From the * Laboratory of Cellular and Molecular Biophysics, A graded response to calcium is the defining feature of calcium-regulated exocytosis. That is, there
exist calcium concentrations that elicit submaximal exocytotic responses in which only a fraction of the available
population of secretory vesicles fuse. The role of calcium-dependent inactivation in defining the calcium sensitivity of sea urchin egg secretory vesicle exocytosis in vitro was examined. The cessation of fusion in the continued
presence of calcium was not due to calcium-dependent inactivation. Rather, the calcium sensitivity of individual
vesicles within a population of exocytotic vesicles is heterogeneous. Any specific calcium concentration above
threshold triggered subpopulations of vesicles to fuse and the size of the subpopulations was dependent upon the
magnitude of the calcium stimulus. The existence of multiple, stable subpopulations of vesicles is consistent with a
fusion process that requires the action of an even greater number of calcium ions than the numbers suggested by
models based on the assumption of a homogeneous vesicle population.
In many calcium-regulated exocytotic systems, the response to increasing concentrations of intracellular calcium is characterized by a sigmoidal relationship between exocytosis and calcium concentration (reviewed
in Knight and Scrutton, 1986 In the sea urchin, Strongylocentrotus purpuratus, 50%
of the vesicles fuse in response to ~20 µM free calcium
(Vogel et al., 1996 Models have been proposed for synaptic transmission
and neuroendocrine secretion that attempt to quantitatively relate the extent and/or rate of exocytosis to the
calcium concentration (Dodge and Rahamimoff, 1967 Cortical degranulation in the sea urchin egg isolated
planar cortex, an example of calcium-triggered exocytosis, is such a preparation (Vacquier, 1975 No evidence was found to support the hypothesis
that calcium-dependent inactivation is responsible for
the cessation of fusion (submaximal responses). The
hypothesis that the calcium sensitivity of secretory vesicle exocytosis in vitro is heterogeneous before initiating fusion was consistent with the data. A decrease in the number of vesicles within a fusing subpopulation
was the only limiting process identified.
Specimens of the sea urchins, Strongylocentrotus purpuratus and
Lytechinus pictus were purchased from Marinus, Inc. (Long Beach,
CA) and maintained at 10 and 15°C in aquaria, respectively. Eggs
were obtained by intracoelomic injection of 0.5 M KCl and collected in artificial sea water (Instant Ocean; Aquarium Systems, Mentor, OH). Eggs were dejellied mechanically by passage through a 90 (S. purpuratus) or 110 (L. pictus) µm pore size nylon mesh, washed three times in large volumes of artificial sea water, allowed to settle in a large beaker that minimized packing, and held at 16°C in artificial sea water. An aliquot of the egg suspension was
deposited onto poly-L-lysine-treated (250 µg/ml) cover slips and
the eggs were allowed to settle and attach to the coverslip over a
2-5-min period. The cover slip was rinsed with shearing medium:
50 mM piperazine-ethane sulfonic acid, K-PIPES (Sigma Chemical
Co., St. Louis, MO), 425 mM potassium chloride (Mallinckrodt, Inc., Paris, KY), 3 mM hydroxyethyl-ethylenediamine-triacetic acid
(HEDTA; Sigma Chemical Co.), 3 mM EGTA (Fluka Chemical
Corp., Ronkonkoma, NY), 3 mM nitrilotriacetic acid (NTA; Fluka
Chemical Corp.), and 1 mM benzamidine (Sigma Chemical Co.),
pH 6.7 adjusted with potassium hydroxide (Mallinckrodt, Inc.).
Later experiments used a modified calcium buffer containing 6 mM
HEDTA, 6 mM EGTA, and 3 mM NTA. The exocytotic response
to defined calcium concentrations was identical using either
buffer composition. A stream of 2-5 ml of shearing medium produced from a hand-held syringe with a 19-gauge needle was used
to shear the attached eggs. This procedure resulted in an attached layer of plasma membrane with bound cortical vesicles
(Vacquier, 1975 Solutions with defined calcium concentrations were prepared
by adding CaCl2 (0.1000 ± 0.0005 mol/liter calcium standard;
Orion Research, Cambridge, MA) to shearing medium (0-7 mM
final concentration). Calcium activities were measured at room
temperature (21-24°C) with calcium-specific electrodes (TIPCA,
Kwik Tip; World Precision Instruments, Inc., Sarasota, FL) calibrated against calcium standards. Solutions prepared according
to Tsien and Rink (1980) Fast perfusion of solutions was achieved using a flow chamber
specifically designed for use with multiple solution exchange protocols (Kaplan et al., 1991 Cortical vesicle fusion was calculated from changes in the forward light scattering intensity. The scattered intensity is proportional to the number of cortical vesicles present in the monolayer
of cortices: the scattered intensity decreases as the number of
cortical vesicles decreases (Zimmerberg et al., 1985 The data obtained from 188 egg preparations (111 S. purpuratus and 77 L. pictus) over a 3-yr period are presented in this study.
The results from a total of 94 double challenges (68 S. purpuratus
and 26 L. pictus) are reported. Curve fitting was performed using
the Levenburg-Marquardt algorithm with Pearson Minimization as implemented in TableCurve 2D software (Windows v2.0; Jandel Scientific, Corte Madera, CA). Derivative curves were calculated from percent fusion versus time using third-order forward
differences and smoothed using a low-pass filter as implemented
in SigmaPlot (Windows v2.0). No seasonal or yearly differences
in exocytosis were observed except at the end of the season, when
large decreases in calcium sensitivity and loss of resistance to
shear were sometimes observed. Data from the end of the season
were not included in the analysis. Decreases in the calcium sensitivity of the cortex during the first few minutes after shearing
have been reported (Moy et al., 1983 Intermediate calcium concentrations lead to stable,
submaximal responses in the extent of fusion (Fig. 1 A).
The loss of vesicles with time cannot be described by a
single exponential process. Differences in the fusion
time course after normalization of the fusion data to
the submaximal extents of fusion indicate that the kinetics of the vesicles that take part in the fusion process depend upon the calcium concentration (Fig. 1 B).
There appears to exist an absolute threshold in calcium
concentration (~5 µM) below which no vesicle fusion
was observed. The fusion kinetics are faster, and higher
calcium concentrations are required for comparable
extents of fusion with L. pictus compared with S. purpuratus (Fig. 2 A). For each species studied, the transition
from 0 to 100% fusion occurs over a narrow range of
calcium concentrations. Well after the time required
to establish a spatially and temporally invariant calcium
concentration, there exists an inflection point in the
%fusion-vs.-time curve such that the instantaneous rate of fusion, d(%fusion)/dt, is maximum. The rate of fusion increases, peaks at this maximum rate, and then
decreases in the presence of a defined, spatially and
temporally invariant, concentration of calcium: the rate
of fusion does not decrease monotonically with time
(Fig. 2 B). However, this kinetic feature can be obscured when the rate (derivative) curve is too noisy, the
phase occurs within a time period comparable to the
solution turnover in the chamber, or the temporal resolution is too low. For example, the early kinetic behavior of L. pictus was easily observed using a higher sampling rate (20 ms/point) compared with the typical sampling rate ( Computational Biology and Engineering Laboratory,
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
; Knight and Baker, 1987
). There exist calcium concentrations that can elicit submaximal exocytotic responses in which only a fraction
of the available population of secretory vesicles fuse,
despite prolonged exposure to calcium concentrations
exceeding a threshold value. Since exocytosis is an irreversible secretion of concentrated products, submaximal exocytotic responses cannot be explained with single, linear reaction schemes because the irreversible
step will collect, in time, the entire population. We
have examined the origin of submaximal exocytotic responses because (a) differentiation between hypotheses that attempt to explain this behavior is required for
the development of correct secretory models; (b) it is a
feature common to calcium-triggered exocytotic systems, including synaptic transmission and neuroendocrine secretion; and (c) the goal of relating specific
proteins with steps in the exocytotic process can only
proceed if the steps in the process are correctly identified and characterized in detail.
). In this paper, we consider two general hypotheses to explain why only a fraction of the
vesicles fused. The first hypothesis is that an initially homogeneous population of cortical vesicles is inactivated
after the initiation of the fusion process such that only
a fraction fuse. The second hypothesis is that the population of cortical vesicles is heterogeneous in their response to calcium before the application of calcium,
such that different subpopulations of vesicles enter the
fusion process, depending upon the magnitude of the
calcium stimulus.
;
Llinas et al., 1976
, 1981
; Simon and Llinas, 1985
;
Zucker and Fogelson, 1986
; Heinemann et al., 1993
,
1994
). Modeling the exocytotic response often requires
the inclusion of calcium-dependent steps distinct from
the actual fusion step. These steps may be dependent
upon temporal and spatial properties of the calcium
concentration that obscure the underlying relationship
between calcium and exocytosis. Preparations that reduce the degree of complexity are attractive systems for
investigating the relationship between calcium and
exocytosis.
; Baker and
Whitaker, 1978
; Zimmerberg et al., 1985
; reviewed in
Jackson and Crabb, 1988
; Vogel et al., 1991
; Zimmerberg et al., 1993
). It is ideal for these studies because
the exocytotic response to calcium is sigmoidal, vesicles are "pre-docked," endocytosis does not occur, and calcium-triggered exocytosis occurs in the absence of
ATP, GTP, and all other soluble factors and proteins.
Vesicle exocytosis is neither influenced by nor dependent upon interconversion between different spatially localized "pools" or compartments. In other systems,
complications such as the temporal overlap of exocytosis and endocytosis, or the loss of cytosolic factors, "rundown," make the origin of submaximal responses difficult to evaluate. For example, the interpretation of
membrane capacitance changes during exocytosis is
strongly dependent upon differentiation of vesicle
transport between "reserve" and readily releasable compartments and from endocytosis (Heinemann et al.,
1994
), and manipulating the submaximal state in certain permeabilized cell preparations is limited by the
loss of factors required for exocytosis (Sarafian et al.,
1987
).
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
), known as the planar isolated cortex.
, and commercial solutions (CALBUF-1;
World Precision Instruments, Inc.) gave the same calibration
curves. The voltage response of the calcium electrodes was linear
over the pCa range 7.0-3.0. The standard error for any single
pCa determination was typically <0.1 pCa U. The standard error
for averaged data was always <0.1 pCa U and was typically <0.05
pCa U.
, 1996
; Zimmerberg et al., 1992
). The
original perfusion system was modified for use with four solutions instead of two. Four valves were used for solution delivery,
two for solution removal, and two were used to toggle the vacuum lines for rapid exchange of fluid. Unstirred layers were minimized using flow rates fast enough to generate turbulent flow
within the chamber. Solution exchange at the cover slip surface
was estimated to be <200 ms based on the pH-dependent shift in
the fluorescence of coverslips coated with fluorescein-conjugated
albumin (Kaplan et al., 1996
). Later experiments used a modified perfusion system using unidirectional solution exchange
within the flow chamber.
). An upright
microscope fitted with a photodiode detector was used as the
light scattering photometer. The combination of a darkfield condenser (0.63 numerical aperture) and a low numerical aperture objective (0.22 numerical aperture) provided conical collection over scattering angles ranging from ~10-40 degrees. Light scattering was normalized using the initial and final intensities measured in the absence of calcium and after exposure to a high calcium concentration (>300 µM). 100 and 0% fusion correspond
to 0 and 1 normalized light scattering, respectively. Exposure of
the cortices to high calcium concentrations resulted in the fusion
of essentially every cortical vesicle present. The probed monolayer consisted of 20-40 cortices, resulting in a signal that represented the scattering behavior of ~106 cortical vesicles. The entire apparatus was located in rooms maintained at ~16°C. Differences in the free calcium concentration of solutions measured at
room temperature but used at 16°C were estimated using the
program Maxchelator (v6.95, BERS constants; program provided
by Chris Patton, cpatton{at}stanford.edu) and found to be less
than the standard error for pCa determination.
; Sasaki and Epel, 1983
; Zimmerberg et al., 1985
). Stable conditions were achieved by waiting
10 min after shearing before initiating the solution exchange
protocols. The origin of the decrease in calcium sensitivity during the first few minutes after shearing is not understood.
RESULTS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
100 ms/point). The maximum rate of
fusion in previously unchallenged cortices increases
with increasing calcium concentration, while the time
to reach the maximum rate decreases with increasing calcium concentration (Fig. 1 B). The increase in the
maximum rate of fusion with increasing calcium concentration is consistent with the previously observed increase in the inverse half time (Zimmerberg et al.,
1985
). What process(es) could limit the extent and instantaneous rate of fusion in the continued presence of calcium?
View larger version (19K):
[in a new window]
Fig. 1.
(A) Percent fusion vs. time. Four different calcium
concentrations are represented (35, 14, 10, and 5 µM). In this example, a calcium concentration of 5 µM was below the threshold
for fusion. The data were collected using a sample time of 0.1 s.
(B) Normalization of the fusion data to the submaximal extents of
fusion for 10, 14, and 35 µM calcium. Differences in the fusion
time course after normalization indicate that the kinetics of the
vesicles that take part in the fusion process depend upon the calcium concentration.
View larger version (15K):
[in a new window]
Fig. 2.
(A) Percent fusion vs. time, species differences. For
comparable extents of fusion, L. pictus requires higher calcium
concentration than S. purpuratus. The data were collected using a
sample time of 0.02 (L. pictus) and 0.1 (S. purpuratus) s. (B) Rate,
d(%fusion)/dt vs. time in the continued presence of calcium. The
maximum rate of fusion is larger and occurs earlier in L. pictus
compared with S. purpuratus. The data were low-pass filtered with a
1.0 Hz cutoff frequency before calculating the derivative using
third order forward differences.
The submaximal fusion response is not limited by an irreversible loss in the ability of the remaining vesicles to fuse. For example, the continued presence of elevated calcium for 30 min had no effect on subsequent fusion (Fig. 3). In every preparation studied, the remaining population of vesicles fused after the addition of a high calcium concentration (>300 µM), independent of the time and sequence of solution challenges. Permanent inactivation of the remaining vesicles was never observed under the conditions described in this report. The calcium sensitivity of unfused vesicles surviving after submaximal stimulation is not altered by the continued presence of calcium. This rules out hypotheses relying on calcium-dependent irreversible transitions of the fusion apparatus to an inactive state.
|
If the cessation of fusion was due to a reversible, calcium-dependent inactivation of the fusion machinery, then returning the preparation to a lower calcium concentration should reset the fusion process. Upon reset, a second exposure to the initial calcium concentration should result in fusion of the remaining vesicles to the same fractional extent as observed previously. This property was not observed. Once the stable, submaximal response was reached, enhanced fusion did not occur when cortices were challenged with a second application of the same calcium concentration after incubation in nominally zero calcium (<0.3 µM) from 0 to 30 min (Fig. 4). The calcium sensitivity of unfused vesicles surviving after submaximal stimulation is not altered by the absence of calcium. The fusion process cannot be reset and does not respond to the same calcium challenge elicited by two identical pulses separated in time by up to 30 min. The decrease in the instantaneous rate of fusion to zero in the continued presence of calcium, characteristic of a stable, submaximal extent of fusion, cannot be attributed to reversible, calcium-dependent inactivation of the fusion apparatus.
|
If the cessation of fusion occurs because a specific subpopulation of vesicles is removed through fusion (heterogeneity), then only perfusion with higher calcium concentrations will enhance fusion. In the absence of other processes, the amount of fusion will be additive and only depend upon the final concentration of calcium reached. Enhanced fusion was obtained, with or without an intervening chelator wash, only when the calcium concentration of the second challenge was raised. Large variations in vesicle exocytosis among the 20-40 cortices in the probed monolayer were not observed. Degranulation occurred in all cortices after a calcium challenge above threshold. The fusion rate observed after a second challenge of higher calcium concentration was variable relative to the fusion rate observed after a single challenge of the same final calcium concentration: rates after the second challenge were less than, equal to, or greater than those seen with single challenge experiments. Nevertheless, the extent of fusion was additive, with the overall extent dependent only on the calcium concentration of the final challenge (Fig. 5, and see Fig. 7 A).
|
|
In the isolated planar cortex, after a critical period
during which removal of calcium is known to leave vesicles that are competent to fuse upon reapplication of the
same calcium concentration (Zimmerberg et al., 1985),
fusion to the stable, submaximal response is observed
independent of the presence or absence of calcium. Small (<4%) differences in fusion were occasionally
observed when the response to the first calcium challenge had not yet reached a plateau value at the time of
the second calcium challenge (Fig. 6 A). The small
changes in fusion that occur during this time could be
mistakenly attributed to solution challenges in the absence of a continuous record of fusion. The absence of
any abrupt change in fusion, with or without an intervening chelator wash, is consistent with the interpretation that the second challenge occurred during the
time when previously activated vesicles, irreversibly
committed to the fusion process, are fusing. In contrast, abrupt changes in fusion are observed only when
calcium is removed before irreversible commitment to
the fusion process (Fig. 6 B). The importance of acquiring a continuous fusion record cannot be overemphasized because changes in fusion observed during the
calcium-independent period could be mistakenly attributed to additional interventions such as the removal
or addition of a calcium challenge (see DISCUSSION).
|
The results from single and double challenges are
summarized in the calcium activation curve (Fig. 7 A).
The single and double challenge data were fit by a log-normal cumulative distribution function % fusion = 50 · erfc{[pCa + log (106 M)]/
, where erfc is the
complementary error function. For S. purpuratus, W = 0.23 ± 0.03 and 0.24 ± 0.06, and midpoint M = 18.3 ± 0.7 and 17.9 ± 1.6 µM (n = 111 and 68), respectively.
For L. pictus, W = 0.25 ± 0.03 and 0.25 ± 0.05, and
midpoint M = 45.9 ± 1.5 and 44.2 ± 3.2 µM (n = 77 and 26), respectively. For either species, the parameters of the fit for single and double challenge calcium
activation curves were not significantly different (P < 0.01). With no evidence for different calcium activation
curves arising from the sequence of calcium challenges,
the entire data sets for S. purpuratus and L. pictus were fit
using a log-normal cumulative distribution function with W = 0.23 ± 0.02 and 0.24 ± 0.02, and midpoint M = 18.2 ± 0.6 and 44.8 ± 1.2 µM, respectively. The shift in
calcium sensitivity between the two species, M, is significant (P < 0.05), while the width of the underlying distribution, W, is invariant. The absence of any difference between the calcium activation curves derived from single
and double challenges suggests that the exocytotic response was dependent only on the final calcium concentration, and not the sequence of concentration steps
used to reach the final concentration.
A log-normal probability density function was calculated from the log-normal cumulative distribution function (Fig. 7 B). The first derivative of the calcium activation curve can be viewed as the underlying probability
density function for fusion thresholds. A log-normal
representation was chosen because calcium thresholds are exclusively positive values. The calcium concentration required for the first fusion event can be estimated
from the probability density function for fusion thresholds. Multiplying the probability density function by
the total number of vesicles in a population approximates the frequency distribution of vesicle thresholds. An estimate of the calcium concentration required for
the first fusion event occurs at a threshold frequency of
one. For example, in a system of 20,000 vesicles, the
first vesicle is estimated to fuse when the concentration
of calcium exceeds ~1 µM in S. purpuratus and 7 µM in
L. pictus. This value is greater than the in vivo concentration of calcium in unfertilized eggs, regardless of
species. The distribution of vesicle thresholds offers a
rationale for explaining why vesicles fail to fuse in unfertilized eggs, where the calcium concentration is believed to be submicromolar (reviewed in Shen, 1995):
the lowest threshold for fusion is higher than the calcium concentration present.
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DISCUSSION |
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What are the limiting mechanism(s) that result in submaximal responses? We conclude that the calcium sensitivity of cortical degranulation is heterogeneous: vesicle exocytosis ceases at a certain calcium concentration because all the vesicles that can fuse at that concentration have fused. No evidence was found for calcium- dependent inactivation in cortical degranulation.
Submaximal Responses Are Not Due to Calcium-dependent Inactivation
Irreversible and reversible inactivation of the fusion
process was ruled out within our experimental times.
This result is different from findings in permeabilized
bovine adrenal medullary cells, where subsequent catecholamine release was obtained in a double challenge
protocol with the same calcium concentration in both
challenges (Baker and Knight, 1981; Knight and Baker, 1982
). While the calcium-dependent processes of chromaffin vesicle exocytosis may differ from those of cortical vesicle exocytosis, it is likely, based on their time
course for catecholamine release, that calcium was
withdrawn from, and then returned to, the permeabilized chromaffin cells before the stable, submaximal response had reached its plateau (e.g., Fig. 6 A, this work;
Fig. 12 A, Baker and Knight, 1981
). This plateau may
have been difficult to identify in the absence of a continuous record of secretion, the presence of an endogenous (nonstimulated) secretion, long equilibration times, and interconversion between vesicle compartments.
Heterogeneity in Triggered Exocytosis Is Due to Multiple Populations with Differing Thresholds
The failure to identify a single limiting process in the
decay of the instantaneous rate other than a decrease
in the number of vesicles in a selected population, the
size of which is set by the calcium concentration, is consistent with a system having the property of earlier heterogeneity in calcium thresholds. Alternatively, multiple limiting processes may act concurrently. Indeed, it
is possible to invoke schemes having complicated rate,
time, and concentration properties that can account
for the behaviors that are observed. However, the existence of multiple subpopulations of vesicles with differing calcium thresholds is the simplest explanation for
the behaviors observed in this system and represents our working hypothesis. That vesicles from the same
cell type respond to calcium differently supports the
hypothesis that vesicles that appear morphologically
homogeneous can have different calcium thresholds
(Ninomiya et al., 1997).
We have proposed that the number and distribution
of activated fusion complexes underlie the control of
the rate and extent of triggered exocytosis, and that
cortical vesicles have nine active fusion complexes, on
average, at high calcium concentrations (Vogel et al.,
1996). Since fusion of a single vesicle is an all-or-none event that can be caused by one activated fusion complex, the probability density function for calcium
thresholds can be regarded as the widest possible distribution of the lowest threshold values present on cortical vesicles. Since a vesicle may have multiple activated
fusion complexes, the lowest threshold group represents a subpopulation of the total number of activable fusion
complexes present in the system. The sampling of the
transition region of the calcium activity curve is not sufficient to distinguish between a continuous or discrete
probability density function for calcium thresholds.
However, there are at least five, experimentally defined, subpopulations with different calcium thresholds.
That cortical vesicles are heterogeneous in their response to calcium raises questions on the molecular origin of this property. Fusion may proceed through
chemically identical complexes whose calcium sensitivity is dependent, before the introduction of calcium, on the local environment. For example, after insertion
into various membranes and lipid preparations, the affinity of purified muscarinic acetylcholine receptors for
antagonists is modulated by the lipid environment
(Berstein et al., 1989). The degree of association between the vesicle and target membrane, local ionic conditions (McLaughlin and Whitaker, 1988
), and local
lipid composition (Vogel et al., 1993
; reviewed in Chernomordik et al., 1995
) may influence the fusion process and manifest as differing sensitivities to calcium. Alternatively, fusion may proceed through distinct complexes, each having different calcium sensitivities. The
heterogeneity in calcium sensitivity may arise from different proteins (e.g., a multigene family as in olfaction;
reviewed in Chess et al., 1992
), different protein isoforms (e.g., multiple synaptotagmins; reviewed in Littleton and Bellen, 1995
), or different posttranslational modifications such as phosphorylation of calcium binding sites.
Sharp Transitions Require the Action of Many Calcium Ions
Efforts have been made to estimate the number of calcium ions involved in the fusion process based on models that relate the calcium concentration and fusion response. A fundamental assumption in these analyses is
that fractional response is directly proportional to fractional calcium binding. The nonlinear relationship between calcium concentration and neurotransmitter release at the neuromuscular junction has been attributed to the cooperative action of four calcium ions in
the release process (Dodge and Rahamimoff, 1967). Dodge and Rahamimoff (1967)
recognized that their
data were compatible with either a stochastic (random)
model or with a stoichiometric reaction involving four
calcium ions and four independent binding sites (a single site binding curve raised to the fourth power). The
nonlinear relationship in the squid giant axon (Augustine and Charlton, 1986
) was described by either a
fourth order stoichiometric relationship or a Hill equation with cooperative interactions between four binding sites. Both Dodge and Rahamimoff (1967)
and Augustine and Charlton (1986)
relied on the linearity of
nth root double-reciprocal plots to conclude that power
functions of a single site binding curve described the
data. In these studies, the number of calcium ions is
represented by a parameter that describes the steepness of the transition from 0 to 100% activity. However,
we have now demonstrated that the response to calcium is consistent with multiple subpopulations with
differing thresholds. These subpopulations exhibit "receptor reserve" behavior (Vogel et al., 1996
). This implies that the underlying subpopulations, each with a
different threshold, must have even steeper individual transitions than the overall measured response because
the width of the measured response includes contributions from both the distribution of thresholds and the
intrinsic width of each subpopulation. For the first
time, we can identify multiple stable subpopulations whose existence requires that their individual transitions be steeper than the measured response. A steeper
individual transition is consistent with a fusion process
that requires the action of an even greater number of
calcium ions than the number suggested by homogeneous models. The calculated dependence on calcium
in other calcium-triggered exocytotic systems may be in
error if a distribution of thresholds (subpopulations)
exist in these systems. Four concurrent, calcium-dependent molecular events may represent a lower limit. The
involvement of many calcium ions may be a consequence of both protein and lipid binding processes. In
fact, six individual transitions, each requiring the interaction of 10 calcium ions, results in an overall calcium
activation curve that, when analyzed using homogeneous models, would suggest the interaction of three to
four calcium ions. The assumption that fractional response is directly proportional to fractional calcium
binding must be tested.
Although shifted, the invariance in the shape of the
calcium activation curves for S. purpuratus and L. pictus
implies that the cortical vesicle subpopulations in both
species respond to the same increment in calcium,
pCa. Similarities in the calcium activation curves for
secretion from endocrine, exocrine, neuronal, and
paracrine cells (Knight and Scrutton, 1986
) support
the hypothesis that subpopulations of exocytotic vesicles exist in every calcium-triggered exocytotic system
and that all subpopulations respond to approximately the same increment in calcium,
pCa. That equivalent
subpopulations of vesicles enter the fusion process for
comparable changes in calcium,
pCa, suggests that
the molecular machinery involved in the overall fusion
process performs the same work in overcoming a common fusion energy barrier,
Efusion, but that the initial and final energy levels differ between systems. These
energy differences may be reflected in the calcium-binding properties of the calcium sensor and/or fusogenic apparatus and the lipid organization of the membranes. The two species, S. purpuratus and L. pictus, are found in the same environment but undergo the cortical reaction during the winter and summer, respectively. Could the shift in the calcium activity curve
towards higher calcium concentrations for L. pictus
be a compensatory mechanism that prevents thermally driven fusion events, which may arise as a result of increased ambient temperature, from occurring?
In summary, we have determined that the calcium sensitivity of individual vesicles within a population of exocytotic vesicles is heterogeneous. The cessation of fusion in the continued presence of calcium was not due to calcium-dependent inactivation. The molecular origin of the observed distribution of thresholds remains to be answered. The dependence of the extent of exocytosis on calcium suggests that many calcium-dependent events are required for the fusion process. Thus, calcium activation curves may arise from both an underlying distribution of calcium thresholds and multiple calcium-dependent events.
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FOOTNOTES |
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Address correspondence to Paul S. Blank, LCMB/NICHD/NIH, Bldg. 10, Rm. 10D14, 10 Center Drive MSC 1855, Bethesda, MD 20892-1855. Fax: 301-594-0813; E-mail: psblank{at}helix.nih.gov
Original version received 12 January 1998 and accepted version received 15 September 1998.
Portions of this work have been previously published in abstract form (Kaplan, D., P.S. Blank, M.S. Cho, I. Steinberg, and J. Zimmerberg. 1994. Biophys. J. 66:284a. Blank, P.S., M.S. Cho, S.S. Vogel, D. Kaplan, D. Bhuva, A. Kang, J. Malley, and J. Zimmerberg. 1997. J. Gen. Physiol. 110:17a).We thank Itzhak Steinberg, who initially directed our attention to the importance of the double challenge protocol, and Peter Bungay and Jim Sullivan for help with the design and fabrication of the flow system.
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REFERENCES |
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