Synthesis of prostaglandins and cyclic AMP by cultured embryonic palate mesenchyme at various population densities.

During embryonic development, facial and palate mesenchymal cells exhibit differential growth rates. Normal palatal growth is regulated in part by hormones and growth factors. Because hormonal responsiveness of some cells correlates with their cell density, we have investigated the relationship between embryonic palate mesenchymal cell population density and their ability to synthesize prostaglandins (PGs) and cyclic AMP. Primary cultures of palate mesenchymal cells exhibited typical lag, log, and stationary phases of growth with a doubling time of 32-34 hrs. The ability of cells to produce PGE2 in response to a calcium ionophore (A23187), an activator of phospholipase A2 (melittin), arachidonic acid, or serum was maximal during the period of early exponential growth. Prostaglandin F2 alpha synthesis in response to A23187 or arachidonic acid showed a similar transient increase also corresponding temporally to the period of early exponential growth. The ability to synthesize PGF2 alpha in response to melittin, however, failed to diminish after early exponential growth. The pattern of cAMP synthesis in response to isoproterenol and PGE1 was different from that seen for induced prostaglandin synthesis. A transient increase in sensitivity to isoproterenol and PGE1 was seen that corresponded temporally to the period of late exponential growth just prior to attainment of confluency. Decreased sensitivity to stimulation of either prostaglandin or cAMP production as the cells became confluent was shown to be a density-dependent phenomenon; confluent cultures that were subcultured to reestablish logarithmic growth exhibited density-dependent hormonal responses identical to those seen in primary cultures. The ability of palate mesenchymal cells to synthesize both prostaglandins and cAMP, thought to be critical for proper palatal development, might thus be related to local differential craniofacial growth rates.