Diffusion Barriers Limit the Effect of Mobile Calcium Buffers on Exocytosis of Large Dense Cored Vesicles

Abstract

Fast exocytosis in melanotropic cells, activated by calcium entry through voltage-gated calcium channels, is very sensitive to mobile calcium buffers (complete block at 800 μM ethylene glycol bis( β-aminoethyl ether)- N, N, N′N′-tetraacetic acid (EGTA)). This indicates that calcium diffuses a substantial distance from the channel to the vesicle. Surprisingly, 1,2-bis(2-aminophenoxy)ethane- N,N,N′,N′-tetraacetic acid (BAPTA), having a similar K D for calcium as EGTA but a ∼100 times faster binding rate, blocked exocytosis only twice as effectively as EGTA. Using computer simulations, we demonstrate that this result cannot be explained by free diffusion and buffer binding rates. We hypothesized that local saturation of calcium buffers is involved. A diffusion barrier for both calcium and buffer molecules, located 50–300 nm from the membrane and reducing diffusion 1000 to 10,000 times, generated similar calcium concentrations for specific concentrations of EGTA and BAPTA. With such barriers, calcium rise phase kinetics upon short step depolarizations (2–20 ms) were faster for EGTA than for BAPTA, implying that short depolarizations should allow exocytosis with 50 μM EGTA but not with 25 μM BAPTA. This prediction was confirmed experimentally with capacitance measurements. Coupling exocytosis to calcium dynamics in the model, we found that a barrier with a ∼3000 times reduced diffusion at ∼130 nm beneath the membrane best explains the experimentally observed effects of EGTA and BAPTA on block and kinetics of release.