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Expression of S9 and actin CyIIa mRNAs reveals dorso-ventral polarity and mesodermal sublineages in the vegetal plate of the sea urchin embryo. , Miller RN., Mech Dev. November 1, 1996; 60 (1): 3-12.
Cloning and characterization of novel beta integrin subunits from a sea urchin. , Marsden M., Dev Biol. January 15, 1997; 181 (2): 234-45.
Histological distribution of FR-1, a cyclic RGDS-peptide, binding sites during early embryogenesis, and isolation and initial characterization of FR-1 receptor in the sand dollar embryo. , Katow H., Dev Growth Differ. April 1, 1997; 39 (2): 207-19.
Ultrastructure and synthesis of the extracellular matrix of Pisaster ochraceus embryos preserved by freeze substitution. , Crawford BJ., J Morphol. May 1, 1997; 232 (2): 133-53.
Skeletal morphogenesis in the sea urchin embryo: regulation of primary mesenchyme gene expression and skeletal rod growth by ectoderm-derived cues. , Guss KA., Development. May 1, 1997; 124 (10): 1899-908.
Isolation and characterization of an endodermally derived, proteoglycan-like extracellular matrix molecule that may be involved in larval starfish digestive tract morphogenesis. , Reimer CL., Dev Growth Differ. June 1, 1997; 39 (3): 381-97.
Looking into the sea urchin embryo you can see local cell interactions regulate morphogenesis. , Wilt FH ., Bioessays. August 1, 1997; 19 (8): 665-8.
A presumptive developmental role for a sea urchin cyclin B splice variant. , Lozano JC., J Cell Biol. January 26, 1998; 140 (2): 283-93.
Matrix metalloproteinase inhibitors disrupt spicule formation by primary mesenchyme cells in the sea urchin embryo. , Ingersoll EP ., Dev Biol. April 1, 1998; 196 (1): 95-106.
Accessing the embryo interior without microinjection. , Latham VH., Acta Histochem. April 1, 1998; 100 (2): 193-200.
Ectoderm cell--ECM interaction is essential for sea urchin embryo skeletogenesis. , Zito F., Dev Biol. April 15, 1998; 196 (2): 184-92.
The dynamics and regulation of mesenchymal cell fusion in the sea urchin embryo. , Hodor PG., Dev Biol. July 1, 1998; 199 (1): 111-24.
Characterization of Involution during Sea Urchin Gastrulation Using Two-Photon Excited Photorelease and Confocal Microscopy. , Piston DW., Microsc Microanal. July 1, 1998; 4 (4): 404-414.
Disruption of primary mesenchyme cell patterning by misregulated ectodermal expression of SpMsx in sea urchin embryos. , Tan H., Dev Biol. September 15, 1998; 201 (2): 230-46.
The betaL integrin subunit is necessary for gastrulation in sea urchin embryos. , Marsden M., Dev Biol. November 1, 1998; 203 (1): 134-48.
Matrix and mineral in the sea urchin larval skeleton. , Wilt FH ., J Struct Biol. June 30, 1999; 126 (3): 216-26.
A putative role for carbohydrates in sea urchin gastrulation. , Latham VH., Acta Histochem. July 1, 1999; 101 (3): 293-303.
A method of microinjection: delivering monoclonal antibody 1223 into sea urchin embryos. , Cho JW., Mol Cells. August 31, 1999; 9 (4): 455-8.
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.
Syntaxin, VAMP, and Rab3 are selectively expressed during sea urchin embryogenesis. , Conner SD., Mol Reprod Dev. January 1, 2001; 58 (1): 22-9.
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.
In situ screening for genes expressed preferentially in secondary mesenchyme cells of sea urchin embryos. , Shoguchi E., Dev Genes Evol. October 1, 2002; 212 (9): 407-18.
Primary mesenchyme cell patterning during the early stages following ingression. , Peterson RE., Dev Biol. February 1, 2003; 254 (1): 68-78.
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.
Expression of univin, a TGF-beta growth factor, requires ectoderm-ECM interaction and promotes skeletal growth in the sea urchin embryo. , Zito F., Dev Biol. December 1, 2003; 264 (1): 217-27.
Carbohydrate involvement in cellular interactions in sea urchin gastrulation. , Khurrum M., Acta Histochem. January 1, 2004; 106 (2): 97-106.
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.
Behavior of pigment cells closely correlates the manner of gastrulation in sea urchin embryos. , Takata H., Zoolog Sci. October 1, 2004; 21 (10): 1025-35.
A novel approach to study adhesion mechanisms by isolation of the interacting system. , Coyle-Thompson C., Acta Histochem. January 1, 2005; 107 (4): 243-51.
PM-2: an ECM epitope necessary for morphogenesis in embryos of the starfish, Pisaster ochraceus. , Maghsoodi B., J Morphol. March 1, 2005; 263 (3): 310-21.
Viviparity in the sea star Cryptasterina hystera (Asterinidae)--conserved and modified features in reproduction and development. , Byrne M ., Biol Bull. April 1, 2005; 208 (2): 81-91.
Study of larval and adult skeletogenic cells in developing sea urchin larvae. , Yajima M ., Biol Bull. October 1, 2006; 211 (2): 183-92.
Gene expression patterns in a novel animal appendage: the sea urchin pluteus arm. , Love AC., Evol Dev. January 1, 2007; 9 (1): 51-68.
Serotonin stimulates [Ca2+]i elevation in ciliary ectodermal cells of echinoplutei through a serotonin receptor cell network in the blastocoel. , Katow H., J Exp Biol. February 1, 2007; 210 (Pt 3): 403-12.
Microplate assay for quantifying developmental morphologies: effects of exogenous hyalin on sea urchin gastrulation. , Razinia Z., Zygote. May 1, 2007; 15 (2): 159-64.
Transplantation of Xenopus laevis Lens Ectoderm. , Sive HL ., CSH Protoc. June 1, 2007; 2007 pdb.prot4751.
Xenopus laevis Einstecks. , Sive HL ., CSH Protoc. June 1, 2007; 2007 pdb.prot4750.
Hyalin is a cell adhesion molecule involved in mediating archenteron- blastocoel roof attachment. , Carroll EJ ., Acta Histochem. January 1, 2008; 110 (4): 265-75.
Exogenous hyalin and sea urchin gastrulation, Part II: hyalin, an interspecies cell adhesion molecule. , Alvarez M., Zygote. February 1, 2008; 16 (1): 73-8.
Exogenous hyalin and sea urchin gastrulation. Part III: biological activity of hyalin isolated from Lytechinus pictus embryos. , Contreras A., Zygote. November 1, 2008; 16 (4): 355-61.
The major yolk protein is synthesized in the digestive tract and secreted into the body cavities in sea urchin larvae. , Unuma T., Mol Reprod Dev. February 1, 2009; 76 (2): 142-50.
Defense system by mesenchyme cells in bipinnaria larvae of the starfish, Asterina pectinifera. , Furukawa R., Dev Comp Immunol. February 1, 2009; 33 (2): 205-15.
Gene regulatory network interactions in sea urchin endomesoderm induction. , Sethi AJ., PLoS Biol. February 3, 2009; 7 (2): e1000029.
Spatiotemporal distribution patterns of oligosaccharides during early embryogenesis in the starfish Patiria pectinifera. , Doihara T., Dev Genes Evol. April 1, 2009; 219 (4): 199-206.
Exogenous hyalin and sea urchin gastrulation. Part IV: a direct adhesion assay - progress in identifying hyalin''s active sites. , Ghazarian H., Zygote. February 1, 2010; 18 (1): 17-26.
Embryonic, larval, and juvenile development of the sea biscuit Clypeaster subdepressus (Echinodermata: Clypeasteroida). , Vellutini BC., PLoS One. March 22, 2010; 5 (3): e9654.
Wavefront image sensor chip. , Cui X., Opt Express. August 2, 2010; 18 (16): 16685-701.
Developmental expression of COE across the Metazoa supports a conserved role in neuronal cell-type specification and mesodermal development. , Jackson DJ., Dev Genes Evol. December 1, 2010; 220 (7-8): 221-34.