Producción CientíficaWe have investigated the dynamics of the free
[Ca2+] inside the secretory granules of neurosecretory PC12
and INS1 cells using a low-Ca2+-affinity aequorin chimera
fused to synaptobrevin-2. The steady-state secretory granule
[Ca2+] ([Ca2+]SG] was around 20–40 lM in both cell types,
about half the values previously found in chromaffin cells.
Inhibition of SERCA-type Ca2+ pumps with thapsigargin
largely blocked Ca2+ uptake by the granules in
Ca2+-depleted permeabilized cells, and the same effect was
obtained when the perfusion medium lacked ATP. Consistently,
the SERCA-type Ca2+ pump inhibitor benzohydroquinone
induced a rapid release of Ca2+ from the granules
both in intact and permeabilized cells, suggesting that the
continuous activity of SERCA-type Ca2+ pumps is essential
to maintain the steady-state [Ca2+]SG. Both inositol 1,4,
5-trisphosphate (InsP3) and caffeine produced a rapid Ca2+
release from the granules, suggesting the presence of InsP3
and ryanodine receptors in the granules. The response to
high-K+ depolarization was different in both cell types, a
decrease in [Ca2+]SG in PC12 cells and an increase in
[Ca2+]SG in INS1 cells. The difference may rely on the
heterogeneous response of different vesicle populations in
each cell type. Finally, increasing the glucose concentration
triggered a decrease in [Ca2+]SG in INS1 cells. In conclusion,
our data show that the secretory granules of PC12 and INS1
cells take up Ca2+ through SERCA-type Ca2+ pumps and
can release it through InsP3 and ryanodine receptors, supporting
the hypothesis that secretory granule Ca2+ may be
released during cell stimulation and contribute to secretion
