Sg. Cessna et Ps. Low, An apoplastic Ca2+ sensor regulates internal Ca2+ release in aequorin-transformed tobacco cells, J BIOL CHEM, 276(14), 2001, pp. 10655-10662
Removal of Ca2+ from tobacco suspension cell medium has two immediate effec
ts on cytosolic Ca2+ fluxes: (i) externally derived Ca2+ influx (occurring
in response to cold shock or hypo osmotic shock) is inhibited, and (ii) org
anellar Ca2+ release (induced by a fungally derived defense elicitor, caffe
ine, or hypo-osmotic shock) is elevated. We show here that the enhanced rel
ease of internal Ca2+ is Likely due to increased discharge from a caffeine-
sensitive store in response to a signal transduced from an extracellular Ca
2+ sensor. Thus, chelation of extracellular Ca2+ in the absence of any othe
r stimulus directly activates release of intracellular Ca2+ into the cytoso
l, Evidence that this chelator-activated Ca2+ flux is dependent on a signal
ing pathway includes its abrogation by prior treatment with caffeine, and i
ts inhibition by protein kinase inhibitors (K252a and staurosporine) and an
ion channel blockers (niflumate and anthracene-9-carboxylate). An unexpecte
d characteristic of tobacco cell adaptation to low external Ca2+ was the em
ergence of a new Ca2+ compartment that was inaccessible to external EGTA, y
et responsive to the usual stimulants of extracellular Ca2+ entry. Thus, ce
lls that are exposed to EGTA for 20 min lose sensitivity to caffeine and de
fense elicitors, indicating that their intracellular Ca2+ pools have been d
epleted, Surprisingly, these same cells simultaneously regain their ability
to respond to stimuli that usually activate extracellular Ca2+ influx even
though all external Ca2+ is chelated, Because this gradual restoration of
Ca2+ influx can be inhibited by the same kinase inhibitors that block EGTA-
activated Ca2+ release, we propose that chelator-activated Ca2+ release fro
m internal stores leads to deposition of this Ca2+ into a novel EGTA- and c
affeine-insensitive compartment that can subsequently be activated by stimu
lants of extracellular Ca2+ entry.