Effects of External Osmotic Pressure on Vesicular Secretion from Bovine Adrenal Medullary Cells*

(Received for publication, November 11, 1996, and in revised form, January 13, 1997)

Ricardo Borges Dagger , Eric R. Travis §, Spencer E. Hochstetler § and R. Mark Wightman §

From the Dagger  Unidad de Farmacología, Facultad de Medicina, Universidad de La Laguna, 38010 Santa Cruz de Tenerife, Spain and the § Department of Chemistry, University of North Carolina, Chapel Hill, North Carolina 27599-3290

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Secretion of catecholamines from individual vesicles of bovine adrenal medullary cells was studied with amperometry in media of various osmolarities and compared with results obtained in isotonic physiological buffer (315 mosM). Hypotonic solutions caused an increase in the number of amperometric spikes evoked by brief exposure to 5 mM Ba2+. Under moderate hypertonic conditions (630 mosM), individual vesicular events were decreased in frequency, and lower amounts were secreted per event. Furthermore, the events were temporally broadened relative to those observed during release in isotonic conditions. At 970 mosM, exposure to 5 mM Ba2+ evoked even smaller secretory events that resemble the prespike feature that has been attributed to the initial opening of the fusion pore. The lack of large spikes is not due to failure of Ba2+ entry because fura-2 fluorescence reveals an increase in intracellular divalent ions. After exposure to Ba2+ in hypertonic solution, spikes could be induced with isotonic solution transiently directed onto the cell, but this process was not accompanied by a change in the concentration of intracellular divalent ions. Thus, this procedure provides an unique opportunity to temporally separate exocytotic secretion from entry of divalent ions.


INTRODUCTION

Secretory vesicles in chromaffin cells of the adrenal medulla sequester a remarkably high concentration of molecules. The major component, catecholamines, is present at a concentration of 550 mM, but the other vesicular constituents such as ATP (122 mM), Ca2+ (17-30 mM), Mg2+ (5 mM), ascorbate (22 mM), and the acidic protein chromogranin A are also present at high concentrations (1). Because the total soluble concentration of intravesicular components is more than 750 mM, it has long been of interest how these vesicles are able to form stable entities that are isotonic with 300 mosM solutions. It seems from nuclear magnetic resonance studies of intact vesicles that the contents form a dynamic viscous solution that is stabilized by ternary complex formation (2). Solution studies have revealed that catecholamines and ATP associate, resulting in a lowered osmotic pressure (3). Similarly, chromogranin A may play an important role in lowering osmolarity through interactions with Ca2+ and catecholamines (4-7). Such association significantly lowers apparent free concentration, as demonstrated for Ca2+ ions in adrenal medullary vesicles (8).

Whereas intravesicular association stabilizes vesicular storage, upon exocytosis the vesicular contents must dissociate to be extruded from the cell in their soluble form. The osmotic gradient that exists immediately upon cell vesicle fusion between the isotonic extracellular milieu and the vesicle contents certainly plays a role in the overall exocytotic process. Indeed, Knight and Baker (9) showed that sucrose-based hypertonic solutions inhibit the amount of Ca2+-dependent catecholamine secretion, whereas incubation with hypotonic media increases it. Similar results were obtained in other laboratories with cultured cells (10-13) and in perfused adrenals (14) as reviewed by Holz (1). The inhibition of release in hypertonic media seems to be due to a direct effect on the exocytotic process because Ca2+ entry is not inhibited (10). Furthermore, the effects of altered osmolarity are reversible, implying that cell function is not greatly perturbed. Such observations led to the chemiosmotic hypothesis for exocytosis, which proposed that swelling of the secretory vesicles provides the driving force for the fusion of the vesicular and cellular membranes (15). However, this hypothesis has been rejected because simultaneous optical and whole-cell capacitance measurements at mast cells revealed that fusion with the cell membrane actually precedes vesicular swelling (16).

Alterations in the amounts of catecholamine released from populations of cells or intact glands by extracellular solutions of different osmolarities could be due either to an alteration in exocytotic efficiency, i.e. an altered exocytotic frequency, or to an alteration of the amount secreted per exocytotic event. Indeed, an increased osmotic gradient between the cell interior and exterior promotes Ca2+ entry (17), promoting increased frequency of exocytotic events (18). To investigate the other possibility, we have examined the effects of osmotic pressure on catecholamine secretion at bovine adrenal medullary cells with amperometry with carbon fiber microelectrodes, a technique that allows individual exocytotic events to be observed (19). Recent observations of individual vesicle extrusion events made with this approach with a high osmotic gradient have already shown that the degree of association of vesicle contents affects their release (20). Here, we test the hypothesis that extrusion of the vesicular contents can be inhibited by removal of the osmotic gradient. Normally, individual secretory events have a duration of several milliseconds (21-22) and a shape and size that are profoundly affected by the extracellular environment. Factors such as external pH (23-24), temperature (25), and the presence of different cations (25-26) have been shown to alter the time course of release. The results presented here show that decreasing the osmotic gradient not only alters the frequency of exocytotic events but also alters the quantity and time course of release during each event. Furthermore, our results show that elevation of intracellular divalent ions, the major trigger for exocytosis, can be temporally dissociated from the extrusion of the vesicular contents in very hypertonic media.


EXPERIMENTAL PROCEDURES

Adrenal Medullary Cell Culture

Bovine adrenal medullary cells, enriched in epinephrine using a single-step Renografin gradient (27), were prepared from fresh tissue as described previously (28). Cells were plated on 12-mm-diameter glass coverslips (Carolina Biological Supply, Burlington, NC) contained in 35-mm-diameter culture dishes (Falcon 3001; Becton Dickinson, Lincoln Park, NJ) at a density of 6 × 105 cells/plate. Cells were incubated at 37 °C in a 5% CO2 environment and used at room temperature between 2 and 5 days of culture.

Electrochemical Detection of Catecholamines

Carbon fiber microelectrodes for the detection of catecholamine release were prepared as described by Kawagoe et al. (29) using 5-µm-radius carbon fibers (Thornel P-55; Amoco Corp., Greenville, SC). A commercial patch-clamp instrument (Axopatch 200B; Axon Instruments, Foster City, CA) was used for amperometry. The instrument was operated in voltage clamp mode in the whole-cell (beta  = 1) configuration with a command potential of +0.650 V applied versus a locally constructed sodium-saturated calomel reference electrode. Electrodes were backfilled with 4 M NaCl and connected to the headstage input using a patch pipette holder with chlorided silver wire. The noise of this system is one-twentieth of that used in all of our prior work (30). Electrodes were calibrated with a flow-injection apparatus using 50 µM epinephrine.

Glass coverslips with adhering adrenal medullary cells were washed in isotonic (315 mosM) Krebs buffer (see Table I). To obtain rapid changes in the osmolarity of the media bathing the cells, the coverslips were placed in a perfusion chamber positioned on the stage of an inverted microscope (Axiovert 35; Zeiss, Thornwood, NY). Buffer was perfused at 2-5 ml/min, and new solutions were introduced with a valve placed close to the chamber. Amperometric measurements were performed with the carbon fiber microelectrode gently touching the cell membrane. Cells were stimulated to release by pressure ejection (Picospritzer; General Valve Corp., Fairfield, NJ) of 5 mM Ba2+ for 5 s from a micropipette placed 25-30 µm away from the cell. Barium was used as a secretagogue because it does not require receptor activation or membrane depolarization, processes that can be affected by osmotic changes (31).

Table I.

Composition and osmolarities of experimental solutions in which the amount of NaCl or sucrose was altered

Concentrations are given in mM and osmolarities are given in mosM.


Extracellular solution Compositiona Osmolarity

Isotonic 150 NaCl, 5KCl, 1.2 MgCl2, 5 glucose, 10 HEPES 315
Hypotonic 86 NaCl, 5KCl, 1.2 MgCl2, 5 glucose, 10 HEPES 200
Hypertonic I 332 NaCl, 5KCl, 1.2 MgCl2, 5 glucose, 10 HEPES 630
Hypertonic II 386 NaCl, 5KCl, 1.2 MgCl2, 5 glucose, 10 HEPES 750
Hypertonic III 522 NaCl, 5KCl, 1.2 MgCl2, 5 glucose, 10 HEPES 970
Hypertonic IV 435 sucrose, 150 NaCl, 5 KCl, 1.2 MgCl2, 5 glucose, 10 HEPES 850

Data Analysis

Amperometric signals were low-pass filtered at 10 kHz (4-pole Bessel filter on Axopatch 200B) and recorded on 0.5-inch videotape (PCM-2 A/D VCR Adapter; Medical Systems Corp., Greenvale, NY). During analysis, current records were replayed through a 400-Hz low-pass filter and digitized to an IBM compatible personal computer at 1 ms/point (Cyberamp 320 and Axotape; Axon). Exocytotic events were located with locally written software, and the areas of individual current spikes (Q), their amplitudes (imax), and their widths at half-height (t1/2)1 were determined as described previously (32). For evaluation of Q changes the quantity Q1/3, which has a Gaussian distribution, was computed for each spike (33).

Intracellular Measurements of Divalent Ions

The fluorescent probe fura-2 was used as described elsewhere (34-35). Briefly, adrenal medullary cells were incubated in Krebs buffer containing 1 µM fura-2/AM (stock solution dissolved in 20% Pluronic F-127 in Me2SO) and 0.1% bovine serum albumin for 30-40 min at room temperature. After loading, the cell plates were rinsed twice and refilled with the desired Krebs-Ringer buffer. The specimens were alternately excited at 340 and 380 nm through a 40× oil-immersion objective (Zeiss). The results were corrected for electrode autofluorescence and reflectance (34). The ratio of corrected fluorescence values (F340/F380) provided an estimate of concentration changes of intracellular divalent ions. This estimate can be due to changes in Ba2+ or Ca2+, and no attempts were made to distinguish between these two species.

Materials

The culture medium, Dulbecco's modified Eagle's/Ham's F-12 medium, was obtained from Life Technologies, Inc. Collagenase (Type I) for digestion of gland tissue was obtained from Worthington Biochemical. Renografin-60 was obtained from Squibb Diagnostics. Fura-2/AM, fura-2-free acid, and Pluronic F-127 were obtained from Molecular Probes (Eugene, OR). All other chemicals were obtained from Sigma, and reagent-grade salts were dissolved with doubly distilled water to make solutions.

Solutions

Isotonic, hypertonic, and hypotonic solutions were prepared as described in Table I. With all bath and pipette solutions, the pH was adjusted to 7.40 with concentrated NaOH. Hypertonic solutions were made by addition of NaCl or sucrose to achieve the desired osmolarity. Solution osmolarities were checked with a freezing point depression osmometer (Osmette A; Precision Systems, Inc., Natick, MA). For solutions with no Ca2+, CaCl2 was omitted with no MgCl2 or calcium chelators added.


RESULTS

Morphological Changes of Cells Caused by Different Osmotic Solutions

The phase-contrast micrographs in Fig. 1 show the effect of different osmotic pressures on adrenal medullary cells. These experiments were conducted in a manner similar to the method used for vesicular release studies: cells were incubated in isotonic solution for 10 min, the perfusion buffer was changed to the osmotic solution of interest for another 10 min, and finally, isotonic conditions were restored. The micrographs shown were taken 2 min after solution changes.


Fig. 1. Photomicrographs of morphological changes of adrenal medullary cells under different osmotic conditions. Cells pictured here were initially bathed in isotonic buffer solution (315 mosM). The cell buffer chamber was then perfused with the hypotonic or hypertonic solution indicated (200, 450, 700, or 1000 mosM). Finally, cells were returned to isotonic conditions. Photomicrographs were taken 2 min after the osmotic changes. The tip diameter of the microelectrode to the left of each cell is 15 µm.
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Low osmotic strength (200 mosM), obtained by NaCl reduction (hypotonic, Table I), caused a rapid increase in cell volume. This change was immediately reversed upon return to isotonic conditions. In contrast, increased osmolarity (450-1000 mosM) caused cell shrinkage to occur. The changes seemed to be reversible except at 1000 mosM, at which some cells exhibited permanent alterations in their cytoplasmic appearance upon return to isotonic conditions.

Secretory Characteristics with Osmotic Pressure

Fig. 2 shows the effect of decreased and increased osmotic pressure on catecholamine release. In isotonic buffer before a solution change, secretion lasting several minutes was elicited by pressure ejection for 5 s of a 5 mM Ba2+ solution. This result was obtained in Ca2+-free solutions (Fig. 2, A and D) and also in solutions containing Ca2+, as we have previously reported (26). The current spikes observed correspond to the exocytotic release of catecholamines from individual vesicles (19). When the osmolarity of the bathing media was decreased to 200 mosM (hypotonic, Table I), reexposure to Ba2+ in the absence of Ca2+ caused secretory spikes that were more frequent and of increased amplitude (Fig. 2B). When Ca2+ was present, low osmotic pressure caused spontaneous release (data not shown), as previously observed (18). When the cell was returned to isotonic medium, Ba2+-induced spikes were similar (but not identical; Ref. 20) to those obtained before exposure to the decreased osmolarity (Fig. 2C).


Fig. 2. Effects of osmotic changes on vesicular catecholamine release from single cells. Representative amperometric traces showing exocytotic release from individual cells as the osmolarity of the extracellular solution is changed. A single adrenal medullary cell was stimulated with 5 mM Ba2+ under (A) isotonic (315 mosM) conditions. The same cell was then exposed to (B) hypotonic conditions (200 mosM) and finally returned to (C) isotonic (315 mosM) conditions. Secretion evoked by Ba2+ at another cell was monitored in the same manner at (D) 315 mosM, (E) 750 mosM, and (F) 315 mosM. Solutions (isotonic, hypotonic, and hypertonic II, Table I) were made with no external Ca2+ and with NaCl as the osmotic agent.
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In contrast, Ba2+-induced secretion decreased in frequency and amplitude as the osmolarity was increased. Results from a single cell in Ca2+-free media are shown in Fig. 2D-F, in which a cell originally in an isotonic medium was placed in a 750 mosM solution (hypertonic II, Table I). Similar effects were obtained when the osmolarity was elevated by adding sucrose instead of NaCl (Fig. 3) or with high-osmolarity media containing Ca2+ (data not shown). Upon a return to isotonic conditions (Figs. 2F and 3C), every cell secreted similarly as before the osmotic change.


Fig. 3. Effects of sucrose-based hypertonic media on catecholamine secretion. Representative amperometric traces taken at a single adrenal medullary cell showing exocytotic release before, during, and after an increase in the solution osmolarity to 850 mosM by the addition of sucrose (hypertonic IV, Table I). A, Ba2+-induced release under isotonic conditions. B, release after a change to hypertonic conditions. C, release upon return to isotonic conditions.
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The effects of increased osmolarity were studied in detail at 630 mosM (hypertonic I, Table I). Each observed spike was characterized with respect to its average charge (Q), t1/2, and maximal amplitude (imax). The mean characteristics from a single cell are summarized in Table II and show a significant increase in t1/2 and a significant decrease in imax. A histogram of t1/2 values (Fig. 4A) reveals a broader distribution and a greater proportion of wider spikes under hypertonic conditions. In addition, the data show a small but significant decrease in Q (Fig. 4B) for secretion in the medium of higher osmolarity. In each of four cells examined in this way, t1/2 increased significantly, and imax decreased significantly in response to the change from 315 to 630 mosM. In three of the four cells, a statistically significant decrease in Q was observed.

Table II.

Mean spike characteristics measured at a single adrenal medullary cell in isotonic (315 mosM) and moderately hypertonic (630 mosM) extracellular solutions

Table values are mean ± S.E. Statistical significance of Q changes was tested using a t test of Q1/3 values (44). Statistical significance of changes in t1/2 and Imax was tested using the Mann-Whitney test for nonparametric data.


Osmolarity (mosM) Q (pC) t1/2 (ms) Imax (pA) Spike frequency (Hz)

315 2.26  ± 0.14 16.4  ± 0.8 170  ± 10 2.10a
630 1.62  ± 0.15b 46.8  ± 4.4b 77  ± 11b 0.48c

a 504 current spikes over 240 s.
b Means are significantly different (p <=  0.01).
c 218 current spikes over 450 s.


Fig. 4. Histograms for individual spike characteristics t1/2 and Q1/3 at 315 and 630 mosM. Histograms displaying the relative distribution of spike t1/2 values (A) and Q1/3 values (B) measured at a single cell whose mean characteristics at two different external osmolarities are given in Table II. Shaded bars, spikes within each bin range obtained at 315 mosM; black bars, spikes obtained at 630 mosM. This analysis included only spike-shaped amperometric events. Frequency was determined by the number of events in the bin range divided by the total number of events.
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Secretion Induced in Very Hypertonic Media

Spikes were initially induced with Ba2+ in isotonic medium, and then the cells were exposed to solutions with an osmolarity of 970 mosM (Fig. 5A; hypertonic III, Table I). Spikes evoked by Ba2+ were virtually abolished in both the absence (Fig. 5A) and presence of Ca2+ (Fig. 6A). However, in both cases exposure to Ba2+ evoked small current fluctuations (Fig. 5B, upper; Fig. 6B, upper) of similar amplitude to the prespike features or feet that precede some secretory events in isotonic media (21, 36). Such an event is shown in expanded form in Fig. 5A (lower inset). Because the amplifier noise in the measurements reported here is lower than that in our previous work, we were also able to observe similar amperometric fluctuations among the spikes that occurred during evoked secretion in isotonic media (Fig. 5A, upper inset). Such events have been described as flickering feet that lack accompanying spikes (37). Similar small changes in amperometric current after exposure to Ba2+ were also observed in hypertonic media prepared with sucrose as the primary osmolyte (hypertonic IV, Table I).


Fig. 5. Secretion evoked by brief isotonic application under hypertonic conditions. A, current traces from a single cell showing the effect of osmolarity on release. The upper and lower traces correspond to release at 315 mosM before and after a change to 970 mosM (middle trace). Horizontal bar, the time during which the Ba2+ stimulating solution was administered to the cell. Upper inset, an expanded view of spikes and low amplitude foot-like events observed after Ba2+ stimulation at 315 mosM. Lower inset, an expanded view of a stand-alone foot after Ba2+ stimulation at 970 mosM. B, response of the cell shown in A to a 15-s pressure ejection of hypertonic Ba2+ (upper trace) and 45 s later to a 15-s isotonic solution under hypertonic (970 mosM) conditions. Solutions used (isotonic and hypertonic III, Table I) contained no external Ca2+ and had NaCl as the osmotic agent.
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Fig. 6. Role of Ca2+ in isotonically induced secretion under hypertonic conditions. A, isotonic-induced release after Ba2+ stimulation under hypertonic (970 mosM) conditions in the presence of 2 mM external Ca2+. B, isotonic-induced release after Ba2+ stimulation under hypertonic (970 mosM) conditions in the absence of external Ca2+ (note the difference in the current scales). C, time course of intracellular divalent cations determined by fura-2 in hypertonic (970 mosM) extracellular medium containing 2 mM Ca2+. Ratios were collected at 400 ms/point. D, time course of intracellular divalent cations determined by fura-2 in hypertonic (970 mosM) extracellular medium without Ca2+. Ratios were collected at 240 ms/point, and a three-point moving average was applied.
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When the cells were returned to an isotonic medium that was Ca2+-free, the base line remained unchanged. However, a change from hypertonic medium with Ca2+ to isotonic medium with Ca2+ induced massive secretion that began about 1 min after the medium change and continued for many minutes (data not shown). Consistent with results obtained by Wakade et al. (17) with perfused adrenal glands, this phenomenon was only found to occur in the presence of external Ca2+. Both with and without Ca2+, subsequent exposure to Ba2+ induced secretion in every case, but occasionally release was of lower frequency than before exposure to the very hypertonic medium.

Secretion Induced by Isotonic Ca2+-free Medium

Although cells exposed to Ba2+ showed few spikes in very hypertonic media, it was found that a 15-s pressure ejection of isotonic solution onto the cells could evoke frequent spikes (Fig. 5B). In these experiments, a three-barrel ejection pipette was used containing isotonic buffer, 5 mM BaCl2 in isotonic buffer, and 5 mM BaCl2 in hypertonic buffer. Catecholamine release from single cells was first measured in isotonic solution, in which exposure to 5 mM isotonic Ba2+ induced release for several minutes. As expected, pressure ejection of isotonic buffer onto cells bathed in isotonic buffer did not cause amperometric current fluctuations. After exposure of the same cell to Ba2+ in a medium of 970 mosM and observation of the small current events, the cell was exposed to isotonic buffer. During the pressure ejection the spikes increased in frequency and reached a maximum at the end of the pressure ejection period (n = 15 cells). Similar results were obtained in the presence and absence of external Ca2+. Interestingly, spikes obtained from isotonic application in Ca2+-free hypertonic buffer were somewhat smaller in amplitude (Fig. 6, A and B; note the difference in the current scales).

Role of Intracellular Divalent Cations

The role of intracellular divalent ions in these processes in hypertonic solutions (n = 6 cells) was examined with the fluorescent probe fura-2 (35). During application of Ba2+ in hypertonic media (970 mosM), fura-2 ratio measurements indicated an influx of divalent cations (note that fura-2 complexes both Ba2+ and Ca2+). Similar to previous results under isotonic conditions (26, 31), this response was obtained in the presence and absence of extracellular Ca2+ (Fig. 6, C and D, respectively). The increase was immediate and sustained for several minutes and occurred during the time interval in which the small current features were observed in the amperometric recordings. The subsequent pressure ejection of isotonic buffer onto these cells was not accompanied by a significant change in the fluorescent ratio. In some cells (i.e. Fig. 6C) small changes in the ratio were observed. However, inspection of the fluorescent recordings at the individual wavelengths showed that this was due to small differences that occurred in the decrease in fluorescence at both wavelengths. The decrease is due to a transient dye dilution as a result of cell expansion during exposure to the isotonic solution followed by its subsequent contraction.


DISCUSSION

Adrenal medullary cells respond as osmometers (10) that swell in hypotonic solutions and shrink in hypertonic media (Fig. 1). Despite the changes in cell volume, cells continue to secrete over a broad range of osmotic strengths. Prior results have demonstrated that under extreme hypertonic conditions, catecholamine secretion from adrenal medullary cells can be inhibited (9-12, 14). The results of the present study with amperometry support these findings and provide new insight into the origin by examining this effect at the level of individual vesicular events. The results show that the external osmolarity can have a dramatic effect on the time course of extrusion of the vesicular contents: in hypotonic solutions extrusion from the vesicles is more rapid than in isotonic medium (20), whereas hypertonic solutions slow the extrusion process until it virtually ceases at very high osmolarity.

It has long been recognized that the high concentration of catecholamines and other intravesicular components in adrenal medullary cells requires some form of internal association to reduce osmotic forces (3, 38). Experiments with amperometric detection of catecholamine secretion from individual vesicles show that the extrusion process is temporally prolonged even in isotonic medium (19, 32), consistent with a finite time required for dissociation of the intravesicular components (21). Even at 37 °C the mean half-width of secretory events exceeds 4 ms (25). The secretory spikes are found to change in shape with the pH and ionic composition of the extracellular media. Acidification of the external media to a pH of 5.5 makes extrusion of the vesicle contents more difficult (23), whereas spikes induced by Ba2+ are broader and shorter in the absence of external Ca2+ (26). Exposure of adrenal medullary cells to extracellular Zn2+, an ion that can further cross-link the vesicle contents, lowers the quantity of catecholamine released during secretory events (25). The findings reported here, that a lowered osmotic gradient between the vesicle contents and the extracellular fluid also increases the time course of vesicular dissociation, are consistent with prior conclusions that the mechanism of storage of the vesicle contents is manifested in the kinetics of individual secretory events. Thus, the osmotic gradient present in isotonic medium immediately after cell-vesicle fusion promotes water entry through the fusion pore into the vesicular matrix, where it elicits the dissolution of the intravesicular contents (39).

Because secretion characteristics can vary from cell to cell, we minimized this effect by allowing each cell to serve as its own control. With the exception of the most hypertonic solutions, the osmotic changes did not permanently alter the cells because secretion was similar before and after osmotic stress. Furthermore, the observed changes are a direct consequence of solution osmolarity because similar results were obtained with NaCl and sucrose media. We used Ba2+ as a secretagogue rather than one that interacts with cell receptors to avoid possible altered affinities of receptor states.

In solutions of intermediate hyperosmolarity (630 mosM) the spike frequency is reduced as well as the amount released in each spike. It is likely that the decreased amounts of secretion seen from populations of cells (1) are due to the lower spike frequency because it is decreased to a greater degree. However, at osmolarities comparable to the osmolarity calculated for the unassociated contents of the vesicles, spikes are virtually eliminated. Because occurrence of spikes only provides information on the last stage of exocytosis, the extrusion of the vesicle contents, we can only conclude that secretion has been arrested but cannot evaluate whether it is arrested at this stage or at a prior one. However, it seems that the extrusion process is the stage in a single exocytotic event that is the most sensitive to external solution osmolarity because cell-vesicle fusion is not inhibited by high osmolarity (16). Furthermore, most vesicular expansion seems to occur only after granule fusion (40), although a small enlargement may occur before fusion (41). Indeed, capacitance measurements in mast cells show that the time course of vesicle-cell fusion is little affected by the external solution osmolarity, even though the vesicular size is a function of external osmolarity (42).

In sufficiently hypertonic solutions, amperometric spikes are rarely observed upon exposure to Ba2+, but small secretory events that resemble the prespike feature can be observed. The prespike feature, found before many secretory spikes in isotonic solution, has been attributed to catecholamine flux through the fusion pore formed in the initial stages of adrenal medullary cell-vesicle fusion (20, 36). As recently reported, these states can be observed without spikes and often flicker as would be expected for flux through a pore of fluctuating diameter (37). In very hypertonic medium, in which fura-2 measurements show that Ba2+ entry into the cell still occurs, these features persist without spikes, suggesting that cell-vesicle fusion has occurred without subsequent extrusion of the cell contents. In other words, the absence of an osmotic gradient seems to have frozen the exocytotic process in a transient state that prevents secretion. This transient state has been observed in mast cells (24), and it appears under conditions in which partial secretory events (43) can be observed. Thus, by analogy, the intermediate state consists of a docked vesicle with a fusion pore open to the external media that releases a small portion of its contents without full dissolution of the entire contents from the granule matrix.

To test this hypothesis, we transiently exposed cells containing internal Ba2+ in hypertonic solution to isotonic solution to restore the normal osmotic gradient between the vesicle contents and the solution. Transient restoration of an osmotic gradient caused a series of secretory spikes that are consistent with the hypothesis that fused vesicles with their contents intact are present at the cell surface. This effect was obtained with or without Ca2+ in solution, and in both cases the occurrence of spikes was not accompanied by a change in the internal concentration of divalent ions. However, the data suggest that ionic effects as well as osmotic effects are important for complete extrusion of the vesicle contents. This is evidenced by the fact that the presence of Ca2+ in the external medium leads to spikes induced by isotonic solution that are of increased amplitude. This result is entirely consistent with our previous finding in isotonic medium that Ba2+-induced spikes are of greater amplitude in Ca2+-containing solutions (26). It seems that hydrated Ca2+ can promote more rapid dissolution of the vesicle contents. Catecholamine release upon complete restoration of isotonic conditions after hypertonic treatment from hypertonic to isotonic conditions causes an increase in the rate of opening of voltage-activated Ca2+ channels (17, 18). Our results with transient isotonic exposure differ in that secretion is not accompanied by an increase in internal Ca2+ or Ba2+. Indeed, these results represent the first time that entry of divalent cations and exocytotic secretion have been separated on a time scale of several minutes.

Taken together with previous findings, the results of this study clearly show that the associated state of the vesicle contents manifests itself during the extrusion of the vesicle contents after vesicle-cell fusion in adrenal medullary cells. In mast cells, in which the intravesicular association has significant ionic character (44), this has been quite clearly demonstrated because the vesicles are large enough for visual observation. Swelling of mast cell matrices increases ionic conductivity and allows the contents to be released (45). Our findings in this work show that an osmotic gradient that could swell the vesicle contents is required to obtain fully developed secretory spikes at adrenal medullary cells. Although pH and ionic gradients clearly must also play a role in dissociating the vesicle contents, the ease of manipulating osmolarity, coupled to the fact that it does not inhibit vesicle-cell fusion, makes this a particularly useful parameter to separate the individual stages during an exocytotic event. In addition, experiments with sucrose as the primary osmolyte clearly demonstrate that an ionic gradient is not sufficient to cause dissociation of the vesicle contents. The temporal separation of entry of divalent cations and secretion provides the opportunity to further investigate the individual steps in the complex phenomenon of exocytosis.


FOOTNOTES

*   This research was supported by a grant from the Office of Naval Research (to R. M. W.) and DGICYT (to R. B).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
   To whom correspondence should be addressed: Dept. of Chemistry, CB #3290, University of North Carolina, Chapel Hill, NC 27599-3290. Tel.: 919-962-1472; Fax: 919-962-2388.
1   The abbreviation used is: t1/2, width at half-height.

ACKNOWLEDGEMENTS

The aid of Timothy J. Schroeder and Jennifer M. Finnegan in this work is gratefully acknowledged.


REFERENCES

  1. Holz, R. W. (1986) Annu. Rev. Physiol. 48, 175-189 [CrossRef][Medline] [Order article via Infotrieve]
  2. Daniels, A. J., Williams, R. J. P., and Wright, P. E. (1978) Neuroscience 3, 573-585 [Medline] [Order article via Infotrieve]
  3. Kopell, W. N., and Westhead, E. W. (1982) J. Biol. Chem. 257, 5707-5710 [Abstract/Free Full Text]
  4. Helle, K. B., Reed, R. K., Pihl, K. E., and Serck-Hanssen, G. (1985) Acta Physiol. Scand. 123, 21-33 [Medline] [Order article via Infotrieve]
  5. Yoo, S. H., and Albanesi, J. P. (1991) J. Biol. Chem. 266, 7740-7745 [Abstract/Free Full Text]
  6. Yoo, S. H., and Lewis, M. S. (1992) J. Biol. Chem. 267, 11236-11241 [Abstract/Free Full Text]
  7. Videen, J. S., Mezger, M. S., Chang, Y.-M., and O'Connor, D. T. (1992) J. Biol. Chem. 267, 3066-3073 [Abstract/Free Full Text]
  8. Haigh, J. R., Parris, R., and Phillips, J. H. (1989) Biochem. J. 259, 485-491 [Medline] [Order article via Infotrieve]
  9. Knight, D. E., and Baker, P. F. (1982) J. Membr. Biol. 68, 107-140 [Medline] [Order article via Infotrieve]
  10. Hampton, R. Y., and Holz, R. W. (1983) J. Cell Biol. 96, 1082-1088 [Abstract/Free Full Text]
  11. Pollard, H. B., Pazoles, C. J., Creutz, C. E., Scott, J. H., Zinder, O., and Hotchkiss, A. (1984) J. Biol. Chem. 259, 1114-1121 [Abstract/Free Full Text]
  12. Ladona, M. G., Bader, M. F., and Aunis, D. (1987) Biochim. Biophys. Acta 927, 18-25 [Medline] [Order article via Infotrieve]
  13. Holz, R. W., and Senter, R. A. (1986) J. Neurochem. 46, 1835-1842 [Medline] [Order article via Infotrieve]
  14. Ladona, M. G., Sánchez-García, P., and García, A. G. (1984) Neuroscience 12, 301-307 [Medline] [Order article via Infotrieve]
  15. Baker, P. F., and Knight, D. E. (1984) Biosci. Rep. 4, 285-298 [Medline] [Order article via Infotrieve]
  16. Zimmerberg, J., Curran, M., Cohen, F. S., and Brodwick, M. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 1585-1589 [Abstract]
  17. Wakade, A. R., Malhotra, R. K., Sharma, T. R., and Wakade, T. D. (1986) J. Neurosci. 6, 2625-2634 [Abstract]
  18. Moser, T., Chow, R. H., and Neher, E. (1995) Pfluegers Arch. Eur. J. Physiol. 431, 196-203
  19. Wightman, R. M., Jankowski, J. A., Kennedy, R. T., Kawagoe, K. T., Schroeder, T. J., Lesczyszyn, D. J., Diliberto, E. J., Jr., Near, J. A., and Viveros, O. H. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 10754-10758 [Abstract]
  20. Schroeder, T. J., Borges, R., Finnegan, J. M., Pihel, K., Amatore, C., and Wightman, R. M. (1996) Biophys. J. 70, 1061-1068 [Abstract]
  21. Wightman, R. M., Schroeder, T. J., Finnegan, J. M., Ciolkowski, E. L., and Pihel, K. (1995) Biophys. J. 68, 383-390 [Abstract]
  22. Walker, A., Glavinovic, M. I., and Trifaro, J.-M. (1996) Pfluegers Arch. Eur. J. Physiol. 431, 729-735 [CrossRef]
  23. Jankowski, J. A., Schroeder, T. J., Ciolkowski, E. L., and Wightman, R. M. (1993) J. Biol. Chem. 268, 14694-14700 [Abstract/Free Full Text]
  24. Monck, J. R., Oberhauser, A. F., Alvarez de Toledo, G., and Fernández, J. M. (1991) Biophys. J. 59, 39-47 [Abstract]
  25. Pihel, K., Travis, E. R., Borges, R., and Wightman, R. M. (1996) Biophys. J. 71, 1633-1640 [Abstract]
  26. Jankowski, J. A., Finnegan, J. M., and Wightman, R. M. (1994) J. Neurochem. 63, 1739-1747 [Medline] [Order article via Infotrieve]
  27. Moro, M. A., López, M. G., Gandía, L., Michelena, P., and García, A. G. (1990) Anal. Biochem. 185, 243-248 [Medline] [Order article via Infotrieve]
  28. Leszczyszyn, D. J., Jankowski, J. A., Viveros, O. H., Diliberto, E. J., Jr., Near, J. A., and Wightman, R. M. (1990) J. Biol. Chem. 265, 14736-14737 [Abstract/Free Full Text]
  29. Kawagoe, K. T., Zimmerman, J. B., and Wightman, R. M. (1993) J. Neurosci. Methods 48, 225-240 [CrossRef][Medline] [Order article via Infotrieve]
  30. Cahill, P. S., Walker, Q. D., Finnegan, J. M., Mickelson, G. E., Travis, E. R., and Wightman, R. M. (1996) Anal. Chem. 68, 3180-3186 [CrossRef][Medline] [Order article via Infotrieve]
  31. Rüden, L. V., García, A. G., and López, M. G. (1993) FEBS Lett. 336, 48-52 [CrossRef][Medline] [Order article via Infotrieve]
  32. Schroeder, T. J., Jankowski, J. A., Kawagoe, K. T., Wightman, R. M., Lefrou, C., and Amatore, C. (1992) Anal. Chem. 64, 3077-3083 [Medline] [Order article via Infotrieve]
  33. Finnegan, J. M., Pihel, K., Cahill, P. S., Huang, L., Zerby, S. E., Ewing, A. G., Kennedy, R. T., and Wightman, R. M. (1996) J. Neurochem. 66, 1914-1923 [Medline] [Order article via Infotrieve]
  34. Finnegan, J. M., and Wightman, R. M. (1995) J. Biol. Chem. 270, 5353-5359 [Abstract/Free Full Text]
  35. Grynkiewicz, G., Poenie, M., and Tsien, R. Y. (1985) J. Biol. Chem. 260, 3440-3450 [Abstract]
  36. Chow, R. H., von Rüden, L., and Neher, E. (1992) Nature 356, 60-63 [CrossRef][Medline] [Order article via Infotrieve]
  37. Zhou, Z., Misler, S., and Chow, R. H. (1996) Biophys. J. 70, 1543-1552 [Abstract]
  38. Winkler, H., and Smith, A. D. (1975) in Handbook of Physiology, Endocrinology VI (Blaschko, A., Sayers, G., and Smith, A. D., eds), pp. 321-339, American Physiological Society, Bethesda, MD
  39. Verdugo, P. (1990) Annu. Rev. Physiol. 52, 157-176 [CrossRef][Medline] [Order article via Infotrieve]
  40. Terakawa, S., Manivannan, S., and Kumakura, K. (1993) J. Physiol. 87, 209-213
  41. Ornberg, R. L., Furuya, S., Goping, G., and Kuijpers, G. A. J. (1995) Cell Tissue Res. 279, 85-92 [CrossRef][Medline] [Order article via Infotrieve]
  42. Brodwick, M. S., Curran, M., and Edwards, C. (1992) J. Membr. Biol. 126, 159-169 [Medline] [Order article via Infotrieve]
  43. Alvarez de Toledo, G., Fernández-Chacón, R., and Fernández, J. M. (1993) Nature 363, 554-558 [CrossRef][Medline] [Order article via Infotrieve]
  44. Uvnäs, B., and Åborg, C.-H. (1989) News Physiol. Sci. 4, 68-71 [Abstract/Free Full Text]
  45. Nanavati, C., and Fernandez, J. M. (1993) Science 259, 963-965 [Medline] [Order article via Infotrieve]

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