Abstract
It has been shown that isolation of sea urchin blastomeres before the post-division adhesion leads mainly to the formation of equal blastomeres at the stage of 4th cleavage division, whereas isolation after adhesion results in the formation of micromeres simultaneous with that in intact embryos. Similar results were obtained in five sea urchin species. It has been concluded that there exists a critical point in the cleavage process, when blastomeres exchange information that determines the further cleavage pattern. It has been shown with this “micromere model” that serotonin and its analogs influence the cleavage pattern of half-embryos. These data have served as a basis for the hypothesis of “protosynapse,” a bilaterally symmetric structure in which the blastomeres are not only source and target of the signal but also a passive obstacle to leakage of the signal substance from the interblastomere cleft to the milieu. Such a structure may also specify the primary asymmetry of the blastomeres. The micromere model may be useful in specific pharmacological screening.
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Original Russian Text © Yu.B. Shmukler, 2010, published in Biofizika, 2010, Vol. 55, No. 3, pp. 451–459.
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Shmukler, Y.B. A “micromere model” of cell-cell interactions in sea urchin early embryos. BIOPHYSICS 55, 399–405 (2010). https://doi.org/10.1134/S0006350910030085
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DOI: https://doi.org/10.1134/S0006350910030085