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High-throughput analysis reveals novel maternal germline RNAs crucial for primordial germ cell preservation and proper migration. , Owens DA ., Development. January 15, 2017; 144 (2): 292-304.
Global analysis of asymmetric RNA enrichment in oocytes reveals low conservation between closely related Xenopus species. , Claußen M., Mol Biol Cell. November 5, 2015; .
Intracellular microRNA profiles form in the Xenopus laevis oocyte that may contribute to asymmetric cell division. , Sidova M., Sci Rep. January 12, 2015; 5 11157.
Possible involvement of insulin-like growth factor 2 mRNA-binding protein 3 in zebrafish oocyte maturation as a novel cyclin B1 mRNA-binding protein that represses the translation in immature oocytes. , Takahashi K., Biochem Biophys Res Commun. May 23, 2014; 448 (1): 22-7.
Novel animal pole-enriched maternal mRNAs are preferentially expressed in neural ectoderm. , Grant PA ., Dev Dyn. March 1, 2014; 243 (3): 478-96.
RNA localization in Xenopus oocytes uses a core group of trans-acting factors irrespective of destination. , Snedden DD., RNA. July 1, 2013; 19 (7): 889-95.
Directional transport is mediated by a Dynein-dependent step in an RNA localization pathway. , Gagnon JA., PLoS Biol. January 1, 2013; 11 (4): e1001551.
Single blastomere expression profiling of Xenopus laevis embryos of 8 to 32-cells reveals developmental asymmetry. , Flachsova M., Sci Rep. January 1, 2013; 3 2278.
The many functions of mRNA localization during normal development and disease: from pillar to post. , Cody NA., Wiley Interdiscip Rev Dev Biol. January 1, 2013; 2 (6): 781-96.
Foxi2 is an animally localized maternal mRNA in Xenopus, and an activator of the zygotic ectoderm activator Foxi1e. , Cha SW ., PLoS One. January 1, 2012; 7 (7): e41782.
Interactions of 40LoVe within the ribonucleoprotein complex that forms on the localization element of Xenopus Vg1 mRNA. , Kroll TT ., Mech Dev. July 1, 2009; 126 (7): 523-38.
The shroom family proteins play broad roles in the morphogenesis of thickened epithelial sheets. , Lee C , Lee C , Lee C ., Dev Dyn. June 1, 2009; 238 (6): 1480-91.
Multiple kinesin motors coordinate cytoplasmic RNA transport on a subpopulation of microtubules in Xenopus oocytes. , Messitt TJ., Dev Cell. September 1, 2008; 15 (3): 426-436.
Long- and short-range signals control the dynamic expression of an animal hemisphere-specific gene in Xenopus. , Mir A., Dev Biol. March 1, 2008; 315 (1): 161-72.
Intracellular expression profiles measured by real-time PCR tomography in the Xenopus laevis oocyte. , Sindelka R ., Nucleic Acids Res. February 1, 2008; 36 (2): 387-92.
Identification of a novel conserved mixed-isoform B56 regulatory subunit and spatiotemporal regulation of protein phosphatase 2A during Xenopus laevis development. , Baek S., BMC Dev Biol. May 31, 2007; 7 139.
XCR2, one of three Xenopus EGF- CFC genes, has a distinct role in the regulation of left- right patterning. , Onuma Y ., Development. January 1, 2006; 133 (2): 237-50.
Identification of asymmetrically localized transcripts along the animal-vegetal axis of the Xenopus egg. , Kataoka K., Dev Growth Differ. October 1, 2005; 47 (8): 511-21.
ALK4 functions as a receptor for multiple TGF beta-related ligands to regulate left- right axis determination and mesoderm induction in Xenopus. , Chen Y ., Dev Biol. April 15, 2004; 268 (2): 280-94.
Xvelo1 uses a novel 75-nucleotide signal sequence that drives vegetal localization along the late pathway in Xenopus oocytes. , Claussen M., Dev Biol. February 15, 2004; 266 (2): 270-84.
Lefty blocks a subset of TGFbeta signals by antagonizing EGF- CFC coreceptors. , Cheng SK., PLoS Biol. February 1, 2004; 2 (2): E30.
Cell fate specification and competence by Coco, a maternal BMP, TGFbeta and Wnt inhibitor. , Bell E ., Development. April 1, 2003; 130 (7): 1381-9.
Localization of RNAs in oocytes of Eleutherodactylus coqui, a direct developing frog, differs from Xenopus laevis. , Beckham YM., Evol Dev. January 1, 2003; 5 (6): 562-71.
A ubiquitous and conserved signal for RNA localization in chordates. , Betley JN., Curr Biol. October 15, 2002; 12 (20): 1756-61.
RNA anchoring in the vegetal cortex of the Xenopus oocyte. , Alarcón VB., J Cell Sci. May 1, 2001; 114 (Pt 9): 1731-41.
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.
Overexpression of the Xenopus tight-junction protein claudin causes randomization of the left- right body axis. , Brizuela BJ., Dev Biol. February 15, 2001; 230 (2): 217-29.
Mesendoderm induction and reversal of left- right pattern by mouse Gdf1, a Vg1-related gene. , Wall NA., Dev Biol. November 15, 2000; 227 (2): 495-509.
Xenopus Xenf: an early endodermal nuclear factor that is regulated in a pathway distinct from Sox17 and Mix-related gene pathways. , Nakatani J., Mech Dev. March 1, 2000; 91 (1-2): 81-9.
Endodermal Nodal-related signals and mesoderm induction in Xenopus. , Agius E ., Development. March 1, 2000; 127 (6): 1173-83.
Vg1 RBP intracellular distribution and evolutionarily conserved expression at multiple stages during development. , Zhang Q ., Mech Dev. October 1, 1999; 88 (1): 101-6.
Animal-vegetal asymmetries influence the earliest steps in retina fate commitment in Xenopus. , Moore KB ., Dev Biol. August 1, 1999; 212 (1): 25-41.
Xenopus GDF6, a new antagonist of noggin and a partner of BMPs. , Chang C ., Development. August 1, 1999; 126 (15): 3347-57.
XCtBP is a XTcf-3 co-repressor with roles throughout Xenopus development. , Brannon M., Development. June 1, 1999; 126 (14): 3159-70.
derrière: a TGF-beta family member required for posterior development in Xenopus. , Sun BI., Development. April 1, 1999; 126 (7): 1467-82.
Xenopus Smad7 inhibits both the activin and BMP pathways and acts as a neural inducer. , Casellas R., Dev Biol. June 1, 1998; 198 (1): 1-12.
Dorsal determinants in the Xenopus egg are firmly associated with the vegetal cortex and behave like activators of the Wnt pathway. , Marikawa Y., Dev Biol. November 1, 1997; 191 (1): 69-79.
A vegetally localized T-box transcription factor in Xenopus eggs specifies mesoderm and endoderm and is essential for embryonic mesoderm formation. , Horb ME ., Development. May 1, 1997; 124 (9): 1689-98.
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.
Exogenous tau RNA is localized in oocytes: possible evidence for evolutionary conservation of localization mechanisms. , Litman P., Dev Biol. May 25, 1996; 176 (1): 86-94.
TGF-beta signals and a pattern in Xenopus laevis endodermal development. , Henry GL., Development. March 1, 1996; 122 (3): 1007-15.
Factors responsible for the establishment of the body plan in the amphibian embryo. , Grunz H ., Int J Dev Biol. February 1, 1996; 40 (1): 279-89.
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.
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.
Induction of dorsal mesoderm by soluble, mature Vg1 protein. , Kessler DS ., Development. July 1, 1995; 121 (7): 2155-64.
Regulation of Spemann organizer formation by the intracellular kinase Xgsk-3. , Pierce SB., Development. March 1, 1995; 121 (3): 755-65.
Two distinct pathways for the localization of RNAs at the vegetal cortex in Xenopus oocytes. , Kloc M ., Development. February 1, 1995; 121 (2): 287-97.
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.
Xwnt-11: a maternally expressed Xenopus wnt gene. , Ku M., Development. December 1, 1993; 119 (4): 1161-73.