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Volume 17, Number 6,
Issue of March 15, 1997
pp. 1919-1927
Copyright ©1997 Society for Neuroscience
Depletion and Replenishment of Vesicle Pools at a Ribbon-Type
Synaptic Terminal
Henrique von Gersdorff and
Gary Matthews
Department of Neurobiology and Behavior, State University of New
York, Stony Brook, New York 11794-5230
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Synaptic depression was studied using capacitance measurements in
synaptic terminals of retinal bipolar neurons. Single 250 msec
depolarizations evoked saturating capacitance responses averaging ~150 fF, whereas trains of 250 msec depolarizations produced plateau capacitance increases of ~300 fF. Both types of stimuli were followed by pronounced synaptic depression, which recovered with a time constant
of ~8 sec after single pulses but required >20 sec for full recovery
after pulse trains. Inactivation of presynaptic calcium current could
not account for depression, which is attributed instead to depletion of
releasable and reserve vesicle pools that are recruited and replenished
at different rates. Recovery from depression was normal in the absence
of fast endocytosis, suggesting that replenishment was from a reserve
pool of preformed vesicles rather than from preferential recycling of
recently fused vesicles. Given the in vivo light
response of the class of bipolar neuron studied here, it is likely
that, under at least some illumination conditions, the cells produce a
fast and phasic bout of exocytosis rather than tonic release.
Key words:
retina;
bipolar cell;
calcium current;
synaptic terminal;
capacitance;
exocytosis;
endocytosis;
synaptic transmission;
synaptic
ribbon
INTRODUCTION
Repeated neuronal stimulation often leads to
synaptic depression or fatigue. Depression has been described in a wide
variety of synaptic preparations, including invertebrate and vertebrate neuromuscular junctions (Thies, 1965 ; Betz, 1970; Katz et al., 1993;
Atwood et al., 1994), the squid giant synapse (Charlton et al., 1982;
Swandulla et al., 1991), and Aplysia californica and
mammalian CNS synapses (Eliot et al., 1994; Borst et al., 1995; Thomson
and Deuchars, 1995; Debanne et al., 1996; Rosenmund and Stevens, 1996).
At crustacean neuromuscular junctions, for example, depression is
characteristic of phasic (fast twitch) synapses, whereas facilitation
typically is observed at tonic synapses (Katz et al., 1993; Atwood et
al., 1994). As with other forms of synaptic plasticity (Zucker, 1989),
either presynaptic or postsynaptic mechanisms potentially could be
responsible for synaptic depression. Here, we present an investigation
of synaptic depression and the recovery from depression by using
capacitance measurements (Neher and Marty, 1982; Gillis, 1995) in giant
synaptic terminals of type Mb1 bipolar neurons from goldfish retina
(Sherry and Yazulla, 1993). Capacitance measurements provide a direct view of presynaptic exocytosis and thus eliminate postsynaptic possibilities. The results suggest that synaptic depression in bipolar
cell terminals is caused by the depletion of vesicles in the readily
releasable pool and that inactivation of calcium current does not play
a role. Also, there is evidence for at least three vesicle populations,
distinguished by their readiness of access to the release process.
First, there is a rapid-release pool, possibly corresponding to the
vesicles tethered to synaptic ribbons (Witkovsky and Dowling, 1969),
which can be released completely in ~200 msec during strong
depolarization. Second, a reserve pool can replenish the depleted
rapid-release pool with a time constant of ~8 sec, but this pool may
contain only enough vesicles to reload the ribbons one time. Third, a
large reservoir of vesicles possibly the entire population within the
terminalis available to refill the reserve pool, but this requires
>20 sec for completion.
Teleost Mb1 bipolar cells respond to light flashes with large, rapid
depolarizations lasting ~200 msec (Saito et al., 1979). Natural
stimuli thus may deplete the readily releasable vesicle pool and lead
to complete depression of synaptic transmission. This may explain in
part why sustained depolarizations of bipolar cells cause only
transient excitatory postsynaptic responses in ON-OFF ganglion and
amacrine cells (Dacheux and Raviola, 1986; Mittman et al., 1990; Dixon
and Copenhagen, 1992). The pronounced depression reported here,
together with the high calcium threshold for exocytosis of Mb1 bipolar
neurons, suggests that these neurons do not release neurotransmitter
tonically (Atwood et al., 1994), in contrast to OFF-type bipolar cells
(Werblin and Dowling, 1969) and photoreceptors in darkness (Dowling and
Ripps, 1973; Rieke and Schwartz, 1996). Instead, this class of bipolar
cells likely responds to depolarization with a rapid and phasic release
of neurotransmitter, at least under illumination conditions that produce large depolarizations.
A brief account of some of these results has been published previously
(von Gersdorff and Matthews, 1995).
MATERIALS AND METHODS
Cell dissociation. The preparation of isolated
goldfish retinal bipolar cells was detailed previously by Heidelberger
and Matthews (1992). Bipolar cells were dissociated by mechanical trituration of pieces of isolated retina after enzymatic digestion with
hyaluronidase (1100 U/ml; Sigma, St. Louis, MO) and papain (30 u/ml;
Fluka, Neu-Ulm, Germany) at room temperature (20-26°C). Electrical
recordings were made from single synaptic terminals as well as from
intact bipolar cells (von Gersdorff and Matthews, 1994a). Mb1 bipolar
cell terminals (Sherry and Yazulla, 1993) were identified by their size
(8-12 µm in diameter) and bulbous morphology. An inverted microscope
(Zeiss IM, Oberkochen, Germany) was used for cell visualization and
fluorescence excitation of Fura-2. Calibration and calculation of
intracellular calcium from Fura-2 fluorescence were as described by
Heidelberger and Matthews (1992).
Electrophysiology. The extracellular recording solution
contained (in mM): NaCl 120, KCl 2.5, MgCl2
1.0, CaCl2 2.5, glucose 10, and HEPES 10, pH 7.4 with NaOH.
The standard patch-pipette solution used to isolate calcium currents
consisted of (in mM): Cs-gluconate 120, TEA-Cl 10, HEPES
10-35, EGTA-K4 or BAPTA-Cs4 0.5, ATP-Na2 2, MgCl2 2-3, GTP 0.5, and Fura-2
0.1-0.2, pH 7.2 with CsOH. Experiments also were done with 120 mM K-gluconate (n = 8) or Cs-glutamate
(n = 6), instead of Cs-gluconate, and identical
capacitance changes were obtained. The osmolarity of the pipette
solution varied from 260-290 mOsm. Pipettes were pulled from
thick-walled Pyrex glass, with an outer diameter of 1.2 mm and an inner
diameter of 0.6 mm. To reduce pipette capacitance and noise, we coated
pipettes by dipping them in low-melting-point dental wax, followed by
brief fire polishing. The open tip resistance was 7-10 M , and
access resistance was 12-25 M after whole-cell break-in. Seal
resistance was often >10 G, and only cells with a stable leak
current <40 pA usually were accepted. A slight positive pressure (3-5
mm Hg with our tubing) was applied sometimes before break-in to null
pipette internal capillary pressure. Records with leak currents of
5-20 pA often were obtained from bipolar cells under these conditions.
Terminals with stable leak currents from 80 to 100 pA had resting
[Ca2+]i  1 µM (with 0.5 mM EGTA or BAPTA and 0.1-0.2 Fura-2 in the patch pipette)
and capacitance responses that were step-like (e.g., Fig. 3).
Recordings were done at room temperature (20-26°C).
Fig. 3.
Repetitive responses occur in the absence of fast
endocytosis. Fast endocytosis was inhibited by elevation of
[Ca2+]i to 1 µM, as measured by
Fura-2 (0.2 mM). The arrows show timing of 1 sec depolarizations from  60 to 0 mV, which evoked repetitive capacitance jumps (A). The interval between
successive stimuli was sufficient to prevent the saturation of the
cumulative capacitance response observed with more rapid repetitive
stimulation (e.g., Fig. 6). This terminal had a stable inward leak
current of 80 pA at 60 mV, which generated the elevated resting
[Ca2+]i. Access conductance
(B) and membrane conductance did not change throughout
the recording. The standard pipette solution (see Materials and
Methods) contained 0.5 mM EGTA. Similar step-like responses also were observed in other terminals in which the leak current was
below 20 pA but in which [Ca2+]i was buffered
to an elevated level with exogenous Ca/Ca buffer mixtures (data not
shown).
[View Larger Version of this Image (18K GIF file)]
Voltage pulses applied through the EPC-7 (List-Medical, Darmstadt,
Germany) or Axopatch 200A (Axon Instruments, Foster City, CA)
patch-clamp amplifier were generated by an Atari Mega ST4 computer
running E7 Screen software (Heka, Germany) driving an ITC-16 interface
(Instrutech, Elmont, NY) or by an EPC-9 (List) patch-clamp amplifier
controlled by an Atari Mega STe computer. For capacitance measurements
with the EPC-7, the voltage pulse was passed first through a hardware
lock-in amplifier (MPI, Göttingen, Germany), in which an 800 Hz
(30 mV peak-to-peak) sinusoidal voltage was superimposed on the 60 mV
holding potential. Then the resulting sinusoidal currents were analyzed
at two orthogonal phases by the lock-in amplifier, which generated
signals proportional to the currents at the two phases. Together with
the DC membrane current, these signals were acquired by a second Atari
Mega ST4 computer and used to calculate membrane capacitance, access
conductance, and membrane conductance (Gillis, 1995). This arrangement
allowed a capacitance measurement every 0.2 sec, limited by the
software processing and data display times. In all cases analyzed,
activation of calcium current produced capacitance changes without
correlated changes in access resistance or membrane conductance.
Capacitance measurements during active conductance changes were
blanked, because these violate the passive three-element cell model
used to deduce capacitance changes (Gillis, 1995). The active currents,
including calcium current, were digitized separately at high temporal
resolution by the computer controlling the patch-clamp amplifier.
Capacitance also was measured with the EPC-9 (List) amplifier using its
automatic capacitance compensation feature, which had a maximum
temporal resolution of 0.34 sec. Both methods of monitoring capacitance gave equivalent results. Data analysis was performed with the software
REVIEW (Instrutech) and Xact (Ver. 3.0, Scilab, GmbH, Germany).
Rundown and endogenous calcium buffers. Multiple
depolarization-triggered capacitance responses typically could be
elicited from Mb1 terminals under whole-cell patch clamp, but
capacitance responses became smaller and eventually disappeared with
time (rundown or washout), although robust calcium current and large changes in [Ca2+]i were observed throughout
the recording. This phenomenon is also commonly observed in capacitance
measurements in chromaffin cells (Augustine and Neher, 1992; Burgoyne,
1995). The absence of capacitance response with continued large calcium
current demonstrates there was no detectable capacitance artifact
caused by gating charges (Horrigan and Bookman, 1994). The degree of
rundown was variable from terminal to terminal, with some displaying
responses for up to 20 min. Similar rundown of glutamate secretion was
observed by Tachibana and Okada (1991) in goldfish Mb1 bipolar
terminals.
We used 0.5 mM calcium chelator (EGTA or BAPTA) in our
standard pipette solution (see above). To determine whether dialysis of
terminals with this level of buffer affected capacitance responses, we
measured the initial capacitance responses of terminals to a
depolarizing pulse (250 msec from 60 to 0 mV) elicited 3-20 sec
after break-in, with pipettes containing 0.5 mM BAPTA and 0.1 mM Fura-2. Within this time window, the average
increase in capacitance was 156 ± 28 fF (mean ± SEM,
n = 10), and the recovery of capacitance back to
initial baseline (endocytosis) was exponential with an average time
constant  = 1.1 sec. For comparison, responses were elicited 60 sec
or more after break-in, when the terminal was fully dialyzed by the
pipette solution, as judged by the plateauing of Fura-2 fluorescence
( = 15-40 sec; data not shown). These later responses had an
average amplitude of 146 ± 34 fF and a slightly slower
endocytosis time constant = 1.5 sec. Assuming that Fura-2 and BAPTA
enter the terminal at approximately the same rate after break-in, the
similarity in early and late responses suggests that 0.5 mM
BAPTA does not significantly alter capacitance responses elicited by
250 msec pulses or that the loss of endogenous mobile calcium buffers
is approximately balanced by the addition of BAPTA.
RESULTS
Saturation of capacitance responses with increasing
calcium current
Previous work in giant synaptic terminals of goldfish retinal
bipolar neurons demonstrated that capacitance responses evoked by
depolarizing pulses saturate at a plateau of ~150 fF for pulse durations exceeding ~200 msec (von Gersdorff and Matthews, 1994a). Figure 1 shows that a similar saturation of the
capacitance response is also apparent when the pulse duration is fixed
at 250 msec, the pulse voltage is varied, and the size of the
capacitance response is plotted against the amplitude of the observed
calcium current. For currents greater than ~150 pA, the capacitance
response reached a maximum size, which again averaged ~150 fF. The
observed amplitude of the capacitance response for large currents was
similar when either a fast calcium buffer (0.5 mM BAPTA;
filled circles in Fig. 1) or a slow calcium buffer (0.5 mM EGTA; open circles in Fig. 1) was included in
the patch-pipette solution. This saturation of the capacitance response
at larger currents is further indication that a limited pool of
vesicles is available for rapid release in bipolar cell synaptic
terminals. Once calcium influx is sufficient to exhaust this pool,
additional calcium influx will not lead to a further increase in the
capacitance response. Similar saturation of capacitance responses also
is seen in experiments using photorelease of caged calcium
(Heidelberger et al., 1994), in which calcium remains elevated for
several seconds after a flash, but the increase in capacitance reaches
its asymptotic value within a few milliseconds or less.
Fig. 1.
Dependence of capacitance response on size of
calcium current. The average capacitance jump is plotted versus calcium
current amplitude. Pulses were 250 msec depolarizations from the
holding potential of 60 to 20, 10, or 0 mV. Each data
point is the average of 4-11 responses, and the
vertical lines show ± 1 SEM. Across-cell averages
at each current range were obtained by binning in 50 pA increments of
observed calcium current. The position of each data
point along the abscissa shows the average
current within each bin. The standard pipette solution (see Materials and Methods) was used, with either 0.5 mM BAPTA
(filled circles) or 0.5 mM EGTA
(open circles). Results are shown from 13 cells for EGTA
and 29 cells for BAPTA.
[View Larger Version of this Image (18K GIF file)]
Recovery after depletion
The rapidly releasable pool observed in capacitance experiments
corresponds to ~6000 synaptic vesicles, which matches closely the
estimated population of vesicles tethered to synaptic ribbons in the
bipolar cell terminal (von Gersdorff et al., 1996). We will assume
here, then, that the saturating response illustrated in Figure 1
reflects the depletion of vesicles on the ribbons. Therefore, we next
asked how long it takes to repopulate the ribbon after it is denuded by
a saturating stimulus. To answer this, a 250 msec depolarization was
given to empty the readily releasable pool, and refilling of the pool
was examined with a second depolarizing stimulus given a variable time
later. Figure 2 summarizes the results. When the second
stimulus followed the first by a few seconds (Fig.
2A), the second capacitance response was smaller than
the first. When the interval between stimuli was greater, however, the
second response was comparable in size to the first (Fig.
2B). Figure 2C shows results from a number
of such experiments. The time course of recovery was approximately
exponential, with a time constant of 8 sec. Figure 2D
demonstrates that the calcium current elicited by the second pulse was
unchanged for all but the shortest interpulse intervals, where a small
amount of calcium-dependent inactivation (von Gersdorff and Matthews,
1996) was observed. Even at these short intervals, however, the calcium
current during the second depolarization was still of sufficient
amplitude to elicit a maximal capacitance response (Fig. 1). Together
with the lack of correspondence between the time course of recovery of
the calcium current and the time course of recovery of the capacitance
response, this demonstrates that the depression of the capacitance
response after a saturating stimulus cannot be attributed to
inactivation of presynaptic calcium current.
Fig. 2.
Paired-pulse depression and recovery.
A, Two capacitance responses were elicited ~4 sec
apart. The arrows show the timing of 250 msec pulses
from 60 to 0 mV. The indicated time is relative to break-in.
B, Two capacitance responses were elicited ~46 sec apart. The arrows indicate timing of 250 msec pulses
from 60 to 0 mV. C, Summary of experiments like those
in A and B. So that results can be
compared across cells, the second capacitance response is expressed as
a percentage of the first jump. The interval between pulses is shown on
the abscissa. The solid line is the
best-fit single exponential, which has a time constant = 8 sec
(correlation coefficient = 0.95). Each data point
represents the result from a single terminal, and there is one point
per terminal. The exception is the point at 0.75 sec, which represents
the average of 27 terminals. D, The same experiments as
in C, showing the corresponding calcium current
amplitudes. The pipette solution contained either 0.5 mM
BAPTA or 0.5 mM EGTA. Not all corresponding calcium
currents are shown, because some terminals were recorded with
K-gluconate in the patch pipette (see Materials and Methods).
[View Larger Version of this Image (18K GIF file)]
Under normal conditions, the capacitance rapidly returns to
baseline (fast endocytosis; time constant = 1-2 sec) after a bout
of depolarization-triggered exocytosis (e.g., Fig.
2A,B). However, fast endocytosis was not required for
recovery of the capacitance response after depletion. To dissociate
endocytosis from exocytosis, we exploited the fact that fast
endocytosis in bipolar cell terminals is inhibited by elevated
intracellular calcium at concentrations that do not themselves evoke
capacitance increases or exocytosis (von Gersdorff and Matthews,
1994b). Inhibition of fast endocytosis by high internal calcium also
has been reported recently in rat pituitary nerve terminals (Hsu and
Jackson, 1996). This allows experiments like that shown in Figure
3, in which endocytosis is inhibited by elevated
[Ca2+]i, but depolarization-evoked exocytosis
is normal. In Figure 3, three successive normal amplitude capacitance
jumps were evoked by depolarizing pulsesproducing an overall
capacitance increase of 450 fFalthough fast endocytosis was absent.
So, the exocytotic response recovered fully during the interval between
pulses despite the inhibition of fast endocytosis. Fast endocytosis in
bipolar cell terminals also can be blocked by slight pressure-induced swelling without altering basal [Ca2+]i (R. Heidelberger and G. Matthews, unpublished data). With this method of
inhibiting endocytosis, step-like capacitance responses of normal
amplitude also were observed with successive depolarizations (data not
shown). Thus, the recovery of capacitance responses to normal size
after depletion taps a reserve pool of preformed vesicles within the
terminal without requiring fast retrieval of recently added membrane.
This reserve pool presumably represents all or part of the several
hundred thousand vesicles observed in electron microscopy of the giant
bipolar cell terminals (von Gersdorff et al., 1996).
Long-duration depolarization elicits larger
capacitance responses
If the recovery process shown in Figure 2 operates during
depolarization as well as in the interval between two brief
depolarizations, then it would be expected that long depolarizations
should elicit larger capacitance jumps than brief depolarizations. To
examine this, we compared capacitance responses evoked by 250 msec, 1 sec, and 2 sec depolarizing pulses. Figure 4 shows
example responses and a summary of the results. The average capacitance
jumps were not significantly different for 250 msec and 1 sec pulses,
although the total Ca2+ influx into the terminal was more
than three times larger for the 1 sec pulses. This extends our earlier
observation that pulses from 250-450 msec in duration all elicit the
same size of capacitance response (von Gersdorff and Matthews, 1994a).
However, capacitance jumps for 2 sec pulses were larger than for the
briefer pulses (Fig. 4B,C), suggesting that 2 sec
stimuli provide sufficient time for partial refilling of the ribbons
during the depolarization. Pulses longer than 2 sec were not examined
because of pronounced calcium-dependent inactivation of calcium current
during pulses of such long duration (von Gersdorff and Matthews, 1996).
For an exponential recovery process with a time constant of 8 sec (Fig.
2), the capacitance response for a 2 sec pulse would be expected to be
~20% larger than for a 250 msec pulse. The observed increase with 2 sec stimuli (Fig. 4) was greater than this, suggesting that recovery
may be speeded during depolarization. A similar observation in
chromaffin cells has been taken as evidence that recovery of granule
pools from depletion is calcium-dependent (von Rüden and Neher,
1993), but we have not pursued this possibility further in bipolar cell
terminals.
Fig. 4.
Long-duration depolarization produces a larger
capacitance response. A, Two responses from the same
terminal are superimposed. Both responses were elicited at the
arrow by depolarizations from a holding potential of
60 to 0 mV. The first lasted 250 msec (open circles)
and the second, given 24 sec afterward, lasted 1 sec (closed
circles). B, Two responses from another terminal again are superimposed. Both responses were elicited at the
arrow by depolarizations from a holding potential of
60 to 0 mV. The first lasted 250 msec (open circles)
and the second, given 179 sec afterward, lasted 2 sec (closed
circles). C, The average capacitance jump is
plotted as a function of pulse duration for pulses lasting 250 msec
(n = 10), 1 sec (n = 10), or 2 sec (n = 5).
[View Larger Version of this Image (20K GIF file)]
Depression after weaker stimuli
The results so far suggest that neurotransmitter release evoked by
strong depolarization is highly transient in bipolar neurons of the
type used in our capacitance experiments. The degree of synaptic
depression might be different with weaker depolarizing pulses, however.
To examine this, we measured the amount of depression produced by 250 msec depolarizing pulses of different amplitudes, as summarized in
Figure 5. A pair of pulses was presented with an
interpulse interval of 1 sec. Figure 5A shows that, with
depolarization to 10 mV, the results were comparable to those
described above for pulses to 0 mV (e.g., Fig. 2): the first pulse
evoked a large capacitance response, but the response to the second
pulse was strongly depressed (17% of the first response, on average).
The average calcium current was slightly smaller for the second pulse (Fig. 5B), but both currents were within the range expected
to produce saturating capacitance responses, if given in isolation (see
Fig. 1). Therefore, inactivation of calcium current, again, cannot
account for the depression.
Fig. 5.
Paired-pulse depression at different pulse
voltages. A, Capacitance responses for first
(gray bars) and second pulses (white bars) of a pair with an interpulse interval of 1 sec. Pulses
were 250 msec depolarizations from 60 mV to 10 mV
(n = 10), 20 mV (n = 11), or
30 mV (n = 5). Error bars indicate ± 1 SEM.
Percentage numbers indicate the second response
expressed as a percentage of the first. B, Calcium
currents for first and second pulses for same set of responses as
A. The pipette solution contained 0.5 mM
BAPTA.
[View Larger Version of this Image (41K GIF file)]
With depolarization to 20 mV, the capacitance response to the first
pulse was smaller than that for depolarization to 10 mV, and there
was less depression (second response 41% of first; Fig.
5A). Decreasing the amplitude of depolarization to 30 mV further reduced the capacitance response to the first pulse and eliminated depression (second response 136% of first; Fig.
5A). For both of these voltages, the calcium current was not
significantly different for the first and second pulses (Fig.
5B). Thus, if depletion of the releasable pool by the first
pulse of a pair is reduced by changing the pulse voltage, the amount of
depression observed with the second pulse also is reduced. This is
consistent with the idea that paired-pulse depression reflects
depletion of a releasable pool of vesicles.
Another way of reducing the amount of release per pulse is the
inclusion of exogenous calcium buffer in the patch-pipette solution
(von Gersdorff and Matthews, 1994a). When synaptic terminals were
dialyzed with pipette solutions containing either 5 or 10 mM calcium buffer (EGTA or BAPTA), most terminals failed to
show a detectable capacitance response after a 250 msec depolarization to 10 mV. In a subset of terminals, however, detectable capacitance responses were observed to single pulses, and we examined paired-pulse depression in this subgroup. In those terminals that did show responses, the average amplitude of the capacitance jump to the first
pulse was reduced substantially (33 ± 2 fF; mean ± SEM, n = 14), although the calcium current was normal
(212 ± 17 pA). The capacitance response to a second 250 msec
depolarization to 10 mV, given 1 sec after the first, was
significantly larger than the first response in these cells
(55 ± 10 fF; mean ± SEM, n = 14; calcium
current = 197 ± 17 pA). Thus, rather than paired-pulse depression, paired-pulse facilitation was observed in the presence of
exogenous calcium buffer (Borst et al., 1995; Tank et al., 1995; Atluri
and Regehr, 1996). Taken together with the results with weaker
depolarization (30 mV; Fig. 5A), this suggests that the
amount of initial exocytosis is a determinant of whether paired-pulse depression or facilitation is observed, as reported for hippocampal synapses by Debanne et al. (1996).
Capacitance response to a train of pulses
Retinal bipolar neurons commonly are thought to signal
sustained changes in illumination lasting for many seconds or minutes. As a measure of sustained synaptic release, we also studied cumulative capacitance responses to trains of stimuli, consisting of single 250 msec depolarizing pulses repeated at a frequency of 1 Hz. Figure
6A shows the average cumulative
capacitance increase during pulse trains, relative to the baseline
capacitance before the onset of the train. With depolarizations to 10
mV in the presence of 0.5 mM BAPTA (Fig.
6A, filled circles), capacitance initially jumped by ~150 fF and then increased more slowly for the next few
pulses before reaching a plateau value of ~300 fF. Further pulsing
failed to increase the capacitance beyond this plateau. The pronounced
depression or saturation in capacitance increases was, however,
accompanied by progressive inactivation of the calcium current elicited
by the pulses (Fig. 6B, filled circles). This is also
apparent when the capacitance increase is plotted as a function of the
calcium current, as shown by the filled circles in Figure
6C. Thus, it is unclear whether the plateau under these stimulus conditions represents depletion of a reserve pool of vesicles
or reduction of calcium influx, a question we will address next.
Fig. 6.
Cumulative capacitance changes elicited by
trains of depolarizing pulses. A, The average cumulative
capacitance change elicited by trains of depolarizing pulses was
measured relative to the resting membrane capacitance before the onset
of the pulse train. The trains consisted of 250 msec pulses from 60
to 10 mV (0.5 mM BAPTA, filled circles,
n = 10; 5.0 mM BAPTA, filled
triangles, n = 22) or 30 mV (open
circles, n = 5), delivered at 1 Hz. The patch pipette contained either 0.5 or 5.0 mM BAPTA, as
indicated in the inset. No significant endocytosis was
detected between pulses because of the elevated
[Ca2+]i (data not shown) [von Gersdorff and
Matthews (1994b), their Fig. 4a]. B, Calcium currents
from the same set of experiments as in A. Pronounced
calcium-dependent inactivation of calcium current is evident for the
10 mV pulse series with 0.5 BAPTA (filled
circles). Less inactivation is observed with 5.0 mM
BAPTA (filled triangles) and with the 30 mV
pulses (open circles). The standard pipette solution
(see Materials and Methods) was used with the indicated amounts of
BAPTA. C, The data from B and C are replotted, showing the capacitance increase as a
function of calcium current during the pulse train.
[View Larger Version of this Image (26K GIF file)]
When a train of 30 mV pulses was presented, the capacitance rose
approximately linearly, without the large initial jump seen with
stronger depolarizations. A plateau of elevated capacitance again was
reached with continued pulsing (Fig. 6A, open
circles). Because the calcium current was much smaller with
depolarization to 30 mV (Fig. 6B, open circles),
there was less inactivation of the current during the train of pulses.
This can be seen in Figure 6C (open circles) by
the steepness of the relation between calcium current and cumulative
capacitance increase. Also, the calcium current with the 30 mV pulses
was similar to the asymptotic current reached during inactivation with
10 mV pulses (compare filled and open circles
in Fig. 6B,C). Thus, a level of current that was
sufficient to support progressive capacitance increase during the early
part of the 30 mV pulse train was not able to produce continued
capacitance increase during the later part of the 10 mV pulse train.
This suggests that the plateau of capacitance with 10 mV pulses is
not attributable to the observed inactivation of the calcium
current.
We also examined responses to repetitive stimulation when the amount of
release per pulse was reduced by adding calcium buffer rather than by
reducing the depolarization. With 5.0 mM BAPTA in the patch
pipette, capacitance in response to trains of 10 mV pulses showed an
initial facilitation, followed by a steady increase up to a plateau
level (Fig. 6A, filled triangles). Inactivation of
calcium current was reduced by the buffer (Fig. 6B,C;
also see von Gersdorff and Matthews, 1996). When the concentration of
calcium buffer in the patch pipette (either BAPTA or EGTA) was
increased to 10 mM, a single 250 msec pulse to 10 mV
produced a detectable capacitance increase in only 9 of 30 trials (for cells with calcium current >100 pA), and so the average single-pulse capacitance response was not significantly different from zero (counting undetectable responses as zero amplitude responses in calculating the average). However, with repetitive pulses given once
per second, the cumulative capacitance changed by 175 ± 23 fF
(mean ± SEM, n = 7) after five pulses for 10 mM EGTA, but only by 55 ± 21 fF (n = 8) for 10 mM BAPTA. Thus, for pulse trains, EGTA was less
effective than BAPTA in preventing capacitance changes, as reported
previously (von Gersdorff and Matthews, 1994a). The reason for this
difference between BAPTA and EGTA in responses to pulse trains given at
1 Hz is uncertain. We speculate, however, that BAPTA may be more
effective than EGTA at avoiding calcium "spillover" (Roberts, 1994;
Tucker and Fettiplace, 1995; Cooper et al., 1996) between neighboring
active zones (i.e., ribbons). By contrast, in the squid giant synapse,
concentrations of up to 80 mM EGTA do not affect release
(Adler et al., 1991).
In all pulse and buffer conditions shown in Figure 6, the cumulative
capacitance increase produced by pulse trains had a similar plateau
amplitude of ~300 fF. A simple interpretation is that the plateau
represents depletion of a vesicle pool, in this case representing the
vesicles available to replenish the readily releasable pool. Assuming
the capacitance of a single vesicle is 26.4 aF (von Gersdorff et al.,
1996), a cumulative increase in capacitance of ~300 fF corresponds to
the fusion of at least 12,000 vesicles with the plasma membrane. This
is approximately twice the estimated number of vesicles on all the
synaptic ribbons in a giant bipolar cell terminal (von Gersdorff et
al., 1996). Thus, during repeated stimulation, it seems that synaptic
ribbons are reloaded only once before exocytosis ceases. Perhaps a
reserve pool of vesicles near the ribbon accounts for the rapid
refilling of empty ribbons (see Fig. 2C), and depletion of
this reserve pool accounts for failure of continued refilling during
repeated stimulation.
Recovery of capacitance responses after prolonged stimulation
We next asked how long after a train of pulses it takes for the
capacitance response to return to normal amplitude. By comparing this
recovery of the capacitance response with the recovery rate from
calcium current inactivation, we can further test if inactivation can
account for the apparent plateau of capacitance seen during pulse
trains. Figure 7A shows that after trains of
pulses a longer time for the recovery of responses was necessary than
for paired-pulse depression. For example, when a test pulse was given
~20 sec after termination of the pulse train, the response was still
depressed (left gray bar, Fig. 7A; average
recovery time 21 sec). By contrast, with paired-pulse depression 20 sec
was sufficient for complete recovery (white bar, Fig.
7A; also see Fig. 2C). The calcium current elicited by the test pulse is shown in Figure 7B, relative
to the control calcium current evoked by the first pulse of the pulse train. Calcium current recovered fully to its original amplitude after
~20 sec, which suggests that inactivation of the current is not
responsible for depression. When the recovery interval was between 50 and 100 sec (Fig. 7A, middle gray bar; average recovery time
79 sec), the test response was, on average, somewhat depressed as
compared with the initial response, although the difference was not
statistically significant. With still longer recovery time (average
recovery time 155 sec), the test response was slightly larger than
normal (again, not statistically significant). If saturation of
capacitance during pulse trains reflects depletion of a reserve pool,
then the slowing of the recovery time after trains suggests that
replenishment of the reserve pool requires longer time than
replenishment of the readily releasable pool (see Fig. 2).
Fig. 7.
Recovery of capacitance responses after prolonged
stimulation. A, The capacitance jump to a 250 msec pulse
from 60 to 10 mV was measured at various intervals after a train of
pulses like those shown in Figure 6A. The size of
this jump is plotted as a percentage of the first jump in the pulse
train. Recovery interval refers to the time between the
termination of the pulse train and the delivery of the 250 msec test
pulse. The capacitance recovered to only ~60% of the control level
for pulses elicited ~20 sec after the pulse train
(n = 4). For comparison, the white
bar shows the amount of recovery observed at the same time
interval with paired pulse depression (n = 12; Fig.
2C). Percentage of recovery of the capacitance jump also
is shown for intervals in the range from 50 to 100 sec and from 100 to
200 sec. B, Recovery of calcium currents for the same
set of experiments as A. Current elicited by the test
pulse is expressed as a percentage of the first calcium current in the
pulse train.
[View Larger Version of this Image (37K GIF file)]
DISCUSSION
Depletion and refilling of vesicle pools
In bipolar cell synaptic terminals, capacitance responses
evoked by strong depolarization saturate for pulse durations from 250 msec to 1 sec. Saturation of postsynaptic responses with increasing presynaptic pulse duration also occurs in Aplysia synapses
(Shapiro et al., 1980), the squid giant synapse (Llinás et al.,
1981), and amacrine cell synapses (Gleason et al., 1994). Pronounced synaptic depression was observed after a saturating capacitance response. In paired-pulse experiments, recovery from depression followed an exponential time course, with a time constant of 8 sec.
Experiments on other presynaptic terminals (Betz, 1970; Swandulla et
al., 1991; Katz et al., 1993) have yielded time constants of 5-8 sec
for recovery from depression. Thus, both conventional and ribbon-type
synapses have similar recovery rates. By contrast, adrenal chromaffin
cells take ~1-3 min to recover fully from depleting stimuli (von
Rüden and Neher, 1993; Burgoyne, 1995; Seward and Nowycky, 1996),
provided Mg-ATP is available (Parsons et al., 1995). Inactivation of
presynaptic calcium current was not involved in depression in bipolar
cell terminals, suggesting that the reduction in response size was
attributable to depletion of a readily releasable pool of synaptic
vesicles. At the squid giant synapse, calcium currents are constant
during depression, also leading to the hypothesis that vesicle pools
become depleted (Charlton et al., 1982). Thus, calcium current
inactivation may function as a safety mechanism to protect terminals
from calcium overload when synaptic vesicles are no longer available
for release.
The size of the saturating capacitance response corresponds well with
the estimated number of vesicles tethered to synaptic ribbons in the
bipolar cell terminal (von Gersdorff et al., 1996). We assume,
therefore, that depression results from depletion of the vesicles
tethered to the ribbons. In fish electroreceptors, which also have
ribbon-type synapses, depression of postsynaptic responses is, indeed,
associated with depletion of vesicles from the ribbons (Fields and
Ellisman, 1985). If this is also true for bipolar cell ribbons, then
the time course of recovery from depression represents the rate of
repopulation of denuded ribbons by synaptic vesicles. Fast endocytosis
was not required for recovery from depression, and so the replenishment
of the release-ready pool occurs from cytoplasmic reserve vesicles.
Conventional active zones also have a reserve pool of synaptic vesicles
that can be depleted after prolonged stimulation (Heuser and Reese,
1981; Pieribone et al., 1995).
During a train of repetitive depolarizing pulses, capacitance rose to
an elevated plateau beyond which there was no further increase with
continued pulsing. This plateau capacitance increase (~300 fF) was
similar in size to the capacitance increase evoked by dialysis with
[Ca2+]i buffered at 50-60 µM
(also ~300 fF; von Gersdorff and Matthews, 1994a). One interpretation
of the saturation of capacitance during repetitive stimulation is that
a reserve pool of vesicles reloads ribbons quickly (8 sec time
constant), but this reserve pool has limited capacity and can be
depleted itself. From the amount of added capacitance during pulse
trains, the reserve pool is estimated at 6000 vesicles, which is
sufficient to reload the ribbons one time. This ready-reserve pool is
much smaller than the reservoir of several hundred thousand vesicles in
the giant terminal as a whole (von Gersdorff et al., 1996), and so it
represents a small subgroup of the entire population of preformed
vesicles. Repetitive depolarizations also have been shown to deplete
distinct vesicle pools in chromaffin cells (Heinemann et al., 1993;
Horrigan and Bookman, 1994). The phasic ribbon-type synapse of lobster
neuromuscular junction also displays pronounced depression (Katz et
al., 1993). We emphasize, however, that there are other possible
mechanisms for saturation of the capacitance response during pulse
trains, such as accumulation or depletion of intracellular factors that affect release and adaptation of the calcium sensor for exocytosis (Hsu
et al., 1996).
If we assume that the plateau of capacitance during pulse trains
represents depletion of reserve vesicles, then replenishment of this
reserve pool from other vesicle reservoirs must be slower than the
reloading rate of the ribbons. Otherwise, the capacitance would not
saturate and instead would continue to increase during a train of
stimuli. Slower replenishment was, in fact, observed: recovery of a
normal capacitance response required >20 sec after pulse trains but
was complete within 20 sec after single pulses. Different rates of
recovery also have been reported in experiments using FM1-43
fluorescence to monitor vesicle dynamics in single hippocampal boutons
(Ryan et al., 1996). For example, Stevens and Tsujimoto (1995) and
Rosenmund and Stevens (1996) report a recovery time of 8-10 sec for
brief stimuli (~20 vesicles released), whereas Liu and Tsien (1995)
find that recovery requires 40 sec after more prolonged stimulation
(~90 vesicles released). If the hippocampal synapses behave similarly
to the bipolar cell terminals, then the different stimulation protocols
may explain this difference in recovery rates.
Calcium buffers, depression, and facilitation
Depression was observed whenever the initial depolarization evoked
a large capacitance response. If the initial response was made smaller,
either by reducing the depolarization or by adding exogenous calcium
buffer, depression was attenuated or eliminated, and facilitation was
observed (Fig. 6). The possibility thus emerges that differences in
levels of endogenous calcium-binding proteins might underlie
differences in paired-pulse facilitation and depression among different
synaptic terminals or during development (Bolshakov and Siegelbaum,
1995). For example, trains of impulses produce either facilitation or
depression at different Ia afferent boutons onto single spinal motor
neurons (Collins et al., 1984). At crustacean neuromuscular junctions
(Katz et al., 1993; Atwood et al., 1994) similar variation has been
attributed to presynaptic mechanisms. Although the calcium-buffering
capacity of the terminals is unknown in these instances,
calcium-binding proteins are expressed differentially within
subpopulations of neurons in various brain regions and during
development (Baimbridge et al., 1992). We speculate, then, that
synaptic terminals with a large buffering capacity would be more likely
to show facilitation, whereas those with a low buffering capacity would
more likely undergo depression.
Phasic synaptic transmission at Mb1 bipolar cell terminals
From capacitance measurements we infer that the synaptic
terminals of type Mb1 bipolar cells release transmitter transiently. Other observations also support the idea that transmitter release is
transient in this class of bipolar neuron. Tachibana and Okada (1991),
have measured "postsynaptic" currents evoked in cultured horizontal
cells closely opposed to patch-clamped goldfish Mb1 bipolar cell
terminals. During a 2 sec activation of presynaptic calcium current in
the bipolar neuron [Tachibana and Okada (1991), their Fig. 7], the
postsynaptic current declined substantially, with a time course not
correlated with inactivation of the bipolar cell calcium current.
Because the glutamate-activated current of the horizontal cells is
sustained during prolonged glutamate application (Tachibana and Okada,
1991), the decline of the postsynaptic response likely represents
depletion of a readily releasable pool of vesicles. Simultaneous
intracellular recordings from synaptically connected amacrine and
ON-type bipolar cells in carp retina (Kujiraoka et al., 1988) also show
that the postsynaptic response of amacrine cells is transient during
sustained injection of depolarizing current into the presynaptic
bipolar neuron, suggesting that neurotransmitter is released only
transiently by bipolar cells. In the intact retina, additional
mechanisms such as feedback inhibition from amacrine cells onto bipolar
cell terminals also likely contribute to shaping transient responses in
ganglion cells (Massey and Maguire, 1995), particularly at high light
levels. It recently has been suggested on the basis of FM1-43 labeling
that ON-type bipolar cells release transmitter continuously (Lagnado et
al., 1996), but it is unclear that the membrane turnover revealed in
those experiments is related to neurotransmitter release, especially
given the physiological evidence for transient release discussed
above.
Intracellular recordings in intact retina show that light
responses of Mb1 bipolar neurons are similar to the depolarizing pulses
used here to evoke saturating capacitance responses. A light flash
elicits a large, rapid depolarization with amplitudes ranging from 22 to 32 mV positive to the 40 mV resting potential [Saito et al.
(1979), their Fig. 3]. This spike-like depolarization repolarizes
within ~200 msec to a less depolarized plateau, the duration of which
depends on illumination intensity. The initial spike is comparable to
the depolarizations used in our capacitance measurements. Physiological
stimuli thus may produce a fast burst of exocytosis in bipolar cell
terminals sufficient to fully deplete the readily releasable vesicle
pool. This would convert sustained responses in photoreceptors into
transient responses in ganglion cells. However, under illumination
conditions that produce smaller, more sustained depolarization,
capacitance measurements indicate that Mb1 bipolar neurons can sustain
release for longer periods (see Fig. 6). Strong stimulation thus favors
phasic release, whereas weaker stimulation favors more tonic
release.
We suggest that Mb1 bipolar neurons, with their high
[Ca2+]i threshold for secretion (Heidelberger
et al., 1994; von Gersdorff and Matthews, 1994a), operate like phasic
spiking neurons, which typically have large initial synaptic responses
that undergo depression after stimulation with trains of action
potentials. By contrast, photoreceptors, with their low
[Ca2+]i threshold for secretion (Rieke and
Schwartz, 1996) and possibly OFF-type bipolar neurons, are thought to
operate in a tonic manner, continuously releasing neurotransmitter in
the dark. Certain classes of ON-type bipolar neurons with small,
varicose synaptic terminals (Saito and Kujiraoka, 1982) also may be
tonic secretors, given their graded responses to light. Morphologically
distinct classes of bipolar neurons (Euler et al., 1996) thus may
channel tonic and phasic information separately to ganglion cells.
FOOTNOTES
Received Oct. 28, 1996; revised Dec. 23, 1996; accepted Dec. 24, 1996.
This work was supported by National Institutes of Health Grant EY03821,
National Research Service Award Fellowship EY06506, and the Alexander
von Humboldt Foundation. We thank J. G. G. Borst, A. Marty, R. Miles,
and E. Neher for helpful comments.
Correspondence should be addressed to Dr. Gary G. Matthews, Department
of Neurobiology and Behavior, State University of New York, Stony
Brook, NY 11794-5230.
Dr. von Gersdorff's present address: Abteilung Membranbiophysik, Max
Planck Institut für biophysikalische Chemie, Am Faßberg, 37077 Göttingen, Germany.
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