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A large-scale analysis of mRNAs expressed by primary mesenchyme cells of the sea urchin embryo. , Zhu X., Development. July 1, 2001; 128 (13): 2615-27.
Skeletogenesis in sea urchin interordinal hybrid embryos. , Brandhorst BP ., Cell Tissue Res. July 1, 2001; 305 (1): 159-67.
Inhibitors of procollagen C-terminal proteinase block gastrulation and spicule elongation in the sea urchin embryo. , Huggins LG., Dev Growth Differ. August 1, 2001; 43 (4): 415-24.
An RGDS peptide-binding receptor, FR-1R, localizes to the basal side of the ectoderm and to primary mesenchyme cells in sand dollar embryos. , Katow H., Dev Growth Differ. October 1, 2001; 43 (5): 601-10.
Spicule matrix protein LSM34 is essential for biomineralization of the sea urchin spicule. , Peled-Kamar M., Exp Cell Res. January 1, 2002; 272 (1): 56-61.
Biomineralization of the spicules of sea urchin embryos. , Wilt FH ., Zoolog Sci. March 1, 2002; 19 (3): 253-61.
Identification and developmental expression of new biomineralization proteins in the sea urchin Strongylocentrotus purpuratus. , Illies MR., Dev Genes Evol. October 1, 2002; 212 (9): 419-31.
Essential role of growth factor receptor-mediated signal transduction through the mitogen-activated protein kinase pathway in early embryogenesis of the echinoderm. , Katow H., Dev Growth Differ. October 1, 2002; 44 (5): 437-55.
T-brain homologue (HpTb) is involved in the archenteron induction signals of micromere descendant cells in the sea urchin embryo. , Fuchikami T., Development. November 1, 2002; 129 (22): 5205-16.
Primary mesenchyme cell patterning during the early stages following ingression. , Peterson RE., Dev Biol. February 1, 2003; 254 (1): 68-78.
Biological targets of neurotoxic pesticides analysed by alteration of developmental events in the Mediterranean sea urchin, Paracentrotus lividus. , Pesando D., Mar Environ Res. February 1, 2003; 55 (1): 39-57.
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.
Activation of pmar1 controls specification of micromeres in the sea urchin embryo. , Oliveri P ., Dev Biol. June 1, 2003; 258 (1): 32-43.
Signals from primary mesenchyme cells regulate endoderm differentiation in the sea urchin embryo. , Hamada M., Dev Growth Differ. August 1, 2003; 45 (4): 339-50.
Spdeadringer, a sea urchin embryo gene required separately in skeletogenic and oral ectoderm gene regulatory networks. , Amore G., Dev Biol. September 1, 2003; 261 (1): 55-81.
Patterning mechanisms in the evolution of derived developmental life histories: the role of Wnt signaling in axis formation of the direct-developing sea urchin Heliocidaris erythrogramma. , Kauffman JS., Dev Genes Evol. December 1, 2003; 213 (12): 612-24.
Ultrastructural localization of spicule matrix proteins in normal and metalloproteinase inhibitor-treated sea urchin primary mesenchyme cells. , Ingersoll EP ., J Exp Zool A Comp Exp Biol. December 1, 2003; 300 (2): 101-12.
Isolation and culture of micromeres and primary mesenchyme cells. , Wilt FH ., Methods Cell Biol. January 1, 2004; 74 273-85.
Commitment and response to inductive signals of primary mesenchyme cells of the sea urchin embryo. , Kiyomoto M ., Dev Growth Differ. February 1, 2004; 46 (1): 107-14.
A Raf/ MEK/ERK signaling pathway is required for development of the sea urchin embryo micromere lineage through phosphorylation of the transcription factor Ets. , Röttinger E., Development. March 1, 2004; 131 (5): 1075-87.
Focal adhesion kinase ( FAK) expression and phosphorylation in sea urchin embryos. , García MG., Gene Expr Patterns. March 1, 2004; 4 (2): 223-34.
PI3K inhibitors block skeletogenesis but not patterning in sea urchin embryos. , Bradham CA ., Dev Dyn. April 1, 2004; 229 (4): 713-21.
The 5-HT receptor cell is a new member of secondary mesenchyme cell descendants and forms a major blastocoelar network in sea urchin larvae. , Katow H., Mech Dev. April 1, 2004; 121 (4): 325-37.
Role of the ERK-mediated signaling pathway in mesenchyme formation and differentiation in the sea urchin embryo. , Fernandez-Serra M., Dev Biol. April 15, 2004; 268 (2): 384-402.
Nuclear beta- catenin-dependent Wnt8 signaling in vegetal cells of the early sea urchin embryo regulates gastrulation and differentiation of endoderm and mesodermal cell lineages. , Wikramanayake AH ., Genesis. July 1, 2004; 39 (3): 194-205.
SpHnf6, a transcription factor that executes multiple functions in sea urchin embryogenesis. , Otim O., Dev Biol. September 15, 2004; 273 (2): 226-43.
UVB radiation prevents skeleton growth and stimulates the expression of stress markers in sea urchin embryos. , Bonaventura R., Biochem Biophys Res Commun. March 4, 2005; 328 (1): 150-7.
P16 is an essential regulator of skeletogenesis in the sea urchin embryo. , Cheers MS., Dev Biol. July 15, 2005; 283 (2): 384-96.
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.
Molecular cytogenetic characterization of an ins(4;X) occurring as the sole abnormality in an aggressive, poorly differentiated soft tissue sarcoma. , Surace C., Virchows Arch. November 1, 2005; 447 (5): 869-74.
Endo16 is required for gastrulation in the sea urchin Lytechinus variegatus. , Romano LA ., Dev Growth Differ. October 1, 2006; 48 (8): 487-97.
Study of larval and adult skeletogenic cells in developing sea urchin larvae. , Yajima M ., Biol Bull. October 1, 2006; 211 (2): 183-92.
Phylogenetic correspondence of the body axes in bilaterians is revealed by the right-sided expression of Pitx genes in echinoderm larvae. , Hibino T., Dev Growth Differ. December 1, 2006; 48 (9): 587-95.
Regulatory sequences driving expression of the sea urchin Otp homeobox gene in oral ectoderm cells. , Cavalieri V., Gene Expr Patterns. January 1, 2007; 7 (1-2): 124-30.
Gene expression patterns in a novel animal appendage: the sea urchin pluteus arm. , Love AC., Evol Dev. January 1, 2007; 9 (1): 51-68.
Evolutionary modification of mesenchyme cells in sand dollars in the transition from indirect to direct development. , Yajima M ., Evol Dev. January 1, 2007; 9 (3): 257-66.
A global view of gene expression in lithium and zinc treated sea urchin embryos: new components of gene regulatory networks. , Poustka AJ., Genome Biol. January 1, 2007; 8 (5): R85.
The Snail repressor is required for PMC ingression in the sea urchin embryo. , Wu SY., Development. March 1, 2007; 134 (6): 1061-70.
Localized VEGF signaling from ectoderm to mesenchyme cells controls morphogenesis of the sea urchin embryo skeleton. , Duloquin L., Development. June 1, 2007; 134 (12): 2293-302.
A switch in the cellular basis of skeletogenesis in late-stage sea urchin larvae. , Yajima M ., Dev Biol. July 15, 2007; 307 (2): 272-81.
Gene regulatory networks and developmental plasticity in the early sea urchin embryo: alternative deployment of the skeletogenic gene regulatory network. , Ettensohn CA ., Development. September 1, 2007; 134 (17): 3077-87.
Skeletogenesis by transfated secondary mesenchyme cells is dependent on extracellular matrix- ectoderm interactions in Paracentrotus lividus sea urchin embryos. , Kiyomoto M ., Dev Growth Differ. December 1, 2007; 49 (9): 731-41.
Ingression of primary mesenchyme cells of the sea urchin embryo: a precisely timed epithelial mesenchymal transition. , Wu SY., Birth Defects Res C Embryo Today. December 1, 2007; 81 (4): 241-52.
FGF signals guide migration of mesenchymal cells, control skeletal morphogenesis [corrected] and regulate gastrulation during sea urchin development. , Röttinger E., Development. January 1, 2008; 135 (2): 353-65.
Mesenchymal cell fusion in the sea urchin embryo. , Hodor PG., Methods Mol Biol. January 1, 2008; 475 315-34.
Muscle formation during embryogenesis of the polychaete Ophryotrocha diadema (Dorvilleidae) - new insights into annelid muscle patterns. , Bergter A., Front Zool. January 2, 2008; 5 1.
Expression patterns of three Par-related genes in sea urchin embryos. , Shiomi K., Gene Expr Patterns. May 1, 2008; 8 (5): 323-30.
The dynamics of secretion during sea urchin embryonic skeleton formation. , Wilt FH ., Exp Cell Res. May 1, 2008; 314 (8): 1744-52.
Twist is an essential regulator of the skeletogenic gene regulatory network in the sea urchin embryo. , Wu SY., Dev Biol. July 15, 2008; 319 (2): 406-15.
Specification process of animal plate in the sea urchin embryo. , Sasaki H., Dev Growth Differ. September 1, 2008; 50 (7): 595-606.