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Human disease-associated extracellular matrix orthologs ECM3 and QBRICK regulate primary mesenchymal cell migration in sea urchin embryos. , Kiyozumi D., Exp Anim. August 6, 2021; 70 (3): 378-386.
Coup-TF: A maternal factor essential for differentiation along the embryonic axes in the sea urchin Paracentrotus lividus. , Tsironis I., Dev Biol. July 1, 2021; 475 131-144.
Na+/H+-exchangers differentially contribute to midgut fluid sodium and proton concentration in the sea urchin larva. , Petersen I., J Exp Biol. April 1, 2021; 224 (7):
A single cell RNA sequencing resource for early sea urchin development. , Foster S., Development. September 11, 2020; 147 (17):
pmar1/ phb homeobox genes and the evolution of the double-negative gate for endomesoderm specification in echinoderms. , Yamazaki A., Development. February 26, 2020; 147 (4):
Genetic manipulation of the pigment pathway in a sea urchin reveals distinct lineage commitment prior to metamorphosis in the bilateral to radial body plan transition. , Wessel GM ., Sci Rep. February 6, 2020; 10 (1): 1973.
Gastrulation in the sea urchin. , McClay DR ., Curr Top Dev Biol. January 1, 2020; 136 195-218.
A biphasic role of non-canonical Wnt16 signaling during early anterior-posterior patterning and morphogenesis of the sea urchin embryo. , Martínez-Bartolomé M ., Development. December 16, 2019; 146 (24):
MITF: an evolutionarily conserved transcription factor in the sea urchin Paracentrotus lividus. , Russo R., Genetica. December 1, 2019; 147 (5-6): 369-379.
Developmental Consequences of Temperature and Salinity Stress in the Sand Dollar Dendraster excentricus. , Abdel-Raheem ST., Biol Bull. December 1, 2019; 237 (3): 227-240.
Regeneration of the cell mass in larvae of temnopleurid sea urchins. , Kasahara M., J Exp Zool B Mol Dev Evol. November 1, 2019; 332 (7): 245-257.
The evolution of a new cell type was associated with competition for a signaling ligand. , Ettensohn CA ., PLoS Biol. September 18, 2019; 17 (9): e3000460.
Development and evolution of gut structures: from molecules to function. , Annunziata R., Cell Tissue Res. September 1, 2019; 377 (3): 445-458.
Evolutionary modification of AGS protein contributes to formation of micromeres in sea urchins. , Poon J., Nat Commun. August 22, 2019; 10 (1): 3779.
Altered actin cytoskeleton in ageing eggs of starfish affects fertilization process. , Limatola N., Exp Cell Res. August 15, 2019; 381 (2): 179-190.
Tipping points of gastric pH regulation and energetics in the sea urchin larva exposed to CO2 -induced seawater acidification. , Lee HG., Comp Biochem Physiol A Mol Integr Physiol. August 1, 2019; 234 87-97.
Sodium-mediated fast electrical depolarization does not prevent polyspermic fertilization in Paracentrotus lividus eggs. , Limatola N., Zygote. August 1, 2019; 27 (4): 241-249.
Cell rearrangement induced by filopodial tension accounts for the late phase of convergent extension in the sea urchin archenteron. , Hardin J., Mol Biol Cell. July 22, 2019; 30 (16): 1911-1919.
How Does the Regulatory Genome Work? , Istrail S., J Comput Biol. July 1, 2019; 26 (7): 685-695.
BMP controls dorsoventral and neural patterning in indirect-developing hemichordates providing insight into a possible origin of chordates. , Su YH ., Proc Natl Acad Sci U S A. June 25, 2019; 116 (26): 12925-12932.
Evolution of nitric oxide regulation of gut function. , Yaguchi J., Proc Natl Acad Sci U S A. March 19, 2019; 116 (12): 5607-5612.
Asymmetric division through a reduction of microtubule centering forces. , Sallé J., J Cell Biol. March 4, 2019; 218 (3): 771-782.
Effects of the fungicide ortho-phenylphenol (OPP) on the early development of sea urchin eggs. , Hosoya N., Mar Environ Res. January 1, 2019; 143 24-29.
Early development of the feeding larva of the sea urchin Heliocidaris tuberculata: role of the small micromeres. , Morris VB., Dev Genes Evol. January 1, 2019; 229 (1): 1-12.
Spatial and temporal patterns of gene expression during neurogenesis in the sea urchin Lytechinus variegatus. , Slota LA., Evodevo. January 1, 2019; 10 2.
Transcriptome analysis of regeneration during Xenopus laevis experimental twinning. , Sosa EA., Int J Dev Biol. January 1, 2019; 63 (6-7): 301-309.
Conserved regulatory state expression controlled by divergent developmental gene regulatory networks in echinoids. , Erkenbrack EM ., Development. December 18, 2018; 145 (24):
Meis transcription factor maintains the neurogenic ectoderm and regulates the anterior-posterior patterning in embryos of a sea urchin, Hemicentrotus pulcherrimus. , Yaguchi J., Dev Biol. December 1, 2018; 444 (1): 1-8.
Anteroposterior molecular registries in ectoderm of the echinus rudiment. , Adachi S., Dev Dyn. December 1, 2018; 247 (12): 1297-1307.
Evolutionarily conserved Tbx5-Wnt2/2b pathway orchestrates cardiopulmonary development. , Steimle JD., Proc Natl Acad Sci U S A. November 6, 2018; 115 (45): E10615-E10624.
The Lhx1-Ldb1 complex interacts with Furry to regulate microRNA expression during pronephric kidney development. , Espiritu EB., Sci Rep. October 30, 2018; 8 (1): 16029.
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.
Reiterative use of FGF signaling in mesoderm development during embryogenesis and metamorphosis in the hemichordate Ptychodera flava. , Fan TP., BMC Evol Biol. August 3, 2018; 18 (1): 120.
Embryonic neurogenesis in echinoderms. , Hinman VF ., Wiley Interdiscip Rev Dev Biol. July 1, 2018; 7 (4): e316.
Axial complex and associated structures of the sea urchin Strongylocentrotus pallidus (Sars, G.O. 1871) (Echinodermata: Echinoidea). , Ezhova OV., J Morphol. June 1, 2018; 279 (6): 792-808.
Cdc42 controls primary mesenchyme cell morphogenesis in the sea urchin embryo. , Sepúlveda-Ramírez SP., Dev Biol. May 15, 2018; 437 (2): 140-151.
Effects of Nodal inhibition on development of temnopleurid sea urchins. , Kasahara M., Evol Dev. May 1, 2018; 20 (3-4): 91-99.
Transforming growth factor-β signal regulates gut bending in the sea urchin embryo. , Suzuki H., Dev Growth Differ. May 1, 2018; 60 (4): 216-225.
The evolutionary origin of chordate segmentation: revisiting the enterocoel theory. , Onai T., Theory Biosci. April 1, 2018; 137 (1): 1-16.
RNA helicase Mov10 is essential for gastrulation and central nervous system development. , Skariah G., Dev Dyn. April 1, 2018; 247 (4): 660-671.
A novel gene''s role in an ancient mechanism: secreted Frizzled-related protein 1 is a critical component in the anterior-posterior Wnt signaling network that governs the establishment of the anterior neuroectoderm in sea urchin embryos. , Khadka A., Evodevo. January 22, 2018; 9 1.
SoxB2 in sea urchin development: implications in neurogenesis, ciliogenesis and skeletal patterning. , Anishchenko E., Evodevo. January 22, 2018; 9 5.
The Enigmatic Genome of an Obligate Ancient Spiroplasma Symbiont in a Hadal Holothurian. , He LS., Appl Environ Microbiol. January 1, 2018; 84 (1):
Notch-mediated lateral inhibition is an evolutionarily conserved mechanism patterning the ectoderm in echinoids. , Erkenbrack EM ., Dev Genes Evol. January 1, 2018; 228 (1): 1-11.
Toward Multiscale Modeling of Molecular and Biochemical Events Occurring at Fertilization Time in Sea Urchins. , Moundoyi H., Results Probl Cell Differ. January 1, 2018; 65 69-89.
Neuropeptidergic Systems in Pluteus Larvae of the Sea Urchin Strongylocentrotus purpuratus: Neurochemical Complexity in a "Simple" Nervous System. , Wood NJ., Front Endocrinol (Lausanne). January 1, 2018; 9 628.
New Neuronal Subtypes With a "Pre-Pancreatic" Signature in the Sea Urchin Stongylocentrotus purpuratus. , Perillo M ., Front Endocrinol (Lausanne). January 1, 2018; 9 650.
New insights from a high-resolution look at gastrulation in the sea urchin, Lytechinus variegatus. , Martik ML., Mech Dev. December 1, 2017; 148 3-10.
Evolutionary recruitment of flexible Esrp-dependent splicing programs into diverse embryonic morphogenetic processes. , Burguera D., Nat Commun. November 27, 2017; 8 (1): 1799.
Notch signaling patterns neurogenic ectoderm and regulates the asymmetric division of neural progenitors in sea urchin embryos. , Mellott DO., Development. October 1, 2017; 144 (19): 3602-3611.