©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
The Quantal Nature of Calcium Release to Caffeine in Single Smooth Muscle Cells Results from Activation of the Sarcoplasmic Reticulum Ca-ATPase (*)

(Received for publication, November 20, 1995)

Josef M. Steenbergen Fredric S. Fay (§)

From the Biomedical Imaging Group, Program in Molecular Medicine, Department of Physiology, University of Massachusetts Medical School, Worcester, Massachusetts 01655

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Calcium release from intracellular stores occurs in a graded manner in response to increasing concentrations of either inositol 1,4,5-trisphosphate or caffeine. To investigate the mechanism responsible for this quantal release phenomenon, [Ca] changes inside intracellular stores in isolated single smooth muscle cells were monitored with mag-fura 2. Following permeabilization with saponin or alpha-toxin the dye, loaded via its acetoxymethyl ester, was predominantly trapped in the sarcoplasmic reticulum (SR). Low caffeine concentrations in the absence of ATP induced only partial Ca release; however, after inhibiting the calcium pump with thapsigargin the same stimulus released twice as much Ca. When the SR Ca-ATPase was rendered non-functional by depleting its ``ATP pool,'' submaximal caffeine doses almost fully emptied the stores of Ca. We conclude that quantal release of Ca in response to caffeine in these smooth muscle cells is largely due to the activity of the SR Ca-ATPase, which appears to return a portion of the released Ca back to the SR, even in the absence of ATP. Apparently the SR Ca-ATPase is fueled by ATP, which is either compartmentalized or bound to the SR.


INTRODUCTION

Cells respond to increasing concentrations of many hormones and neurotransmitters with graded changes in cytosolic [Ca]. The rise in [Ca] arises in many cells due to release of Ca from internal stores through activation of the inositol 1,4,5-trisphosphate (IP(3)) (^1)receptor by IP(3)(1) . The graded nature of Ca release from internal stores is known as quantal release(2) . Internal Ca stores in many cells also contain ryanodine receptors (RyR), which are activated by cytoplasmic calcium (3) and possibly cyclic ADP-ribose(4) . Calcium release due to activation of this receptor with caffeine also occurs in a quantal fashion(5, 6) . Three principal hypotheses have been proposed to explain the partial emptying of Ca from internal stores by submaximal levels of IP(3) or caffeine. 1) Individual store elements have different sensitivities to agonists and empty in an all or none fashion (7) ; 2) all stores partially empty at certain agonist concentrations due to diminished positive feedback effects of luminal [Ca] on Ca release(7) ; and 3) individual store elements differ not in the sensitivity of their IP(3) or possibly ryanodine receptors but rather in the density of these receptors(8) .

An alternative to these explanations is that Ca release is graded in response to increasing levels of agonists simply because at different levels of stimulation a new steady state is achieved reflecting IP(3)- or caffeine-induced stimulation of release and Ca sequestration by pumps associated with these stores. This explanation has been dismissed (9, 10) as IP(3)-induced Ca release in permeabilized cells still occurred in a ``quantal fashion'' under conditions where Ca pumps were nominally blocked due to ATP removal. However, evidence is emerging that the ATP consumed by some ion pumps (11, 12) is compartmentalized and might not be readily lost either by washing away ATP or even by incubation with ATP scavengers used in some studies(9, 10) . If Ca pumps on internal stores also have a compartment of inaccessible ATP then the role of such pumps in quantal release phenomena may have to be reconsidered. Recent work showing that inhibition of the Ca-ATPase with thapsigargin abolishes IP(3)-induced quantal release in permeabilized pancreatic acinar cells (13) suggests that activity of Ca pumps may well be required for quantal Ca release. As thapsigargin caused a significant Ca leak from intracellular stores in that study, the interpretation of those results may be difficult. Furthermore this study was carried out on populations of cells, and hence graded release may have arisen not because release of Ca in each cell was graded but because of variations in the responses of cells within the population. We thus developed a technique to monitor [Ca] changes in the sarcoplasmic reticulum in single isolated smooth muscle cells by loading these cells with the low affinity calcium indicator mag-fura 2 AM and permeabilizing the cell membrane to remove cytosolic dye and gain access to the cytoplasm, a general strategy first described by Hofer and Machen(14) .


EXPERIMENTAL PROCEDURES

Isolation and Loading of Smooth Muscle Cells

Smooth muscle cells were enzymatically dissociated from the stomach of the toad Bufo marinus(15) and loaded at a density of 10^5-10^6 cells/ml with acetoxymethyl ester of mag-fura 2 (1 µM, 25 °C) for at least 2 h.

Solutions

Buffer A consisted of (in mM): 130 K, 114 Cl, 1 dithiothreitol, 5 EGTA, 2 Ca, 20 HEPES, and 1 µg/ml leupeptin (pH 7.2). Buffer B was similar but also contained 3 mM MgATP and 0.1 mM Na(3)GTP. Calculated [Ca] in these buffers was 100 nM(16) . Caffeine, alpha-toxin, and saponin were dissolved in buffer A.

Permeabilization of Smooth Muscle Cells

After loading, cells were suspended in buffer A and placed in a perfusion chamber (200 µl). To exchange media the chamber was perfused at 2.5 ml/min for 30 s. After the cells settled, they were permeabilized with saponin (100 µg/ml, 30-60 s) or alpha-toxin (100 units/ml, 30-60 min), washed with buffer A, and resuspended in buffer B. Prior to an experiment, cells were washed with buffer A (ATP free). The ability of the sarcoplasmic reticulum (SR) to store and release Ca was retained following permeabilization with either agent. Saponin was used in most studies, as it acted more rapidly.

Three-dimensional Imaging of Fluorescence

To assess the three-dimensional distribution of mag-fura 2 a series of fluorescent images were obtained at 0.5-µm intervals through focus with a digital imaging microscope(17) . Images were obtained at 380 nm excitation and 510 nm emission with a water immersion objective (Nikon, times60, N.A. = 1.3). A constrained deconvolution algorithm (18) was applied to the images to reduce noise and distortion inherent to the acquisition process.

Calcium Measurements

Fluorescence in a non-nuclear region of single cells was measured with a microfluorimeter(19) . Fluorescence was recorded alternately at 340 and 380 nm, at up to 330 Hz, and after correction for background fluorescence was converted to a calcium ratio (340/380). Minimum fluorescence ratio (R(min)) was determined in vitro in buffer A without CaCl(2).

Materials

Mag-fura 2 AM was from Molecular Probes (Eugene, OR), saponin from ICN Biochemicals (Cleveland, OH), alpha-toxin from Life Technologies, Inc., and all other chemicals from Sigma.

Statistics

Data are given as mean ± S.E. and were subjected to Student's paired t test. Statistical significance was achieved at p < 0.05.


RESULTS AND DISCUSSION

In permeabilized cells, mag-fura 2 was distributed in a punctuate manner principally beneath the cell membrane and around the nucleus and was almost absent from the cytoplasm (Fig. 1). The pattern of dye distribution beneath the cell membrane was similar to that of calsequestrin(18) , a calcium-binding protein present in the SR of these cells, indicating that the loaded intracellular stores have a distribution pattern similar to this cellular compartment.


Figure 1: Three-dimensional distribution of mag-fura 2-loaded stores in alpha-toxin-permeabilized smooth muscle cell. Image to the left is a projection of 33 image planes at 0.5-µm intervals through cell; a cross-section is given on the right. Scale bars are 10 µm. Pixel spacing in x and y (0.25 pixel/µm) was less than in z (0.50 pixel/µm) and accounts largely for apparent asymmetry of the cell cross-section. Larger bright regions are most likely dye droplets adsorbed to the cell surface. The large oval at the center of the X-Y projection is dye associated with nuclear envelope.



Caffeine (25 mM, no ATP), which activates the RyR in these cells(20) , decreased the fluorescence ratio of mag-fura 2, and thus the [Ca], in the intracellular stores from 2.42 to 0.58. These stores apparently released their total free calcium in response to this high caffeine concentration as the final fluorescence ratio was virtually identical to R(min) in vitro. In the presence of ATP these stores were capable of calcium uptake, achieving a fluorescence ratio at least 80% of that prior to the initial caffeine challenge. As can be seen in Fig. 2A the response to caffeine was quite reproducible. Refilling of internal stores following caffeine stimulation was almost completely blocked by the specific inhibitor of the SR Ca-ATPase thapsigargin (5 min, 2 µM; Fig. 2B). Thus, based on the observations that the loaded intracellular stores have an anatomical distribution similar to the SR, contain a functional RyR and Ca-ATPase, and seem to release their total free calcium content in response to caffeine, we believe that the majority of mag-fura 2 signal originates from a SR-like compartment.


Figure 2: Changes in mag-fura 2 fluorescence ratio in response to caffeine in single saponin-permeabilized smooth muscle cells. A, two consecutive responses to caffeine in a single smooth muscle cell. After perfusing chamber with solution A (ATP free) for 60 s, solution A containing 25 mM caffeine was applied to the cell, the chamber again perfused with solution A for 60 s, and the cells placed in solution B (containing ATP) for 5 min. Solution A was then applied and the cell stimulated again with caffeine as before. Mag-fura 2 fluorescence decreased in a single exponential manner upon the first (2.15*(exp.(-0.1917*t)) + 0.2824; r^2 = 0.98) and second (1.473*(exp.(-0.2297*t)) + 0.3932; r^2 = 0.99) caffeine (25 mM) stimulation. B, effect of thapsigargin on the refilling of Ca stores as measured with mag-fura 2 in a single cell. Following initial caffeine stimulation and store refilling, the cell was exposed to 2*10M thapsigargin for 5 min and then exposed to caffeine followed by solution B. C, two consecutive responses to caffeine at a lower concentration (5 mM) in another smooth muscle cell. Experimental protocol are identical to that in A.



While high caffeine concentration (25 mM) caused the stores to release virtually all stored Ca, lower caffeine concentrations (5 mM) released less Ca in a reproducible manner (Fig. 2C). Increasing the caffeine concentration from 5 to 25 mM in the absence of ATP caused additional Ca release in the same cell (Fig. 3). The resting fluorescence ratio before caffeine application averaged 1.86 ± 0.13 and decreased to 1.18 ± 0.13 and 0.63 ± 0.05 in the presence of 5 and 25 mM caffeine, respectively (n = 7; Fig. 3B). This dose-dependent graded release of Ca from stores in the absence of ATP is a fundamental characteristic of the ``quantal response'' (12) (Fig. 3A).


Figure 3: Effect of incremental caffeine stimulation on mag-fura 2 fluorescence ratio in single saponin-permeabilized smooth muscle cells. A, typical fluorescence ratio recorded from a cell stimulated with 5 and then 25 mM caffeine. B, mean and S.E. for the steady states in fluorescence ratio in 7 cells subject to protocol in A. *, p < 0.05 compared with control;**, p < 0.05 compared with 5 mM caffeine.



What is responsible for the graded nature of Ca release with these submaximal doses of caffeine? It has been suggested that partial emptying of stores under such conditions may result from the presence of receptors on individual stores with different sensitivities to caffeine or alternatively that individual stores may have different densities of receptors with equivalent sensitivities to caffeine. In either case release of Ca in response to supramaximal doses of caffeine should be described by a multiexponential process. We found, however, that a single-exponential function was sufficient to fit the caffeine-induced Ca release (Fig. 2A), implying that there is only one functional store from which calcium is released. Therefore, these data suggested that the mechanism of quantal release may have some other basis. As shown in Fig. 2B, in the presence of thapsigargin but in the absence of exogenous ATP caffeine not only released more Ca from the SR but also at a faster rate compared with the caffeine response in the absence of thapsigargin. This suggested that perhaps the SR Ca-ATPase was active during the first caffeine response, even though caffeine was applied in the absence of ATP and the cells were washed with buffer A (60 s, no ATP/GTP). Thus the graded release of Ca at submaximal caffeine concentrations might result from opposing effects of the SR pumps and caffeine-activated Ca release channels, which may be operating to some extent even in an ATP-free medium, perhaps because the SR Ca-ATPase contains a tightly bound ``ATP pool.''

To investigate this hypothesis 5 and 25 mM caffeine was applied incrementally to the same cell before and after blocking the SR Ca-ATPase with thapsigargin (Fig. 4). As shown in Fig. 4A, caffeine at the lower concentration released more calcium from the SR and at a faster rate after thapsigargin. In six cells treated in this manner, the mean fluorescence ratio at rest was 2.07 ± 0.16 and decreased to 1.50 ± 0.18 and 0.65 ± 0.04 in the presence of 5 and 25 mM caffeine, respectively. The fluorescence ratio increased to 1.79 ± 0.16 in the presence of ATP (buffer B) for 5 min. After thapsigargin (2 µM) incubation for 5 min the resting ratio was 1.76 ± 0.17 and decreased to 0.92 ± 0.06 and 0.71 ± 0.04 in the presence of 5 and 25 mM caffeine, respectively (Fig. 4B). While the fluorescence ratio recovered to a variable degree after initial exposure to caffeine (range, 65-100%), the conversion of the response to caffeine following thapsigargin from being decidedly graded to largely all-or-none was not correlated with the extent of this recovery (r^2 = 0.21). These data supported our hypothesis that the SR Ca-ATPase was active during the first caffeine applications, even though ATP was absent from the medium. However, after blocking the SR calcium pumps the stores were still capable of releasing more calcium in the presence of a high caffeine concentration. As noted in Fig. 2, thapsigargin was not 100% effective in blocking the SR calcium pumps at this concentration. Therefore, a small fraction of the pumps might have remained active and been able to establish an equilibrium between calcium influx and efflux from internal stores, albeit at a lower store [Ca]. However, higher thapsigargin concentrations were not used to avoid nonspecific membrane leakiness seen at high concentrations(21) . The fluorescence ratio throughout the 5-min incubation with thapsigargin remained constant, indicating that the stores have a very low endogenous Ca leak rate.


Figure 4: Effect of thapsigargin on the change in mag-fura 2 fluorescence ratio in response to caffeine at 5 and 25 mM in saponin-permeabilized smooth muscle cells. A, typical fluorescence ratio recorded from a cell stimulated with incremental caffeine concentrations (5 and 25 mM) before and after thapsigargin (2 µM, 5 min). B, mean and standard errors for the steady states in fluorescence ratio in 6 cells subject to the protocol in A.



An additional experiment was performed to test the contribution of the SR Ca pumps to the quantal release phenomenon in response to caffeine without resorting to the use of pump inhibitors. In this series of experiments the putative ``ATP pool'' for SR Ca pumps was depleted by activation of these pumps at low caffeine concentration, and then the cells were tested for graded Ca release. For this, cells were stimulated with 5 mM caffeine, put in buffer A (no ATP) for 5 min, and then stimulated with 5 and 25 mM caffeine, during which time fluorescence ratio changes were monitored (Fig. 5). The resting ratio was 2.15 ± 0.17 and decreased to 1.41 ± 0.09 in the presence of 5 mM caffeine but in the absence of ATP. After buffer A (no ATP) incubation for 5 min the ratio had increased to 1.70 ± 0.11 but then decreased to 0.86 ± 0.03 and 0.79 ± 0.03 (n = 7) in the presence of 5 and 25 mM caffeine, respectively (Fig. 5B). After the first caffeine stimulus the cells were capable of calcium uptake as indicated by an increased ratio, supporting the notion that a small amount of ATP remained in the cell and was capable of fueling the SR calcium pump. The second caffeine response released virtually all free Ca from the SR, but higher caffeine concentration induced still a small but significant release of Ca. It is not clear why this additional Ca release occurred. It is possible that mitochondria are capable of producing a small amount of ATP and thus fuel the SR Ca pump, or the mitochondria may directly take up some Ca and pass it on to the SR. These data clearly indicate that the SR Ca-ATPase is active during the first caffeine application, partially returning some of the released calcium back to the SR, ultimately resulting in a steady state where not all Ca has been released. In addition, the second 5 mM caffeine application was capable of lowering the final calcium concentration in the SR more than the first stimulus, regardless of the initial luminal calcium concentration.


Figure 5: Effect of separated submaximal caffeine stimulation in the continued absence of ATP on mag-fura 2 fluorescence ratio in single saponin-permeabilized smooth muscle cells. A, typical fluorescence ratio recorded from a cell stimulated twice with 5 mM caffeine 5 min apart in the continued absence of ATP. B, mean and S.E. for the steady states in fluorescence ratio in 6 cells subject to the protocol in A. *, p < 0.05 compared with first 5 mM caffeine stimulus;**, p < 0.05 compared with second 5 mM caffeine stimulus.



In conclusion, graded increases in caffeine concentrations released calcium from the SR in a quantal manner in isolated smooth muscle cells permeabilized with saponin. These data cannot be reconciled with the current three hypotheses to explain the underlying mechanism of quantal release. Calcium release could be fit by a single exponential function, which is inconsistent with the notion that 1) discrete stores have different sensitivity to agonists and empty in an all or none fashion or that 2) ryanodine receptors are heterogeneously distributed among the stores. In addition, a second caffeine application of equal magnitude was capable of releasing more calcium from the SR regardless of the luminal calcium concentration, contrary to the notion that partial emptying of stores results from an effect of luminal [Ca] on the sensitivity of ryanodine receptors. We have shown that the phenomenon of quantal release at least in these cells in response to caffeine is largely due to the activity of the SR Ca-ATPase, which appears to return a portion of the released Ca back to the SR, even though these applications were in the absence of ATP and the cells were washed with an ATP-free buffer prior to these stimuli. Apparently, the SR Ca-ATPase is fueled by ATP, which is either compartmentalized or bound to the SR membrane.

While the current data may not be directly relevant to the mechanism underlying quantal release of Ca in response to IP(3) or even caffeine in other cells, they highlight that Ca pumps on internal stores are quite effective, at least acutely, in resequestering Ca as it leaves those stores even after exogenous ATP has been removed and with Ca buffers in the cytosol. Certainly this fact should be kept in mind in interpreting quantal release phenomena. Recent work on other single cells has shown that the ability to demonstrate quantal release phenomena is a function of other experimental conditions as well (Ca buffering, Ca indicator affinity, and Ca indicator location(^2); extent of fragmentation of the internal store system(23, 24) ), suggesting that ``quantal release'' may reflect the interplay of the Ca release mechanism with other aspects of Ca store function in the cell. While it may still be that quantal release of Ca at the cellular level is an inherent property of the release mechanism per se, as suggested by the work of Ferris et al.(22) , further carefully controlled work on this intriguing phenomenon needs to be carried out.


FOOTNOTES

*
This work was supported by National Institutes of Health Grant HL14523. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed: Biomedical Imaging Group, Biotech II, 373 Plantation St., Suite 114, Worcester, MA 01605. Tel.: 508-856-6548; Fax: 508-856-1840.

(^1)
The abbreviations used are: IP(3), inositol 1,4,5-trisphosphate; RyR, ryanodine receptor(s); SR, sarcoplasmic reticulum.

(^2)
T. Cheek and C. Taylor, personal communication.


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©1996 by The American Society for Biochemistry and Molecular Biology, Inc.