This is the first thorough study of refilling of a cortical calcium store in a secretory cell after stimulation in which we combined widely different methodologies. Stimulation of dense-core vesicle ("trichocysts") exocytosis in Paramecium involves a Ca(2+) -influx" superimposed to Ca(2+) -release from cortical stores ("alveolar sacs" (ASs)). In quenched-flow experiments, membrane fusion frequency rose with increasing [Ca(2+)](o) in the medium, from approximately 20-25% at [Ca(2+)](o) < or = 0.25 microM to 100% at [Ca(2+)](o) between 2 and 10 microM, i.e. close to the range of estimated local intracellular [Ca(2+)] during membrane fusion. Next, we analyzed Ca(2+)-specific fluorochrome signals during stimulation under different conditions. Treatment with actin-reactive drugs had no effect on Ca(2+) -signaling. In double trigger experiments, with BAPTA in the second secretagogue application (BAPTA only for stimulation and analysis), the cortical Ca(2+) -signal (due solely to Ca(2+) released from cortical stores) recovered with t(1/2) approximately 65 min. When ASs were analyzed in situ by X-ray microanalysis after different trigger times (+Ca(2+)(o)), t(1/2) for store refilling was similar, approximately 60 min. These values are similar to previously measured 45Ca(2+) -uptake by isolated ASs. In sum we find, (i) exogenous Ca(2+) increases exocytosis/membrane fusion performance with EC(50)=0.7 microM, (ii) Ca(2+) -signaling in this system is not sensitive to actin-reactive drugs, and (iii) refilling of these cortical calcium stores goes on over hours and thus is much slower than expected.