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Evolutionary modification of AGS protein contributes to formation of micromeres in sea urchins. , Poon J., Nat Commun. August 22, 2019; 10 (1): 3779.
Asymmetric division through a reduction of microtubule centering forces. , Sallé J., J Cell Biol. March 4, 2019; 218 (3): 771-782.
Resistance is futile: Centering forces yield for asymmetric cell division. , Alper J., J Cell Biol. March 4, 2019; 218 (3): 727-728.
Actin-Network Architecture Regulates Microtubule Dynamics. , Colin A., Curr Biol. August 20, 2018; 28 (16): 2647-2656.e4.
Physical Forces Determining the Persistency and Centering Precision of Microtubule Asters. , Tanimoto H., Nat Phys. August 1, 2018; 14 (8): 848-854.
Aurora A activation in mitosis promoted by BuGZ. , Huang Y., J Cell Biol. January 2, 2018; 217 (1): 107-116.
Quantitative approaches for the study of microtubule aster motion in large eggs. , Tanimoto H., Methods Cell Biol. January 1, 2017; 139 69-80.
Using sea urchin gametes and zygotes to investigate centrosome duplication. , Sluder G., Cilia. September 6, 2016; 5 (1): 20.
[Oligopeptides in plant medicines cited in Chinese Pharmacopoeia]. , Su L., Zhongguo Zhong Yao Za Zhi. August 1, 2016; 41 (16): 2943-2952.
Mother centrioles are kicked out so that starfish zygote can grow. , Verlhac MH., J Cell Biol. March 28, 2016; 212 (7): 759-61.
Shape-motion relationships of centering microtubule asters. , Tanimoto H., J Cell Biol. March 28, 2016; 212 (7): 777-87.
Activator-inhibitor coupling between Rho signalling and actin assembly makes the cell cortex an excitable medium. , Bement WM., Nat Cell Biol. November 1, 2015; 17 (11): 1471-83.
The effect of taxol microinjection on the microtubular structure in polar body formation of starfish oocytes. , Kikuchi Y., Cytoskeleton (Hoboken). February 1, 2012; 69 (2): 125-32.
Action at a distance during cytokinesis. , von Dassow G., J Cell Biol. December 14, 2009; 187 (6): 831-45.
Cyclin B- cdk1 controls pronuclear union in interphase. , Tachibana K., Curr Biol. September 9, 2008; 18 (17): 1308-13.
Bipolar, anastral spindle development in artificially activated sea urchin eggs. , Henson JH ., Dev Dyn. May 1, 2008; 237 (5): 1348-58.
[Quantity of functionally changed cells as an identificator of the moment of the organizmus transfer to the next period of development]. , Shabalkin IP., Tsitologiia. January 1, 2007; 49 (1): 21-5.
Determination of first cleavage plane: the relationships between the orientation of the mitotic apparatus for first cleavage and the position of meiotic division-related structures in starfish eggs. , Kitajima A., Dev Biol. April 1, 2005; 280 (1): 48-58.
The cleavage plane will bend when one aster of the mitotic apparatus stops growing in compressed sea urchin eggs. , Yoshigaki T., Bull Math Biol. July 1, 2002; 64 (4): 643-72.
Displacement of the mitotic apparatus which induces ectopic polar body formation or parthenogenetic cleavage in starfish oocytes. , Hamaguchi Y., Dev Biol. November 15, 2001; 239 (2): 364-75.
Measurement of the intracellular pH threshold for sperm aster formation in sea urchin eggs. , Hamaguchi MS., Dev Growth Differ. August 1, 2001; 43 (4): 447-58.
MAP kinase, a universal suppressor of sperm centrosomes during meiosis? , Stephano JL., Dev Biol. June 15, 2000; 222 (2): 420-8.
Premeiotic aster as a device to anchor the germinal vesicle to the cell surface of the presumptive animal pole in starfish oocytes. , Miyazaki A., Dev Biol. February 15, 2000; 218 (2): 161-71.
Parameters that specify the timing of cytokinesis. , Shuster CB ., J Cell Biol. September 6, 1999; 146 (5): 981-92.
Aster-forming abilities of the egg, polar body, and sperm centrosomes in early starfish development. , Saiki T., Dev Biol. November 1, 1998; 203 (1): 62-74.
Effect of wortmannin, an inhibitor of phosphatidylinositol 3-kinase, on the first mitotic divisions of the fertilized sea urchin egg. , De Nadai C., J Cell Sci. September 1, 1998; 111 ( Pt 17) 2507-18.
A cytoplasmic dynein required for mitotic aster formation in vivo. , Inoue S., J Cell Sci. September 1, 1998; 111 ( Pt 17) 2607-14.
Caulerpenyne interferes with microtubule-dependent events during the first mitotic cycle of sea urchin eggs. , Pesando D., Eur J Cell Biol. September 1, 1998; 77 (1): 19-26.
Role of fungal dynein in hyphal growth, microtubule organization, spindle pole body motility and nuclear migration. , Inoue S., J Cell Sci. June 1, 1998; 111 ( Pt 11) 1555-66.
The coordination of centrosome reproduction with nuclear events of the cell cycle in the sea urchin zygote. , Hinchcliffe EH., J Cell Biol. March 23, 1998; 140 (6): 1417-26.
Recruitment of maternal material during assembly of the zygote centrosome in fertilized sea urchin eggs. , Holy J., Cell Tissue Res. August 1, 1997; 289 (2): 285-97.
Excision and disassembly of sperm tail microtubules during sea urchin fertilization: requirements for microtubule dynamics. , Fechter J., Cell Motil Cytoskeleton. January 1, 1996; 35 (4): 281-8.
Nuclear envelope breakdown is under nuclear not cytoplasmic control in sea urchin zygotes. , Sluder G., J Cell Biol. June 1, 1995; 129 (6): 1447-58.
Cyclin B interaction with microtubule-associated protein 4 (MAP4) targets p34cdc2 kinase to microtubules and is a potential regulator of M-phase microtubule dynamics. , Ookata K., J Cell Biol. March 1, 1995; 128 (5): 849-62.
Protein tyrosine phosphorylation during sea urchin fertilization: microtubule dynamics require tyrosine kinase activity. , Wright SJ., Cell Motil Cytoskeleton. January 1, 1995; 30 (2): 122-35.
Cleavage in conical sand dollar eggs. , Rappaport R., Dev Biol. July 1, 1994; 164 (1): 258-66.
Dithiothreitol prevents membrane fusion but not centrosome or microtubule organization during the first cell cycles in sea urchins. , Schatten H ., Cell Motil Cytoskeleton. January 1, 1994; 27 (1): 59-68.
The late events of fertilisation in the penaeoidean shrimp Sicyonia ingentis. , Hertzler PL., Zygote. November 1, 1993; 1 (4): 287-96.
Calyculin A induces contractile ring-like apparatus formation and condensation of chromosomes in unfertilized sea urchin eggs. , Tosuji H., Proc Natl Acad Sci U S A. November 15, 1992; 89 (22): 10613-7.
Mitotic apparatus formation and cleavage induction by micromanipulation of the nucleus and centrosome: the centrosome forms a spindle together with only the chromosomes at a short distance. , Saiki T., Exp Cell Res. October 1, 1992; 202 (2): 450-7.
Conditions for assembly of tubulin-based structures in unfertilized sea urchin eggs. Spirals, monasters and cytasters. , Harris PJ., J Cell Sci. July 1, 1992; 102 ( Pt 3) 557-67.
Activation of maternal centrosomes in unfertilized sea urchin eggs. , Schatten H ., Cell Motil Cytoskeleton. January 1, 1992; 23 (1): 61-70.
Organelle motility within mitotic asters of the fungus Nectria haematococca. , Aist JR., Eur J Cell Biol. December 1, 1991; 56 (2): 358-63.
Organization of the sea urchin egg endoplasmic reticulum and its reorganization at fertilization. , Terasaki M ., J Cell Biol. September 1, 1991; 114 (5): 929-40.
Effects of 6-dimethylaminopurine on microtubules and putative intermediate filaments in sea urchin embryos. , Dufresne L., J Cell Sci. August 1, 1991; 99 ( Pt 4) 721-30.
Multipolar mitosis in procaine-treated polyspermic sea urchin eggs and in eggs fertilized with UV-irradiated spermatozoa with a computer model to simulate the positioning of centrosomes. , Czihak G., Eur J Cell Biol. August 1, 1991; 55 (2): 255-61.
Differential behavior of centrosomes in unequally dividing blastomeres during fourth cleavage of sea urchin embryos. , Holy J., J Cell Sci. March 1, 1991; 98 ( Pt 3) 423-31.
Protein synthesis and the cell cycle: centrosome reproduction in sea urchin eggs is not under translational control. , Sluder G., J Cell Biol. June 1, 1990; 110 (6): 2025-32.
Calcium in mitosis: role of 51-kD protein in the centrosome of sea urchin egg in aster formation. , Sakai H., Adv Exp Med Biol. January 1, 1989; 255 471-80.
Germinal vesicle components are not required for the cell-cycle oscillator of the early starfish embryo. , Picard A., Dev Biol. July 1, 1988; 128 (1): 121-8.