Dual Appearances of Pigment Cells from In Vitro Cultured Embryonic Cells of Japanese Flounder: An Implication for a Differentiation–Associated Clock

The cells dissociated from developing embryos of Japanese flounder (Paralichthys olivaceus) are cultured in vitro to examine the developmental fate of their pigment cells in relation to establishment of bilaterally asymmetric integumental coloration in vivo. When neurula embryos are dissociated using trypsin–EDTA in Dulbecco's modified Ca²⁺–, Mg²⁺–free phosphate buffered saline and then cultured in vitro using L–15–based fetal calf serum–supplemented growth medium at 20°C, numerous pigment cells appear twice in the same culture with an interval of approximately 1 month even under similar culture conditions. The first group of pigment cells, which is relatively larger in cell size (about 70 μm wide) and lower in cell density, emerges within 12 hr after plating, whereas the second, which is far smaller in cell size (about 30 μm) and overwhelmingly higher in cell density than the first, does so about 1 month after plating. The timing of their appearances in vitro is in good accordance, respectively, with that observed for the larvae under normal development in vivo; the first group appears at the period corresponding to hatching, whereas the second at the period corresponding to the completion of metamorphosis. Light microscopic examinations disclose that each group of pigment cells is composed of black melanophores and reflecting leucophores, and that the population density of melanophores and leucophores in the first group at the climax of appearance is approximated as 1:4. Typical xanthophores that are distributed in the skin of the larvae of this species are scarcely observed in culture in vitro. Because of their dual synchronous appearances with about 1 month interval under the similar culture conditions, and because of their low proliferative activity during the periods from the first appearance to the second, it is presumed that both groups of pigment cells are installed with a clock set differently for their differentiation. Light and electron microscopic immunocytochemistry on cultured cells using the HNK–I antibody, which marks avian migratory neural crest cells, both disclose that the antibody cross–reacts with all these pigment cells, and that a certain number of immunoreactive unpigmented cells exist even at the time of the second appearance of pigment cells. These findings would imply that the second group of pigment cells served in a form of undifferentiated propigment cells up to metamorphosis, at which they start to differentiate under control of a clock presumably set during neurulation.