1179-89.
Confocal microscopy of F-actin distribution in Xenopus oocytes. , Roeder AD., Zygote. May 1, 1994; 2 (2): 111-24.
An3 mRNA encodes an RNA helicase that colocalizes with nucleoli in Xenopus oocytes in a stage-specific manner. , Gururajan R., Proc Natl Acad Sci U S A. March 15, 1994; 91 (6): 2056-60.
Highly polarized EGF receptor tyrosine kinase activity initiates egg activation in Xenopus. , Yim DL., Dev Biol. March 1, 1994; 162 (1): 41-55.
The four animal blastomeres of the eight-cell stage of Xenopus laevis are intrinsically capable of differentiating into dorsal mesodermal derivatives. , Grunz H ., Int J Dev Biol. March 1, 1994; 38 (1): 69-76.
Fibroblast growth factor, but not activin, is a potent activator of mitogen-activated protein kinase in Xenopus explants. , Graves LM., Proc Natl Acad Sci U S A. March 1, 1994; 91 (5): 1662-6.
Presence of inositol 1,4,5-trisphosphate receptor, calreticulin, and calsequestrin in eggs of sea urchins and Xenopus laevis. , Parys JB., Dev Biol. February 1, 1994; 161 (2): 466-76.