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Pluripotency and the origin of animal multicellularity. , Sogabe S., Nature. June 1, 2019; 570 (7762): 519-522.
Taxon-specific expansion and loss of tektins inform metazoan ciliary diversity. , Bastin BR., BMC Evol Biol. January 31, 2019; 19 (1): 40.
The complex simplicity of the brittle star nervous system. , Zueva O ., Front Zool. February 1, 2018; 15 1.
Regeneration of the digestive system in the crinoid Himerometra robustipinna occurs by transdifferentiation of neurosecretory-like cells. , Kalacheva NV., PLoS One. January 1, 2017; 12 (7): e0182001.
Distinct mechanisms eliminate mother and daughter centrioles in meiosis of starfish oocytes. , Borrego-Pinto J., J Cell Biol. March 28, 2016; 212 (7): 815-27.
Functional Morphology of the Arm Spine Joint and Adjacent Structures of the Brittlestar Ophiocomina nigra (Echinodermata: Ophiuroidea). , Wilkie IC., PLoS One. January 1, 2016; 11 (12): e0167533.
Eph- Ephrin signaling and focal adhesion kinase regulate actomyosin-dependent apical constriction of ciliary band cells. , Krupke OA., Development. March 1, 2014; 141 (5): 1075-84.
A detailed description of the development of the hemichordate Saccoglossus kowalevskii using SEM, TEM, Histology and 3D-reconstructions. , Kaul-Strehlow S., Front Zool. September 6, 2013; 10 (1): 53.
Glutathione transferase theta in apical ciliary tuft regulates mechanical reception and swimming behavior of Sea Urchin Embryos. , Jin Y., Cytoskeleton (Hoboken). August 1, 2013; 70 (8): 453-70.
Evolution of a novel muscle design in sea urchins (Echinodermata: Echinoidea). , Ziegler A., PLoS One. January 1, 2012; 7 (5): e37520.
Atypical protein kinase C controls sea urchin ciliogenesis. , Prulière G., Mol Biol Cell. June 15, 2011; 22 (12): 2042-53.
Comparative morphology of the axial complex and interdependence of internal organ systems in sea urchins (Echinodermata: Echinoidea). , Ziegler A., Front Zool. June 9, 2009; 6 10.
Mechanism of transport of IFT particles in C. elegans cilia by the concerted action of kinesin-II and OSM-3 motors. , Pan X., J Cell Biol. September 25, 2006; 174 (7): 1035-45.
Testing the geometric clutch hypothesis. , Lindemann CB., Biol Cell. December 1, 2004; 96 (9): 681-90.
Polycystins: what polycystic kidney disease tells us about sperm. , Kierszenbaum AL., Mol Reprod Dev. April 1, 2004; 67 (4): 385-8.
Ciliary protein turnover continues in the presence of inhibitors of golgi function: evidence for membrane protein pools and unconventional intracellular membrane dynamics. , Stephens RE ., J Exp Zool. May 1, 2001; 289 (6): 335-49.
Photoreceptor localization of the KIF3A and KIF3B subunits of the heterotrimeric microtubule motor kinesin II in vertebrate retina. , Whitehead JL., Exp Eye Res. November 1, 1999; 69 (5): 491-503.
Chloral hydrate alters the organization of the ciliary basal apparatus and cell organelles in sea urchin embryos. , Chakrabarti A., Cell Tissue Res. September 1, 1998; 293 (3): 453-62.
Heterotrimeric kinesin-II is required for the assembly of motile 9+2 ciliary axonemes on sea urchin embryos. , Morris RL ., J Cell Biol. September 8, 1997; 138 (5): 1009-22.
Displacement of gold marker in immunoelectron microscopy of human respiratory cilia. , Umeda A., Microsc Res Tech. September 1, 1997; 38 (5): 500-4.
Spatial expression of alpha and beta tubulin genes in the late embryogenesis of the sea urchin Paracentrotus lividus. , Casano C., Int J Dev Biol. October 1, 1996; 40 (5): 1033-41.
Ciliogenesis in sea urchin embryos--a subroutine in the program of development. , Stephens RE ., Bioessays. April 1, 1995; 17 (4): 331-40.
Tubulin and tektin in sea urchin embryonic cilia: pathways of protein incorporation during turnover and regeneration. , Stephens RE ., J Cell Sci. February 1, 1994; 107 ( Pt 2) 683-92.
The microvilli and hyaline layer of embryonic asteroid epithelial collar cells: a sensory structure to determine the position of locomotory cilia? , Crawford BJ., Anat Rec. August 1, 1993; 236 (4): 697-709.
Organization of the ciliary basal apparatus in embryonic cells of the sea urchin, Lytechinus pictus. , Anstrom JA., Cell Tissue Res. August 1, 1992; 269 (2): 305-13.
Ultrastructure of the tube-foot of an ophiuroid echinoderm, Hemipholis elongata. , Hajduk SL., Tissue Cell. January 1, 1992; 24 (1): 111-9.
Cytology and function of the madreporite systems of the starfish Henricia Sanguinolenta and Asterias Vulgaris. , Ferguson JC., J Morphol. October 1, 1991; 210 (1): 1-11.
Localization of the sea urchin Spec3 protein to cilia and Golgi complexes of embryonic ectoderm cells. , Eldon ED., Genes Dev. January 1, 1990; 4 (1): 111-22.
Retention of ciliary ninefold structure after removal of microtubules. , Stephens RE ., J Cell Sci. March 1, 1989; 92 ( Pt 3) 391-402.
Coordinate and selective beta- tubulin gene expression associated with cilium formation in sea urchin embryos. , Harlow P., Genes Dev. December 1, 1987; 1 (10): 1293-304.
Stimulation of tubulin gene transcription by deciliation of sea urchin embryos. , Gong ZY., Mol Cell Biol. December 1, 1987; 7 (12): 4238-46.
Comparative studies on receptor structure in the brittlestar Ophiura ophiura. , Cobb JL., J Neurocytol. February 1, 1986; 15 (1): 97-108.
Association of anti- dynein-1 cross-reactive antigen with the mitotic spindle of mammalian cells. , Yoshida T., Cell Struct Funct. September 1, 1985; 10 (3): 245-58.
Rudimentary cilia in muscle cells of annelids and echinoderms. , Gardiner SL., Cell Tissue Res. January 1, 1980; 213 (2): 247-52.
Kinetics of the regeneration of sea-urchin cilia. II. Regeneration of animalized cilia. , Burns RG., J Cell Sci. June 1, 1979; 37 205-15.
An ultra-structural study of the gills of Echinus esculentus. , Cobb JL., Cell Tissue Res. August 9, 1977; 182 (2): 265-74.
Nucleated sites for the assembly of cytoplasmic microtubules in the ectodermal cells of blastulae of Arbacia punctulata. , Tilney LG., J Cell Biol. September 1, 1970; 46 (3): 564-75.
Microtubules in the formation and development of the primary mesenchyme in Arbacia punctulata. I. The distribution of microtubules. , Gibbins JR., J Cell Biol. April 1, 1969; 41 (1): 201-26.