Origin of intracellular calcium and quantitation of mobilizable calcium in neutrophils stimulated with chemotactic peptide

The origin and amount of mobilized Ca2+ in chemotactic peptide-stimulated guinea pig neutrophils were examined using biochemical techniques. The total amount of releasable Ca2+ by 20 microM A23187 from the unstimulated intact cells was 0.91 nmol/4 X 10(6) cells, as assessed by change in absorbance of the antipyrylazo III-Ca2+ complex. Two types of internal vesicular Ca2+ pool, mitochondrial and non-mitochondrial pool were identified in the saponin-permeabilized cells. The total amount of releasable Ca2+ was comparable to that accumulated by the non-mitochondrial pool at (1-2) X 10(-7) M of a free Ca2+ concentration. The mitochondrial uncoupler, capable of releasing Ca2+ from the mitochondrial pool, neither modified the basal cytosolic free Ca2+ in quin 2-loaded cells nor caused a Ca2+ efflux from the intact cells. These results suggest that the releasable Ca2+ may be located in the non-mitochondrial pool of unstimulated intact cells, and the mitochondrial pool contains little releasable Ca2+. The addition of fMet-Leu-Phe increased the cytosolic free Ca2+ by two processes: Ca2+ mobilization from internal stores and Ca2+ influx through the surface membrane. The Ca2+ mobilized and effluxed from the intact cells by stimulation with the maximal doses of fMet-Leu-Phe was estimated to be 0.27 nmol/4 X 10(6) cells. Almost equal amounts were released by the maximal doses of inositol 1,4,5-trisphosphate from the non-mitochondrial pool of saponin-treated cells that had accumulated Ca2+ at a free Ca2+ concentration of 1.4 X 10(-7) M. The mechanism related to the Ca2+ influx by fMet-Leu-Phe stimulation was also examined. The addition of nifedipine or phosphatidic acid did not affect the change in the cytosolic free Ca2+ induced by fMet-Leu-Phe, thereby suggesting that the receptor-mediated Ca2+ channel may be involved in the Ca2+ influx.     

Effect of guanosine triphosphate on the release and uptake of Ca2+ in saponin-permeabilized macrophages and the skeletal-muscle sarcoplasmic reticulum.

The effects of GTP, with or without polyethylene glycol (PEG), on the release and uptake of Ca2+ were examined by using saponin-treated macrophages and sarcoplasmic reticulum isolated from skeletal muscles. The application of GTP in concentrations in the range 0.1-10 microM induced a gradual, small but sustained release of Ca2+ from the saponin-treated macrophages. The addition of PEG to GTP markedly enhanced the GTP-mediated Ca2+ release. GTP at the same concentration ranges used for Ca2+ release decreased the amount of Ca2+ uptake, at a steady state, but stimulated the rate of Ca2+ accumulation in the presence of oxalate, the Ca2+-precipitating anion. The addition of PEG abolished the GTP-evoked stimulation of Ca2+ accumulation in the presence of oxalate. The stimulating effect on the rate of Ca2+ accumulation by GTP and its elimination by PEG were not due to changes in the permeability of oxalate by either GTP or PEG, or both. The Ca2+-releasing effect of GTP without PEG was enhanced by eliminating the uptake activity by decreasing the content of ATP. These results indicate that GTP has an inherent activity to release Ca2+ from non-mitochondrial intracellular stores of saponin-treated macrophages, and PEG enhances the GTP-mediated Ca2+ release, partly owing to its eliminating effect on GTP-stimulated Ca2+ uptake activity. These effects of GTP observed with saponin-permeabilized macrophages were not apparent in the isolated skeletal-muscle sarcoplasmic reticulum.     

Identification of intracellular calcium pools. Selective modification by thapsigargin

Recent studies have identified inositol 1,4,5-tris-phosphate(InsP3)-sensitive and -insensitive Ca2+ pools and a GTP-dependent mechanism that transfers Ca2+ between them. Here, the Ca2+ pump-inhibitory sesquiterpene lactone, thapsigargin, is shown to distinguish these two Ca2+ pools and identify a third Ca2+ pumping pool unresponsive to InsP3 or GTP. Using saponin-permeabilized DDT1MF-2 smooth muscle cells, approximately 75% of total intracellular ATP-dependent Ca2+ accumulation is blocked by thapsigargin with an IC50 of 30 nM. In contrast, 1 mM vanadate or 5 microM A23187 block 100% of Ca2+ accumulation. The thapsigargin-responsive Ca2+ pool corresponds exactly to that released by 10 microM InsP3 in the presence of 10 microM GTP. Indeed, addition of InsP3 with GTP has no effect on Ca2+ accumulated in the presence of 3 microM thapsigargin whereas A23187 releases all the remaining Ca2+. Added after maximal Ca2+ uptake, thapsigargin induces only slow Ca2+ release consistent with blockade of pumping activity. Unlike InsP3, the action of thapsigargin is entirely heparin insensitive. The large increment in Ca2+ uptake caused by 12 mM oxalate is completely reversed by thapsigargin, indicating that thapsigargin functions on an oxalate-permeable pool. Moreover, the still larger uptake induced by GTP in the presence of oxalate is also completely reversed by either thapsigargin or InsP3. The results indicate that thasigargin blocks Ca2+ uptake into two discrete pools: the InsP3-sensitive, oxalate-permeable Ca2+ pool and the InsP3-insensitive, oxalate-impermeable Ca2+ pool that can be "recruited" into the InsP3-sensitive pool by GTP-dependent Ca2+ translocation (Ghosh, T. K., Mullaney, J.M., Tarazi, F.I., and Gill, D.L. (1989) Nature 340, 236-239). Additionally, a third Ca2+ pool is defined, unreleasable by InsP3 or GTP, and containing a thapsigargin-insensitive Ca2+ pump.     

Calcium stores in electropermeabilized HL-60 cells before and after differentiation

Non-induced HL-60 cells (N-IND) and HL-60 cells induced to differentiate with 2 microM retinoic acid (IND) were electropermeabilized with electrical discharges, and the intracellular Ca2+ stores were measured in each type of cell. Both N-IND and IND cells accumulate Ca2+ in the presence of ATP after electropermeabilization. The Ca2+ is stored in at least two different compartments; accumulation in one of the compartments is inhibited by oligomycin and CCCP, and it is not releasable by Ins(1,4,5)P3. The maximal accumulation of Ca2+ by the Ins(1,4,5)P3 sensitive pool is about 0.3 nmol/10(6) cells and 0.9 nmol/10(6) cells for the N-IND and for the IND cells, respectively, and the half-maximal value occurs at a free Ca2+ concentration of 0.23 microM and 0.63 microM, respectively. The oligomycin + CCCP sensitive pool hardly accumulates any Ca2+ at this level of free Ca2+, but at higher free [Ca2+] (greater than microM) its maximal capacity is 80-100-fold higher than the Ins(1,4,5)P3-sensitive pool (about 17-18 nmol/10(6) cells). It is concluded that at physiological free Ca2+ concentrations, the non-mitochondrial Ca2+ pool is regulating the intracellular free Ca2+ in N-IND and IND HL-60 cells, and that this Ca2+ pool can be mobilized by Ins(1,4,5)P3. Furthermore, the capacity of this pool increases about 3-fold when the cells are induced to differentiate with retinoic acid.     

Fast kinetics of calcium release induced by myo-inositol trisphosphate in permeabilized rat hepatocytes

We used a stopped-flow method for determining the kinetic properties (between 10 ms and 10 s) of the Ca2+ release induced by inositol 1,4,5-trisphosphate (InsP3) in saponin-treated rat hepatocytes. Preliminary experiments ensured that the indicator was able to monitor rapid changes in free Ca2+ reliably. At 20 degrees C, a maximally efficient concentration of 10 microM InsP3 released Ca2+ with a half-time of 150-300 ms, the initial rate being about 1-2 nmol of Ca2+/mg of cell protein/s. The delay between the addition of 10 microM InsP3 and the onset of Ca2+ release was shorter than 20 ms, suggesting that the opening process of Ca2+ channels after binding of InsP3 to receptors is completed within a few milliseconds. Half-maximal initial rates for Ca2+ release occurred at about 1 microM InsP3 (Hill index was 1.6). The resulting Ca2+ efflux had a moderate temperature dependence. It could not be fitted to a single exponential. After low speed centrifugation of saponin-treated cells (1000 x g for 1 min), part of the InsP3-sensitive Ca2+ pool was recovered in the cell-free supernatant fraction, suggesting that the response to InsP3 arises from a vesicular fraction which may diffuse from the saponin-treated cells into the medium.     

Increase in Ca2+ permeability of intracellular Ca2+ store membrane of saponin-treated guinea pig peritoneal macrophages by inositol 1,4,5-trisphosphate

Inositol 1,4,5-trisphosphate (InsP3) releases Ca2+ from the non-mitochondrial Ca2+ store site of various types of cells. To study the mechanisms of the Ca2+ release from the store site, the effect of InsP3 on the passive Ca2+ release and influx, and the active Ca2+ uptake in the presence of oxalate, was examined using saponin-treated guinea pig peritoneal macrophages. InsP3 stimulated the passive Ca2+ release and influx. Although InsP3 slightly inhibited the active Ca2+ uptake in the presence of oxalate, it seems unlikely that the Ca2+ release by this agent is caused by the inhibition of the Ca2+ uptake, because the addition of apyrase or hexokinase (which removes ATP within 30 s, so that no more Ca2+ can be accumulated) or vanadate (which inhibits the Ca2+ uptake) resulted in very slow release of Ca2+. These results suggest that the Ca2+ permeability of the Ca2+ store membrane is increased by InsP3. InsP3 did not cause an increase in the Ca2+ permeability of phospholipid vesicles (liposomes), indicating that this agent may bring about Ca2+ release by a specific effect on the physiologically relevant Ca2+ channels or carriers in the non-mitochondrial Ca2+ store site. The passive Ca2+ release by InsP3 was enhanced by ATP and an unhydrolyzable ATP analogue, 5'-adenylyimidodiphosphate, but not by ADP or AMP. The passive Ca2+ release by InsP3 was observed even at 0 degree C.     

Kinetics of ATP-dependent Ca2+ uptake by permeabilized rat enterocytes. Effects of inositol 1,4,5-trisphosphate

Isolated rat enterocytes were permeabilized by saponin treatment. 45Ca2+ was accumulated by these cells when provided with ATP in a medium containing Ca2+ ligands. The use of oxalate, vanadate and mitochondrial inhibitors indicated that both non-mitochondrial and mitochondrial pools are involved. Kinetic analysis of non-mitochondrial Ca2+ uptake revealed a Km of 0.1 microM Ca2+ and a Vmax of 0.4 nmol Ca2+/mg protein X min for this Ca2+-pumping ATPase activity. Mitochondria started to take up Ca2+ between 0.2 and 0.3 microM free Ca2+ reaching maximal rates around 2 microM. At 1 microM free Ca2+ mitochondria accumulated 20 times more Ca2+ than the non-mitochondrial pool. Inositol 1,4,5-trisphosphate released 40% of the Ca2+ content of the non-mitochondrial pool. Half-maximal release was observed at 0.5 and 1.5 microM IP3 in duodenal and ileal cells respectively. These findings support the possibility that the phosphatidyl inositide metabolism plays a role in regulation of electrolyte transport in enterocytes.     

Inositol 1,4,5-trisphosphate and intracellular Ca2+ homeostasis in clonal pituitary cells (GH3). Translocation of Ca2+ into mitochondria from a functionally discrete portion of the nonmitochondrial store

Ca2+-specific minielectrodes were used to monitor changes in the ambient free Ca2+ concentration [( Ca2+]a) maintained by the intracellular organelles of permeabilized GH3 cells. Mitochondria maintained a [Ca2+]a steady state of around 500 nM and displayed a very high capacity for Ca2+ uptake. A nonmitochondrial pool, tentatively identified as the endoplasmic reticulum (ER), displayed higher affinity for Ca2+ by maintaining a steady state of approximately 170 nM. The capacity of this pool was around 10 nmol/mg cell protein. Inositol 1,4,5-trisphosphate (InsP3) released Ca2+ specifically from the ER, with an EC50 of approximately 2 microM, and gave maximal release of around 4 nmol Ca2+/mg of cell protein. Repeated InsR3 additions under conditions allowing for functional mitochondrial transport resulted in successively attenuated peaks, leading eventually to the depletion of the InsP3 sensitive portion of the ER. However, Ca2+ could still be released from the total ER pool with the ATPase inhibitor, vanadate. This InsP3-insensitive store did not reaccumulate InsP3 releasable Ca2+ nor could it directly refill the sensitive pool. However, the attenuation of the InsP3 responses could be overcome by repleting the sensitive pool with exogenous Ca2+ or by inhibiting Ca2+ uptake into the mitochondria. The results suggest: 1) the ER is the major intracellular organelle buffering Ca2+ in nonstimulated GH3 cells; 2) InsP3 releases Ca2+ from only a portion of the ER; 3) the InsP3-sensitive and -insensitive ER pools are functionally distinct; 4) InsP3 addition results in a transfer of Ca2+ from the ER to the mitochondria.     

Properties of different Ca2+ pools in permeabilized rat thymocytes

The regulation of free Ca2+ concentration by intracellular pools and their participation in the mitogen-induced changes of the cytosolic free Ca2+ concentration, [Ca2+]i, was studied in digitonin-permeabilized and intact rat thymocytes using a Ca2+-selective electrode, chlortetracycline fluorescence and the Ca2+ indicator quin-2. It is shown that in permeabilized thymocytes Ca2+ can be accumulated by two intracellular compartments, mitochondrial and non-mitochondrial. Ca2+ uptake by the non-mitochondrial compartment, presumably the endoplasmic reticulum, is observed only in the presence of MgATP, is increased by oxalate and inhibited by vanadate. The mitochondria do not accumulate calcium at a free Ca2+ concentration below 1 microM. The non-mitochondrial compartment has a greater affinity for calcium and is capable of sequestering Ca2+ at a free Ca2+ concentration less than 1 microM. At free Ca2+ concentration close to the cytoplasmic (0.1 microM) the main calcium pool in permeabilized thymocytes is localized in the non-mitochondrial compartment. Ca2+ accumulated in the non-mitochondrial pool can be released by inositol 1,4,5-triphosphate (IP3) which has been inferred to mediate Ca2+ mobilization in a number of cell types. Under experimental conditions in which ATP-dependent Ca2+ influx is blocked, the addition of IP3 results in a large Ca2+ release from the non-mitochondrial pool; thus IP3 acts by activation of a specific efflux pathway rather than by inhibiting Ca2+ influx. SH reagents do not prevent IP3-induced Ca2+ mobilization. Addition of the mitochondrial uncouplers, FCCP or ClCCP, to intact thymocytes results in no increase in [Ca2+]i measured with quin-2 tetraoxymethyl ester whereas the Ca2+ ionophore A23187 induces a Ca2+ release from the non-mitochondrial store(s). Thus, the data obtained on intact cells agree with those obtained in permeabilized thymocytes. The mitogen concanavalin A increases [Ca2+]i in intact thymocytes suspended in both Ca2+-containing an Ca2+-free medium. This indicates a mitogen-induced mobilization of an intracellular Ca2+ pool, probably via the IP3 pathway.     

Inositol 1,4,5-trisphosphate-induced Ca2+ release from the sarcoplasmic reticulum and contraction in crustacean muscle

Intracellular applications of a fixed amount (0.2 to 8 nmol) of inositol 1,4,5-trisphosphate (InsP3) over a brief period (2 s) into barnacle muscle fibers induced vigorous contractures. Peak tension attained during the first application depended on [InsP3]: the maximum tension evoked by the injection of 8 nmol was 1.6 kg/cm2. Peak tension during a second application of a high dose of InsP3 (greater than 10 microM) was always smaller than that during the first application. Extracellular Ca2+ could be omitted with no measurable effects on either the amplitude or time course of the contractures evoked by InsP3. Aequorin was used to measure InsP3-evoked Ca2+ release from intracellular stores in minced muscle fibers from lobster and in skinned muscle fibers from barnacle. Provided the sarcoplasmic reticulum was preloaded with Ca2+, application of InsP3 induced a transient Ca2+ release that was [InsP3] dependent. During each transient, [Ca2+] rose rapidly to a peak value (t1/2 less than 5 s) and then slowly returned (t1/2 less than 100 s) to a basal level. Maximum Ca2+ release was obtained at [InsP3] less than 100 microM and amounted to 4 nmol Ca2+/g of muscle, enough to increase [Ca2+]i from 0.1 to 8 microM had the Ca2+ release occurred in the intact fiber. Successive applications of a fixed amount of InsP3 elicited successive transient increases in Ca2+. The effects of [Ca2+] on the incorporation of [3H]inositol into the pools of phosphatidylinositol, phosphatidylinositol 4-phosphate, and phosphatidylinositol 4,5-bisphosphate pools were measured.(ABSTRACT TRUNCATED AT 250 WORDS)     

Calcium pools in sea urchin eggs: roles of endoplasmic reticulum and mitochondria in relation to fertilization.

A preparation of sea urchin eggs permeabilized with digitonin (40 microM for 2.5 min) was used to study the kinetic characteristics of the two cellular compartments suspected to play a key role in cellular calcium transfer during fertilization: an ATP-dependent Ca2+ pool (Km = 0.47 microM; Vm = 0.48 nmol/min.mg protein) probably located in the endoplasmic reticulum and a mitochondrial Ca2+ pool (Km = 1.50 microM; Vm = 0.12 nmol/min.mg protein). Fertilization triggered a decrease in the rate of ATP dependent uptake by the non-mitochondrial pool (Km = 0.59 microM; Vm = 0.15 nmol/min.mg protein) while it transiently increased the Ca2+ uptake into mitochondria (2 min post-fertilization: Km = 2.20 microM; Vm = 0.40 nmol/min.mg protein). Microanalysis studies performed on quickly frozen, freeze substituted and embedded eggs showed a transient Ca2+ enrichment of mitochondria soon after fertilization thus suggesting that mitochondria behave as a Ca2+ sink at fertilization. Results are discussed in relation to the role of endoplasmic reticulum and mitochondria in handling free calcium during the early period following sea urchin egg fertilization.     

Calcium mobilization in permeabilized fibroblasts: effects of inositol trisphosphate, orthovanadate, mitogens, phorbol ester, and guanosine triphosphate

Utilizing a digitonin-permeabilized cell system, we have studied the release of calcium from a non-mitochondrial intracellular compartment in cultured human fibroblasts (HSWP cells). Addition of 1 mM MgATP to a monolayer of permeabilized cells in a cytosolic media buffered to 150 nM Ca with EGTA rapidly stimulates 45Ca uptake, and the subsequent addition of the putative intracellular messenger inositol trisphosphate (InsP3) induces rapid release of 85% (+/- 6% n = 6) of the 45Ca taken up in response to ATP. Mitogenic peptides (bradykinin, vasopressin, epidermal growth factor [EGF], and insulin) and orthovanadate, which are effective in mobilizing intracellular Ca in intact cells, have little or no effect when added alone to permeabilized cells. However, in the presence of GTP these agents stimulate accumulation of inositol phosphates and release Ca from the InsP3-sensitive pool. These data suggest that a GTP binding protein is involved in receptor mediated activation of phospholipase C, which leads to release of inositol phosphates. The GTP-dependent release of InsP3 and the mobilization of 45Ca from the intracellular compartment are inhibited by pretreatment of cells, prior to permeabilization, with the protein kinase C activator 12-O-tetradecanoyl-phorbol-13-acetate (TPA). TPA pretreatment does not affect the InsP3 stimulated Ca release. These results suggest that protein kinase C is involved in down-regulation or inhibition of phospholipase C, or the GTP binding protein responsible for relaying the mitogenic signal from the cell surface receptor to the phospholipase C activity.     

Inositol trisphosphate mediates thyrotropin-releasing hormone mobilization of nonmitochondrial calcium in rat mammotropic pituitary cells

Thyrotropin-releasing hormone (TRH) stimulation of prolactin secretion from GH3 cells, cloned rat pituitary tumor cells, is associated with 1) hydrolysis of phosphatidylinositol 4,5-bisphosphate to yield inositol trisphosphate (InsP3) and 2) elevation of cytoplasmic free Ca2+ concentration [( Ca2+]i), caused in part by mobilization of cellular calcium. We demonstrate, in intact cells, that TRH mobilizes calcium and, in permeabilized cells, that InsP3 releases calcium from a nonmitochondrial pool(s). In intact cells, TRH caused a loss of 16 +/- 2.7% of cell-associated 45Ca which was not inhibited by depleting the mitochondrial calcium pool with uncoupling agents. Similarly, TRH caused an elevation of [Ca2+]i from 127 +/- 6.3 nM to 375 +/- 54 nM, as monitored with Quin 2, which was not inhibited by depleting mitochondrial calcium. Saponin-permeabilized cells accumulated Ca2+ in an ATP-dependent manner into a nonmitochondrial pool, which exhibited a high affinity for Ca2+ and a small capacity, and into a mitochondrial pool which had a lower affinity for Ca2+ but was not saturated under the conditions tested. Permeabilized cells buffered free Ca2+ to 129 +/- 9.2 nM when incubated in a cytosol-like solution initially containing 200 to 1000 nM free Ca2+. InsP3, but not other inositol sugars, released calcium from the nonmitochondrial pool(s); half-maximal effect occurred at approximately 1 microM InsP3. Ca2+ release was followed by reuptake into a nonmitochondrial pool(s). These data suggest that InsP3 serves as an intracellular mediator (or second messenger) of TRH action to mobilize calcium from a nonmitochondrial pool(s) leading to an elevation of [Ca2+]i and then to prolactin secretion.     

Characterization of the inositol 1,4,5-trisphosphate-induced Ca2+ release in pancreatic beta-cells.

Pancreatic beta-cells isolated from obese-hyperglycaemic mice released intracellular Ca2+ in response to carbamoylcholine, an effect dependent on the presence of glucose. The effective Ca2+ concentration reached was sufficient to evoke a transient release of insulin. When the cells were deficient in Ca2+, the Ca2+ pool sensitive to carbamoylcholine stimulation was equivalent to that released by ionomycin. Unlike intact cells, cells permeabilized by high-voltage discharges failed to generate either inositol 1,4,5-triphosphate (InsP3) or to release Ca2+ after exposure to carbamoylcholine. However, the permeabilized cells released insulin sigmoidally in response to increasing concentrations of Ca2+. Also in the absence of functional mitochondria these cells exhibited a large ATP-dependent buffering of Ca2+, enabling the maintenance of an ambient Ca2+ concentration corresponding to about 150 nM even after several additional pulses of Ca2+. InsP3, maximally effective at 6 microM, promoted a rapid and pronounced release of Ca2+. The InsP3-sensitive Ca2+ pool was rapidly filled and lost its Ca2+ late after ATP depletion. The transient nature of the Ca2+ signal was not overcome by repetitive additions of InsP3. It was possible to restore the response to InsP3 after a delay of approx. 20 min, an effect which had less latency after the addition of Ca2+. These latter findings argue against degradation and/or desensitization as factors responsible for the transiency in InsP3 response. It is suggested that Ca2+ released by InsP3 is taken up by a part of the endoplasmic reticulum (ER) not sensitive to InsP3. On metabolism of InsP3, Ca2+ recycles to the InsP3-sensitive pool, implying that this pool indeed has a very high affinity for the ion. The presence of functional mitochondria did not interfere with the recycling process. The ER in pancreatic beta-cells is of major importance in buffering Ca2+, but InsP3 only modulates Ca2+ transport for a restricted period of time following immediately upon its formation. Thereafter the non-sensitive part of the ER takes over the continuous regulation of Ca2+ cycling.     

The origin, quantitation, and kinetics of intracellular calcium mobilization by vasopressin and phenylephrine in hepatocytes

The addition of phenylephrine or vasopressin to isolated hepatocytes resulted in an efflux of calcium. The intracellular source of this calcium was determined by measuring the calcium released upon the sequential additions of an uncoupling agent and the Ca2+ ionophore A23187 to control and hormone-treated cells. The release promoted by these agents was used as an estimate of the calcium content of the mitochondria and endoplasmic reticulum, respectively. The validity and limitations of this method are critically evaluated. The source of the calcium mobilized by the hormones was found to depend on the intracellular calcium distribution. When the amount of total cell-releasable Ca2+ was low (less than 0.9 nmol/mg cell dry weight), the endoplasmic reticulum represented the major cellular calcium pool and was also the predominant pool mobilized by the hormone. As the cell calcium content was increased, the endoplasmic reticulum attained its maximum capacity and the mitochondria sequestered increasing amounts of calcium. Under these conditions, the hormones mobilized calcium from the mitochondria with minimal effects on the endoplasmic reticulum calcium pool. These results suggest that more than one hormone-induced Ca2+-releasing agent may be formed. Both the total amount and the rate of calcium released from the cell under the influence of hormones was independent of the cell calcium content. The appearance of hormone-releasable Ca2+ in the extracellular medium showed a lag period of 5 to 10 s, during which a rapid increase of phosphorylase activity was observed. In contrast, the mobilization of a comparable amount of calcium by carbonyl cyanide p-trifluoromethoxyphenylhydrazone showed no significant lag, but the activation of phosphorylase was slower. A kinetic analysis of the hormone-releasable Ca2+ indicated a rapid onset with a peak increase of cytosolic free Ca2+ between 5 and 10 s prior to release of Ca2+ from the cell. The results suggest that an early action of the hormone is the inhibition of the plasma membrane Ca2+ efflux pump.     

Modulation of intracellular Ca2+ in the parathyroid cell. Release of Ca2+ from non-mitochondrial pools by inositol trisphosphate

Stimuli which enhance secretion from parathyroid cells such as low extracellular Ca2+ or Mg2+ are associated with a decrease in the cytosolic Ca2+ concentration as measured by quin2. Current evidence suggests that increased production of inositol 1,4,5-triphosphate (IP3) releases Ca2+ from cellular stores thus increasing cytosolic Ca2+. We used saponin-permeabilized dispersed bovine parathyroid cells to study the effect of IP3 on intracellular Ca2+. IP3 released Ca2+ from these cells in a dose-dependent manner; half-maximal response occurred with 0.3 microM IP3 and maximal response with 1.2 microM IP3. Permeabilized cells incubated in the presence of the mitochondrial inhibitor antimycin A released a similar amount of Ca2+ suggesting that IP3 releases Ca2+ from a non-mitochondrial pool. These results suggest that IP3 regulates cytosolic Ca2+ in this system and may function as a second messenger controlling hormone secretion.     

GTP-sensitivity of the energy-dependent Ca2+ storage pool in permeabilized pancreatic acinar cells

Isolated rabbit pancreatic acinar cells, permeabilized by saponin treatment and incubated in the presence of 0.1 microM free Ca2+, accumulated 3.3 nmol of Ca2+/mg of acinar protein in an energy-dependent pool. Part of this energy-dependent pool could be released by GTP in a polyethylene glycol-dependent manner. The kinetics of GTP-induced release of Ca2+ showed a biphasic pattern with an initial rapid phase followed by a sustained slower phase. In contrast, IP3-induced release of Ca2+ was completed within 30 s following addition of IP3. No reuptake of Ca2+ was observed following GTP- or IP3-induced release of Ca2+. The GTP effect was independent of IP3 and not inhibited by Ca2+, indicating that the IP3-operated Ca2+ channel is not involved in GTP-induced release of Ca2+. The size of the IP3-releasable pool was not affected by GTP, indicating that GTP, when added to permeabilized acinar cells, does not promote the coupling between IP3-insensitive and IP3-sensitive Ca2+ accumulating organelles. Thus, in permeabilized acinar cells, GTP and IP3 act on different Ca2+ sequestering pools. Interestingly, however, comparison of the size of the GTP-releasable pool with that of the IP3-releasable pool for the cell preparations used in the present study, revealed an inversed relationship, indicating that at the time of permeabilization the GTP-releasable pool can be coupled to a greater or lesser extent to the IP3-releasable pool. This suggests that, in the intact cell, a GTP-dependent mechanism may exist that controls the size of the IP3-releasable pool by coupling IP3-insensitive to IP3-sensitive organelles. Moreover, this suggests that the extent of coupling is preserved during permeabilization.     

Guanine nucleotide-dependent pertussis-toxin-insensitive stimulation of inositol phosphate formation by carbachol in a membrane preparation from human astrocytoma cells.

The efficacy of muscarinic-receptor agonists for stimulation of inositol phosphate formation and Ca2+ mobilization in intact 1321N1 human astrocytoma cells is correlated with their capacity for formation of a GTP-sensitive high-affinity binding complex in membranes from these cells [Evans, Hepler, Masters, Brown & Harden (1985) Biochem. J. 232, 751-757]. These observations prompted the proposal that a guanine nucleotide regulatory protein serves to couple muscarinic receptors to the phospholipase C involved in phosphoinositide hydrolysis in 1321N1 cells. Inositol phosphate (InsP) formation was measured in a cell-free preparation from 1321N1 cells to provide direct support for this idea. The formation of InsP3, InsP2 and InsP1 was increased in a concentration-dependent manner (K0.5 approximately 5 microM) by guanosine 5'-[gamma-thio]triphosphate (GTP[S]) in washed membranes prepared from myo-[3H]inositol-prelabelled 1321N1 cells. Both GTP[S] and guanosine 5'-[beta gamma-imido]triphosphate (p[NH]ppG) stimulated InsP formation by 2-3-fold over control; GTP, GDP and GMP were much less efficacious. Millimolar concentrations of NaF also stimulated the formation of inositol phosphates in membrane preparations from 1321N1 cells. In the presence of 10 microM-GTP[S], the muscarinic cholinergic-receptor agonist carbachol stimulated (K0.5 approximately 10 microM) the formation of InsP above that achieved with GTP[S] alone. The effect of carbachol was completely blocked by atropine. The order of potency of nucleotides for stimulation of InsP formation in the presence of 500 microM-carbachol was GTP[S] greater than p[NH]ppG greater than GTP = GDP. Pertussis toxin, at concentrations that fully ADP-ribosylate and functionally inactivate Gi (the inhibitory guanine nucleotide regulatory protein), had no effect on InsP formation in the presence of GTP[S] or GTP[S] plus carbachol. These data are consistent with the idea that a guanine nucleotide regulatory protein that is not Gi is involved in receptor-mediated stimulation of InsP formation in 1321N1 human astrocytoma cells.     

Guanosine 5''-O-Thiotriphosphate and Sodium Fluoride Activate Polyphosphoinositide Hydrolysis in Rat Cortical Membranes by Distinct Mechanisms

NaF and guanosine 5'-O-thiotriphosphate [GTP(S)] stimulated the accumulation of [3H]inositol monophosphate ([3H]InsP) in rat brain cortical membranes, with half-maximal stimulation at 2 mM and 1 microM, respectively. Calcium also increased basal [3H]InsP formation over a range of concentrations from 10(-7) to 10(-4) M. The stimulatory effect of GTP(S) (30 microM) on [3H]InsP production was insensitive to Ca2+, whereas NaF-evoked [3H]InsP formation was dependent on Ca2+ concentrations. Guanosine 5'-O-thiodiphosphate significantly attenuated GTP(S)- but not NaF-stimulated [3H]InsP production. Coincubation of GTP(S) (30 microM) and submaximal concentrations of NaF (1 or 3 mM) stimulated [3H]InsP formation to a degree that was nearly additive with that produced by either drug alone. However, the resultant accumulation of [3H]InsP in the presence of maximally effective concentrations of GTP(S) and NaF was not different from that produced by NaF alone. Incubation of cortical membranes with GTP(S) and NaF for 1 min stimulated the accumulation of [3H]inositol bisphosphate (InsP2) but not [3H]InsP. [3H]InsP2 production elicited by GTP(S) was markedly enhanced by the muscarinic cholinergic agonist carbachol. In contrast, NaF-stimulated [3H]InsP2 formation was not potentiated by carbachol. Our findings of different characteristics of GTP(S) and fluoride activation of polyphosphoinositide (PPI) hydrolysis suggest that separate regulatory mechanisms are involved in these two modes of stimulation in brain membranes. Activation of PPI hydrolysis by fluoride may be mediated by a direct stimulation of PPI phosphodiesterase or by activating a putative guanine nucleotide regulatory protein at a location distinct from the GTP-binding site.     

Ca(2+)-induced Ca2+ release in insulin-secreting cells.

The sulphydryl reagent thimerosal (50 microM) released Ca2+ from a non-mitochondrial intracellular Ca2+ pool in a dose-dependent manner in permeabilized insulin-secreting RINm5F cells. This release was reversed after addition of the reducing agent dithiothreitol. Ca2+ was released from an Ins(1,4,5)P3-insensitive pool, since release was observed even after depletion of the Ins(1,4,5)P3-sensitive pool by a supramaximal dose of Ins(2,4,5)P3 or thapsigargin. The Ins(1,4,5)P3-sensitive pool remained essentially unaltered by thimerosal. Thimerosal-induced Ca2+ release was potentiated by caffeine. These findings suggest the existence of Ca(2+)-induced Ca2+ release also in insulin-secreting cells.