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cis-Regulatory analysis for later phase of anterior neuroectoderm-specific foxQ2 expression in sea urchin embryos. , Yamazaki A., Genesis. June 1, 2019; 57 (6): e23302.
MAPK and GSK3/ß-TRCP-mediated degradation of the maternal Ets domain transcriptional repressor Yan/ Tel controls the spatial expression of nodal in the sea urchin embryo. , Molina MD., PLoS Genet. September 17, 2018; 14 (9): e1007621.
Lectins identify distinct populations of coelomocytes in Strongylocentrotus purpuratus. , Liao WY., PLoS One. November 10, 2017; 12 (11): e0187987.
Experimental demonstration of a trophic cascade in the Galápagos rocky subtidal: Effects of consumer identity and behavior. , Witman JD., PLoS One. April 17, 2017; 12 (4): e0175705.
Diversification of spatiotemporal expression and copy number variation of the echinoid hbox12/ pmar1/ micro1 multigene family. , Cavalieri V., PLoS One. March 28, 2017; 12 (3): e0174404.
An integrated modelling framework from cells to organism based on a cohort of digital embryos. , Villoutreix P., Sci Rep. December 2, 2016; 6 37438.
Expression of GATA and POU transcription factors during the development of the planktotrophic trochophore of the polychaete serpulid Hydroides elegans. , Wong KS., Evol Dev. July 1, 2016; 18 (4): 254-66.
A workflow to process 3D+time microscopy images of developing organisms and reconstruct their cell lineage. , Faure E., Nat Commun. February 25, 2016; 7 8674.
Ca²⁺ influx-linked protein kinase C activity regulates the β- catenin localization, micromere induction signalling and the oral-aboral axis formation in early sea urchin embryos. , Yazaki I., Zygote. June 1, 2015; 23 (3): 426-46.
Mechanisms of the epithelial-to-mesenchymal transition in sea urchin embryos. , Katow H., Tissue Barriers. January 1, 2015; 3 (4): e1059004.
Early asymmetric cues triggering the dorsal/ventral gene regulatory network of the sea urchin embryo. , Cavalieri V., Elife. December 2, 2014; 3 e04664.
Molecular conservation of metazoan gut formation: evidence from expression of endomesoderm genes in Capitella teleta (Annelida). , Boyle MJ., Evodevo. June 17, 2014; 5 39.
Mesomere-derived glutamate decarboxylase-expressing blastocoelar mesenchyme cells of sea urchin larvae. , Katow H., Biol Open. January 15, 2014; 3 (1): 94-102.
Nuclearization of β- catenin in ectodermal precursors confers organizer-like ability to induce endomesoderm and pattern a pluteus larva. , Byrum CA ., Evodevo. November 4, 2013; 4 (1): 31.
Towards 3D in silico modeling of the sea urchin embryonic development. , Rizzi B., J Chem Biol. September 13, 2013; 7 (1): 17-28.
Beyond BLASTing: tertiary and quaternary structure analysis helps identify major vault proteins. , Daly TK., Genome Biol Evol. January 1, 2013; 5 (1): 217-32.
Integration of canonical and noncanonical Wnt signaling pathways patterns the neuroectoderm along the anterior-posterior axis of sea urchin embryos. , Range RC ., PLoS Biol. January 1, 2013; 11 (1): e1001467.
Characterization and Endocytic Internalization of Epith-2 Cell Surface Glycoprotein during the Epithelial-to-Mesenchymal Transition in Sea Urchin Embryos. , Wakayama N., Front Endocrinol (Lausanne). January 1, 2013; 4 112.
The tension at the top of the animal pole decreases during meiotic cell division. , Satoh SK., PLoS One. January 1, 2013; 8 (11): e79389.
Reciprocal signaling between the ectoderm and a mesendodermal left-right organizer directs left-right determination in the sea urchin embryo. , Bessodes N., PLoS Genet. January 1, 2012; 8 (12): e1003121.
Atypical protein kinase C controls sea urchin ciliogenesis. , Prulière G., Mol Biol Cell. June 15, 2011; 22 (12): 2042-53.
The echinoid mitotic gradient: effect of cell size on the micromere cleavage cycle. , Duncan RE., Mol Reprod Dev. January 1, 2011; 78 (10-11): 868-78.
Ancestral regulatory circuits governing ectoderm patterning downstream of Nodal and BMP2/4 revealed by gene regulatory network analysis in an echinoderm. , Saudemont A., PLoS Genet. December 23, 2010; 6 (12): e1001259.
Embryonic, larval, and juvenile development of the sea biscuit Clypeaster subdepressus (Echinodermata: Clypeasteroida). , Vellutini BC., PLoS One. March 22, 2010; 5 (3): e9654.
Distinct embryotoxic effects of lithium appeared in a new assessment model of the sea urchin: the whole embryo assay and the blastomere culture assay. , Kiyomoto M ., Ecotoxicology. March 1, 2010; 19 (3): 563-70.
Action at a distance during cytokinesis. , von Dassow G., J Cell Biol. December 14, 2009; 187 (6): 831-45.
Evolutionary modification of specification for the endomesoderm in the direct developing echinoid Peronella japonica: loss of the endomesoderm-inducing signal originating from micromeres. , Iijima M., Dev Genes Evol. May 1, 2009; 219 (5): 235-47.
Gene regulatory network interactions in sea urchin endomesoderm induction. , Sethi AJ., PLoS Biol. February 3, 2009; 7 (2): e1000029.
Specification process of animal plate in the sea urchin embryo. , Sasaki H., Dev Growth Differ. September 1, 2008; 50 (7): 595-606.
Gene expression patterns in a novel animal appendage: the sea urchin pluteus arm. , Love AC., Evol Dev. January 1, 2007; 9 (1): 51-68.
Subequatorial cytoplasm plays an important role in ectoderm patterning in the sea urchin embryo. , Kominami T., Dev Growth Differ. February 1, 2006; 48 (2): 101-15.
The micro1 gene is necessary and sufficient for micromere differentiation and mid/ hindgut-inducing activity in the sea urchin embryo. , Yamazaki A., Dev Genes Evol. September 1, 2005; 215 (9): 450-59.
Developmental potential of small micromeres in sea urchin embryos. , Kurihara H., Zoolog Sci. August 1, 2005; 22 (8): 845-52.
SoxB1 downregulation in vegetal lineages of sea urchin embryos is achieved by both transcriptional repression and selective protein turnover. , Angerer LM ., Development. March 1, 2005; 132 (5): 999-1008.
Structure, regulation, and function of micro1 in the sea urchin Hemicentrotus pulcherrimus. , Nishimura Y., Dev Genes Evol. November 1, 2004; 214 (11): 525-36.
The M-phase-promoting factor modulates the sensitivity of the Ca2+ stores to inositol 1,4,5-trisphosphate via the actin cytoskeleton. , Lim D., J Biol Chem. October 24, 2003; 278 (43): 42505-14.
Coquillette, a sea urchin T-box gene of the Tbx2 subfamily, is expressed asymmetrically along the oral-aboral axis of the embryo and is involved in skeletogenesis. , Croce J ., Mech Dev. May 1, 2003; 120 (5): 561-72.
Nuclear envelope breakdown in starfish oocytes proceeds by partial NPC disassembly followed by a rapidly spreading fenestration of nuclear membranes. , Lénárt P., J Cell Biol. March 31, 2003; 160 (7): 1055-68.
Primary mesenchyme cell patterning during the early stages following ingression. , Peterson RE., Dev Biol. February 1, 2003; 254 (1): 68-78.
Patterning the sea urchin embryo: gene regulatory networks, signaling pathways, and cellular interactions. , Angerer LM ., Curr Top Dev Biol. January 1, 2003; 53 159-98.
Transient activation of the micro1 homeobox gene family in the sea urchin ( Hemicentrotus pulcherrimus) micromere. , Kitamura K., Dev Genes Evol. February 1, 2002; 212 (1): 1-10.
Change in the adhesive properties of blastomeres during early cleavage stages in sea urchin embryo. , Masui M., Dev Growth Differ. February 1, 2001; 43 (1): 43-53.
Regulating potential in development of a direct developing echinoid, Peronella japonica. , Kitazawa C., Dev Growth Differ. February 1, 2001; 43 (1): 73-82.
Micromere descendants at the blastula stage are involved in normal archenteron formation in sea urchin embryos. , Ishizuka Y., Dev Genes Evol. February 1, 2001; 211 (2): 83-8.
Deuterostome evolution: early development in the enteropneust hemichordate, Ptychodera flava. , Henry JQ., Evol Dev. January 1, 2001; 3 (6): 375-90.
A BMP pathway regulates cell fate allocation along the sea urchin animal-vegetal embryonic axis. , Angerer LM ., Development. March 1, 2000; 127 (5): 1105-14.
Regulative potential to form an amniotic cavity in mesomeres of a direct developing echinoid, Peronella japonica. , Kitazawa C., Zygote. January 1, 2000; 8 Suppl 1 S79.
Studies on the cellular basis of morphogenesis in the sea urchin embryo. Directed movements of primary mesenchyme cells in normal and vegetalized larvae. , Gustafson T., Exp Cell Res. December 15, 1999; 253 (2): 288-95.
SpSoxB1, a maternally encoded transcription factor asymmetrically distributed among early sea urchin blastomeres. , Kenny AP., Development. December 1, 1999; 126 (23): 5473-83.
Timing of the potential of micromere-descendants in echinoid embryos to induce endoderm differentiation of mesomere-descendants. , Minokawa T ., Dev Growth Differ. October 1, 1999; 41 (5): 535-47.