CA2-ACTIVATED [CA2+](I) OSCILLATIONS IN AN EXOCRINE CELL( INFLUX DRIVES AGONIST)

In current models describing agonist-induced oscillations in [Ca2+](i) , Ca2+ entry is generally assumed to have a simple sustaining role, re plenishing Ca2+ lost from the cell and recharging intracellular Ca2+ s tores. In cells from the avian nasal gland, a model exocrine cell, we show that inhibition of Ca2+ entry by La3+ SK&F 96365, or by membrane depolarization, rapidly blocks [Ca2+](i) oscillations but does so with out detectible depletion of agonist-sensitive Ca2+ stores. As the rate of Mn2+ quenching during [Ca2+](i) oscillations is constant, Ca2+ ent ry is not directly contributing to the [Ca2+](i) changes and, instead, appears to be involved in inducing the repetitive release of Ca2+ fro m internal stores. Together, these data contradict current models in t hat (i) at the low agonist concentrations where [Ca2+](i) oscillations are seen, generated levels of Ins(1,4,5)P-3 are themselves inadequate to result in a regenerative [Ca2+](i) signal, and (ii) Ca2+ entry is necessary to actually drive the intrinsic oscillatory mechanism.