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The Journal of Neuroscience, September 1, 2001, 21(17):6467-6474
ATP Is Required at an Early Step in Compensatory Endocytosis in
Synaptic Terminals
Ruth
Heidelberger
Department of Neurobiology and Anatomy, W. M. Keck Center for
the Neurobiology of Learning and Memory, University of Texas Houston
Health Science Center, Houston, Texas 77030
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ABSTRACT |
Whole-terminal capacitance measurements were used to examine
membrane retrieval that follows Ca2+-triggered
exocytosis in single synaptic terminals. Exocytosis was followed by
endocytosis only when the internal solution contained a hydrolyzable
analog of ATP. ATP- -S, a poorly hydrolyzable ATP analog, did not
support endocytosis but instead produced a rapid and profound
inhibition of membrane retrieval. Under similar conditions, the GTP
analogs GTP--S and GDP- -S failed to block endocytosis, suggesting
that ATP is the preferred substrate. Furthermore, the requirement for
ATP was independent of the role of ATP in regulating intraterminal
Ca2+, and the role of Ca2+ in
endocytosis was different from that of ATP. The results suggest a
direct, acute requirement for ATP hydrolysis in compensatory fast
endocytosis in synaptic terminals. Given that the capacitance technique
detects changes in membrane surface area, ATP must be required for the
membrane fission step or at a step that is a prerequisite for membrane fission.
Key words:
endocytosis; synaptic vesicle; ATP; synapse; bipolar
cell; retina; calcium
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INTRODUCTION |
Three distinct patterns of
endocytosis have been identified in secretory cells when capacitance
measurements are used to monitor membrane retrieval. The first of
these, "compensatory endocytosis," is observed immediately after
Ca2+-dependent exocytosis and serves to
restore the membrane capacitance precisely back to baseline.
Compensatory endocytosis typically has a time constant of a few
seconds, although after strong stimuli or elevations in basal
Ca2+, the recovery time can be quite
prolonged (von Gersdorff and Matthews, 1994a ,b). This form of
endocytosis has been reported in both synaptic terminals (von Gersdorff
and Matthews, 1994a,b) and neuroendocrine cells (Smith and Neher, 1997;
Engisch and Nowycky, 1998). In neuroendocrine cells and neuronal
somata, but not synaptic terminals,
Ca2+-triggered endocytosis may also lead
to a large undershoot of the baseline capacitance (Thomas et al., 1994;
Smith and Neher, 1997; Engisch and Nowycky, 1998; Heidelberger, 1998).
This "excess retrieval" is thought to be related to cellular
housekeeping functions rather than neurotransmitter release (Smith and
Neher, 1997; Engisch and Nowycky, 1998). A third pattern of
endocytosis, "rapid endocytosis," has been observed after an
exocytotic burst in adrenal chromaffin cells (Artalejo et al., 1995). A
similar rapid retrieval of membrane has been observed only at extremely
high internal Ca2+ in synaptic terminals
(Heidelberger, 1998), and its significance to synaptic function is
unclear. Rapid endocytosis in chromaffin cells involves the GTPase
dynamin and tyrosine phosphorylation but not clathrin (Artalejo et al.,
1995; Nucifora and Fox, 1999). In contrast, very little is specifically
known about the underlying molecular mechanism of compensatory
endocytosis, particularly at synapses. Because compensatory endocytosis
is coupled both temporally and in magnitude to the preceding exocytotic
response and is the predominant mechanism in synaptic terminals, it is this form of endocytosis that is likely to play a significant role in
synaptic function.
Previous morphological studies have suggested that metabolic energy is
required for the replenishment of synaptic vesicles at active zones
(Atwood et al., 1972; Schaeffer and Raviola, 1978). ATP has also been
shown to be required at multiple reactions in receptor-mediated
endocytosis, including at the very early steps of coated pit formation
(Smythe et al., 1989; Schmid and Smythe, 1991) and at the membrane
fission step that forms a coated vesicle from a coated pit (Smythe et
al., 1989; Schmid and Carter, 1990; Schmid and Smythe, 1991). However,
because more than one pathway of membrane retrieval exists in nerve
terminals (Miller and Heuser, 1984; Koenig and Ikeda, 1996), whether
ATP was specifically required at an early step in fast compensatory
endocytosis remained uncertain. To address this question, changes in
membrane surface area associated with synaptic vesicle fusion and
retrieval were monitored using time-resolved capacitance measurements
in single synaptic terminals of retinal bipolar neurons, along with
measurements of intraterminal Ca2+. The
validity of the capacitance approach for these glutamatergic neurons is
well established (von Gersdorff et al., 1998). The results demonstrate
that, not only is ATP specifically required in the fast compensatory
endocytic pathway, but that it is necessary for endocytosis to be initiated.
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MATERIALS AND METHODS |
Preparation of synaptic terminals. Synaptic terminals
of Mb1 bipolar neurons were prepared acutely from dark-adapted goldfish retina using a combination of enzymatic and mechanical treatment (Heidelberger and Matthews, 1992). Isolated synaptic terminals were
identified on the basis of their characteristic appearance, size
(terminals of 8-12 µm in diameter), and electrophysiological profile
(Kaneko and Tachibana, 1985; Heidelberger and Matthews, 1992). All
experiments were performed at room temperature (21-24°C).
Solutions. External bathing solution for all experiments
contained (in mM): 115 NaCl, 2.6 KCl, 1.6 MgCl2, 1.0 CaCl2, 10 HEPES, and 11 glucose, pH 7.3 (255-260 mOsm). Standard internal recording solution contained (in mM): 85-100 Cs-gluconate,
10 tetraethylammonium (TEA)-Cl, 1-2
MgCl2, 33-65 mM Cs-HEPES,
0.5 GTP, 2 mM MgATP, 0.5 EGTA, and 0.2 fura-2. In
some experiments Cs-gluconate was replaced by Cs-glutamate and TEA-Cl
was reduced to 5 mM. For all internal solutions,
free Mg2+ was at least 1 mM. Internal solutions in which free
Ca2+ was defined were made by replacing
0.5 EGTA in the standard solution with a combination of 5 mM EGTA and 2.5 mM
CaCl2 to give a free Ca2+ concentration of ~150
nM. For ATP--S solutions, ATP--S was substituted for ATP and 1 mM additional
MgCl2 was added to give 3 mM MgCl2. GTP--S
solutions were based on the standard solution and contained 3.2 mM GTP--S, a total of either 3 or 10 mM MgCl2, and a reduced ATP
concentration of 1 mM. For GDP--S solutions, GDP--S replaced GTP in the standard internal solution. The pH and
osmolarity of the final internal solutions were adjusted to 7.25 and
265 mOsm, respectively. Note that ATP--S was used rather than
omitting ATP because, like other L-type calcium channels, the bipolar
neuron calcium channels require ATP to maintain their activity.
The time course of loading of terminals with internal solution was
monitored by following the increase in fura-2 fluorescence. Calculations suggest that loading with nucleotides should be slightly faster than fura-2 (Pusch and Neher, 1988), which is complete within
~50 sec after break-in in synaptic terminals. Therefore, a minimum of
50 sec was allowed for dialysis before the start of an experiment. The
nucleotide content of solutions with high ATP and GTP--S were
verified by HPLC using a spheroclone column from Phenomenex
(Torrance, CA). Cs+ salts were prepared
from CsOH purchased from Aldrich (Steinheim, Germany and Milwaulkee,
WI). Fura-2 was obtained from Molecular Probes (Eugene, OR).
ATP--S and GTP were obtained from Boehringer Mannheim (Mannheim,
Germany and Indianapolis, IN). GTP--S was obtained from Calbiochem
(La Jolla, CA) and Boehringer Mannheim (Indianapolis, IN). GDP--S
was obtained from Calbiochem. All other reagents were from Sigma
(Deisenhofen, Germany and St. Louis, MO). Internal solutions were kept
on ice and protected from light when not stored in the dark at
 20°C.
Electrical measurements. Conventional whole-cell recordings
were performed on synaptic terminals using Sylgard-coated pipettes with
resistances of 7-10 M . Because hydrostatic pressure can influence
the time course of endocytosis (R. Heidelberger and G. Matthews,
unpublished observations), the hydrostatic pressure in the pipette was
adjusted to a constant value with either a feedback-controlled device
from Lorenz (Katlenburg-Lindau, Germany) or manually with a
micrometer-controlled syringe and a monometer. In addition, the angle
of the pipette was held constant, and the pipettes were backfilled with
a fixed volume of fluid.
Electrical recordings were made using the computer-controlled EPC-9
patch-clamp amplifier from Heka Elektronik (Lambrecht, Germany).
Capacitance measurements were performed using the software emulation of
a two-phase lock-in amplifier that is provided as part of the EPC-9
Pulse software (Heka Elektronik) or with the automatic capacitance
compensation of the EPC-9 amplifier (Chow et al., 1992; Heidelberger et
al., 1994). With the software lock-in amplifier, a 1600 Hz sinusoidal
stimulus,  32 mV peak-to-peak, was applied about the DC holding
potential. The resulting current was processed using the Lindau-Neher
technique (Lindau and Neher, 1988; Gillis, 1995) to give estimates of
the equivalent circuit parameters (Cm,
Gs, and
Gm). The reversal potential of
the measured DC current was assumed to be 0. For all experiments, the
holding potential, Vh, was 60 mV and
all depolarizations were to 0 mV. Terminals with leak current greater
than 40 pA were excluded from analysis.
Calcium measurements. For measurement of the average
intraterminal Ca2+, alternating excitation
at 345 and 390 nm was typically provided by a computer-controlled
monochrometer-based system from ASI/T.I.L.L. Photonics (Eugene, OR) as
described previously (Messler et al., 1996). In some experiments,
alternating excitation was provided by a two-flash lamp system from
T.I.L.L. Photonics (Graefeling, Germany). Emitted fluorescence was
collected from an ~20-µm-diameter spot in the object plane through
a 470 nm long-pass and a 540 nm short-pass filter and, for the
monochrometer-based system, detected by a photomultiplier tube (model
R928; Hamamatsu, Hamamatsu City, Japan) or photodiode (model S4753-02;
Hamamatsu). This fluorescence signal was sampled by the EPC-9 and
acquired using the Fura extension of the Pulse software. For the
two-flash lamp system, both excitation and emitted light were detected
by photodiodes, simultaneously integrated, and digitized (Heinemann et
al., 1994). Fura-2 calibrations were performed in terminals using
Ca2+-EGTA-buffered solutions
(Heidelberger and Matthews, 1992). Because of potential
complications of changes in intraterminal
Ca2+ altering the rate of endocytosis (von
Gersdorff and Matthews, 1994), terminals with resting
Ca2+ >300 nM were
excluded from analysis.
Analysis. To control for differences in internal solutions
and variability in cell preparations, data were either collected in a
pairwise manner or compared with control data obtained under identical
experimental conditions. Data were exported into Igor from WaveMetrics
Inc. (Lake Oswego, OR) for analyses. More than 75 terminals that had
Ca2+ and capacitance responses were
examined for this study; however, many terminals were excluded from
analyses as a result of the strict criteria of a resting
Ca2+ <300 nM and a
leak current less than 40 pA. Terminals were also excluded if the
first stimulation was given earlier than 50 sec after break-in. ATP
hydrolysis is required for refilling of the release-ready pool of
synaptic vesicles (Heidelberger, 1998) (R. Heidelberger, P. Sterling, and G. Matthews, unpublished observations); therefore, in
experiments comparing the effects of ATP--S with ATP on endocytosis,
only the first endocytotic response was analyzed. For all experiments,
n represents the number of terminals examined rather than
the total number of times the event was witnessed. All pooled data are
expressed as mean ± SEM. Comparisons between test groups and
controls were analyzed with a two-sample t test or a paired
t test using SAS software (SAS Institute, Cary, NC).
Statistically significant differences are indicated in the text and
figure legends.
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RESULTS |
ATP is acutely required for fast endocytosis
Observations from a previous study in which exocytosis was evoked
by flash-photolysis of caged Ca2+ provided
hints that, in addition to its role in maintaining exocytosis, ATP
might be required for fast compensatory endocytosis in synaptic terminals (Heidelberger, 1998). However, this interpretation was tenuous because of the global elevation of
Ca2+ and the reported inhibitory effects
of high cytosolic Ca2+ on endocytosis (von
Gersdorff and Matthews, 1994; Rouze and Schwartz, 1998; Neves and
Lagnado, 1999). To address the role of ATP under more controlled
conditions, acutely isolated synaptic terminals of retinal bipolar
neurons were voltage clamped, and exocytosis followed by compensatory
synaptic endocytosis was triggered by stepping the membrane potential
from 60 to 0 mV. This protocol activates
Ca2+ influx through presynaptic L-type
Ca2+ channels (Heidelberger and Matthews,
1992) to trigger the release of the neurotransmitter glutamate
(Tachibana et al., 1993; von Gersdorff et al., 1998). Changes in
surface area associated with membrane addition and retrieval were
monitored using time-resolved membrane capacitance measurements, and
intraterminal Ca2+ was ratiometrically
calculated with the fluorescent Ca2+
indicator dye fura-2 (Heidelberger and Matthews, 1992). As expected (von Gersdorff and Matthews, 1994a), after a 500 msec depolarization, terminals dialyzed with ATP-containing internal solution exhibited exocytosis followed by fast compensatory endocytosis (Fig.
1A). In contrast,
terminals dialyzed with internal solution containing ATP--S secreted
in response to a first stimulus, but they failed to rapidly retrieve
membrane (Fig. 1B). The mean time constant of
endocytosis was more than four times longer in terminals with ATP--S
than in ATP terminals (ATP--S,  = 26 ± 8 sec,
n = 5; ATP, = 5.5 ± 1 sec,
n = 6), indicating that ATP may be required for fast
compensatory endocytosis. This inhibitory action of ATP--S was
observed <60 sec after achieving the whole-cell recording configuration, suggesting that ATP is acutely required for compensatory endocytosis. However, internal Ca2+ failed
to fully return to resting levels after stimulation without ATP. Even
when 1 mM EGTA was added to the ATP--S
solution to increase the Ca2+ buffering
capacity, the mean resting poststimulus
Ca2+ was ~203% of the prestimulus
resting Ca2+ (n = 5)
compared with ATP controls, in which the poststimulus Ca2+ returned to within 15% of the basal
level (n = 5).
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Figure 1.
Terminals dialyzed with ATP but not ATP--S
exhibit fast compensatory endocytosis. A, The
time-resolved capacitance record of an isolated synaptic terminal
dialyzed with standard internal solution (2 mM ATP). In
response to a 500 msec depolarization from a
Vh of 60 to 0 mV, the membrane capacitance
(Cm) increased by ~186 fF. The time
course of restoration of the membrane capacitance back to baseline
could be described by a single exponential with a time constant of
~2.96 sec. The corresponding membrane conductance
(Gm) and series conductance
(Gs) are shown in the bottom
panels. Lack of correlated changes between
Cm and Gs or
Gm suggest that changes in
Cm reflect changes in membrane surface area.
B, The time-resolved capacitance record of an isolated
synaptic terminal dialyzed with internal solution in which 2 mM ATP was replaced by 2 mM ATP--S. In
response to a 500 msec depolarization from a
Vh of 60 to 0 mV, the membrane capacitance
increased by ~55 fF. Note the slow time course of membrane retrieval.
Gm and Gs are
shown in the bottom panels. Again, there are no
correlated changes in Cm and
Gm or Gs. For
both A and B, timing of the
depolarization is given by the arrow. Terminals are from
the same trituration.
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The requirement for ATP is not mediated
by Ca2+
To distinguish between a direct requirement of ATP in fast
endocytosis from an indirect requirement mediated by elevation of
cytosolic Ca2+,
Ca2+ was defined in the internal solutions
to be 150 nM, a value close to resting internal
Ca2+ in undialyzed synaptic terminals
(Heidelberger and Matthews 1992). Figure
2 shows representative capacitance
responses from a pair of terminals dialyzed with
Ca2+-EGTA-buffered internal solutions
containing either ATP (Fig. 2A) or ATP--S (Fig.
2B). In both terminals, a 500 msec depolarizing voltage step from 60 to 0 mV evoked a transient increase in
intraterminal Ca2+ that triggered the
addition of membrane. Whereas the terminal with ATP exhibited a rapid
return of membrane capacitance to baseline ( = 3.2 sec),
endocytosis was completely blocked in the terminal with ATP--S. The
mean time constant of endocytosis in terminals dialyzed with
Ca2+-buffered internal solution containing
ATP was 2.58 ± 0.32 sec (n = 8) (Fig.
3A), in good agreement with
values reported previously for the time course of fast endocytosis in
synaptic terminals (von Gersdorff and Matthews, 1994a,b). In contrast,
the mean time constant of endocytosis was 67.0 ± 30 sec
(n = 6) in ATP--S terminals (Fig. 3A),
excluding four terminals in which there was no return of the membrane
capacitance during the observed time interval (>40 sec after
stimulation). The inhibition of fast endocytosis by ATP--S,
introduced into the terminals as a Li+
salt, could not be attributed to the presence of
Li+. At concentrations of up to 20 mM, Li+ did not
significantly effect the time course of fast endocytosis ( = 2.69 ± 0.85 sec, n = 5). In addition, the
Li+ salt of another nucleotide, GTP--S,
did not block fast endocytosis (Fig.
4).
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Figure 2.
ATP--S does not support rapid endocytosis, even
when differences in internal Ca2+ are minimized.
A, B, Top panels, The
capacitance records from isolated synaptic terminals dialyzed with
Ca2+-EGTA-buffered internal solutions containing
either ATP (A) or ATP--S
(B). Exocytosis was evoked by a 500 msec
depolarization from 60 to 0 mV. Fast endocytosis followed exocytosis
with ATP but not ATP--S. Timing of the depolarizations are indicated
by the arrows. Bottom panels, The
corresponding Ca2+ records, ratiometrically
calculated from changes in fura-2 fluorescence.
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Figure 3.
The ATP requirement for endocytosis is independent
of intraterminal Ca2+. A, Exocytosis
followed by endocytosis was evoked by a 500 msec depolarization from
60 to 0 mV. The mean endocytosis time constant is shown for terminals
dialyzed with Ca2+-EGTA-buffered internal solutions
containing either ATP (n = 8; black
bar) or ATP--S (n = 6; gray
bar). Four terminals dialyzed with ATP--S-containing
internal solution failed to endocytose in the >40 sec after
exocytosis and are not included in this figure. B, There
are no statistical differences in the mean Ca2+
parameters between terminals with ATP versus ATP--S when
Ca2+-buffered internal solutions are used. Same
group of terminals as in A. Data are expressed as
mean ± SEM.
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Figure 4.
GTP--S does not block endocytosis, but it does
decrease the amplitude of exocytosis. A, Capacitance
record from the synaptic terminal of a bipolar neuron that was dialyzed
with internal solution containing 3.2 mM GTP--S and 2 mM Mg2+. Two 2 sec depolarizations from
60 to 0 mV were given at the times indicated by the
arrows to evoke exocytosis. Note the reproducibility of
the response. The time constant of endocytosis was ~4 sec.
B, Pooled data showing the average time constant of
endocytosis from five cells (9 responses) dialyzed with GTP--S
compared with ATP terminals (2 or 10 mM;
n = 8). In GTP--S cells, free
Mg2+ was either 2 mM
(n = 3) or 10 mM (n = 2). Voltage steps were from 60 to 0 mV and were 0.25-1 sec in
duration. Data expressed as mean ± SEM. C, The
amplitude of the capacitance response to a 500 msec depolarization was
diminished in terminals with GTP--S (n = 5;
light gray bar) relative to terminals with
Ca-EGTA-buffered internal solutions containing either ATP
(n = 13; black bar) or ATP--S
(n = 15; dark gray bar) or
literature estimates (dotted line) of the average size
of the release-ready pool of synaptic vesicles in bipolar neuron
synaptic terminals (Heidelberger, 2001). Increasing the duration of
Ca2+ influx to 2 sec increased the amplitude of the
capacitance response in GTP--S terminals (n = 6 terminals, 12 responses).
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The Ca2+ records in Figure 2 indicate that
intraterminal Ca2+ returned to baseline
after closure of Ca2+ channels with either
ATP or ATP--S when using a
Ca2+-buffered internal solution. Analysis
of the Ca2+ records indicated that there
were no significant differences in the resting
Ca2+ before and after a stimulus between
terminals with ATP or ATP--S (Fig. 3B). Furthermore,
there was no statistically significant difference in the peak
Ca2+ after membrane depolarization
or in the time course or recovery of
Ca2+ to basal levels (Fig. 3B).
Thus, intraterminal Ca2+ was well
controlled in these experiments and comparable between groups. In
addition, little rundown of ICa was
observed with successive depolarizations in terminals with either ATP
or ATP--S, consistent with the suggestion that
Ca2+ did not remain high under the
membrane (data not shown). Therefore, the inability of terminals with
ATP--S to rapidly retrieve membrane after exocytosis cannot be
ascribed to differences in Ca2+ between
terminals with ATP or ATP--S, indicating that the role of ATP in
fast endocytosis is independent of its role in regulating intraterminal
Ca2+.
Neither GTP--S nor GDP--S inhibit fast endocytosis
To determine whether the observed requirement for ATP was direct
or mediated via the intraterminal conversion of ATP--S to GTP--S,
terminals were dialyzed with internal solution in which (1) GTP was
omitted and the nonhydrolyzable GTP analog GTP--S was added at a
concentration of 3.2 mM, (2) the ATP concentration was
reduced from 2 to 1 mM, and (3) free
Mg2+ concentration was either 2 or 10 mM to facilitate nucleotide exchange. Figure
4A shows a representative recording. Each exocytotic response was followed by the rapid retrieval of membrane and the restoration of membrane capacitance to baseline. That terminals can
exocytose in the presence of GTP--S is not surprising given that the
inhibition of exocytosis by GTP--S is a very slow process (Hess et
al., 1993; Artalejo et al., 1995). Interestingly, the mean time
constant of endocytosis in GTP--S terminals ( = 3.19 ± 0.72 sec, n = 3 terminals, 7 responses) was virtually
identical to controls ( = 3.20 ± 0.56 sec,
n = 8) for depolarizations <1 sec in duration (Fig.
4B) and quite distinct from the prolonged time course
of endocytosis observed with ATP--S (Figs. 1-3). Longer depolarizations, which give rise to slower rates of endocytosis (von
Gersdorff and Matthews, 1994a,b), failed to consistently reveal an
inhibitory effect of GTP--S on endocytosis. Of the six terminals
with GTP--S that met the criteria for analysis, only one did not
exhibit compensatory endocytosis, and there was no statistically
significant difference between the mean time constant for endocytosis
after a 2 sec depolarization in terminals with GTP--S compared with
controls (GTP--S, = 13.66 ± 4.65 sec,
n = 6 terminals, 12 responses; controls, = 5.46 ± 1.93 sec, n = 5 terminals, 8 responses;
p = 0.13). GTP--S did appear to have a suppressive
effect on the mean amplitude of the membrane addition triggered by a
500 msec depolarization (Fig. 4C). This could be overcome by
increasing the duration of the membrane depolarization (Fig.
4C), consistent with a smaller average peak
ICa in GTP--S terminals (GTP--S,
66 ± 5 pA, n = 7; GTP, 173 ± 18 pA,
n = 12). GTP--S has been reported to decrease
ICa in adrenal chromaffin cells
(Artalejo et al., 1995) and in neurons (Scott et al., 1991). G-proteins
may also inhibit exocytosis downstream of
Ca2+ entry (Blackmer et al., 2001).
Next, the nonhydrolyzable guanosine diphosphate GDP--S was
substituted for GTP in the internal solution. GDP--S also failed to
block fast endocytosis (Fig.
5A). The mean time constant of endocytosis in terminals dialyzed with GDP--S was 3.06 ± 0.86 sec (n = 4) (Fig. 5B). Longer
depolarizations (2-5 sec in duration) also failed to block fast
endocytosis ( = 4.96 ± 0.45 sec, n = 5).
As with GTP--S, the average amplitude of the capacitance response
with GDP--S after a 500 msec depolarization was smaller (58 ± 18 fF, n = 4) than the average size of the response
with ATP (Fig. 4C), and ICa
was smaller, on average, in amplitude (49 ± 7 pA,
n = 4). The lack of a dramatic, quick inhibition of
endocytosis by either GTP--S or GDP--S suggests that the rapid
inhibition of fast endocytosis by ATP--S reflects an acute and
specific requirement for ATP over GTP.
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Figure 5.
GDP--S does not inhibit endocytosis.
A, Capacitance record from an isolated synaptic terminal
that was dialyzed with an internal solution containing GDP--S in
place of GTP. Exocytosis was evoked by a 500 msec depolarization from
60 to 0 mV. Timing of depolarization is indicated by the
arrow. The time constant of membrane recovery was 3.5 sec. B, Pooled data show that GDP--S terminals
(n = 4; gray bar) endocytosed with a
nearly identical time course as ATP terminals (2 or 10 mM;
n = 8; black bar) after 500 msec
depolarizations (GDP--S) or 0.250-1 sec depolarizations
(ATP).
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Depletion of ATP does not mediate the reported calcium-dependent
inhibition of fast endocytosis
Endocytosis is Ca2+ sensitive in
nerve terminals, with higher internal Ca2+
concentrations slowing the rate of membrane retrieval (von Gersdorff and Matthews, 1994; Hsu and Jackson, 1996; Neves and Lagnado, 1999).
However, reports from other cells have indicated that elevated internal
Ca2+ may stimulate endocytosis (Engisch
and Nowycky, 1998; Klingauf et al., 1998; Sankaranarayanan and Ryan,
2001). Because intraterminal Ca2+ is
regulated primarily by plasma membrane
Ca2+ ATPases (Zenisek and Matthews, 2000),
it is conceivable that depletion of ATP attributable to high
Ca2+ might underlie the reported
Ca2+-dependent inhibition of endocytosis
in synaptic terminals. To test this hypothesis, the relationship
between ATP, Ca2+, and the rate of
compensatory membrane retrieval was examined. First, ATP in the
internal solution was increased from 2 to 10 mM (Fig.
6). After membrane depolarization,
terminals with high ATP exhibited fast endocytosis after
Ca2+-triggered exocytosis with time
constants indistinguishable from controls (2 mM ATP,
= 2.85 ± 0.70 sec, n = 18; 10 mM ATP, = 3.2 ± 0.58 sec,
n = 4 terminals, 8 responses), indicating that 2 mM ATP is sufficient to support fast endocytosis
in response to moderate stimulation. When the duration of
depolarization was increased to 2 sec, the time constant of endocytosis
increased as expected (von Gersdorff and Matthews, 1994a,b), but the
mean time constants of endocytosis were not statistically different between the two conditions (10 mM ATP, 4.82 ± 0.87 sec, n = 3 terminals, 6 responses; 2 mM ATP, 5.46 ± 1.93 sec, n = 4 terminals, 8 responses). These results suggest that depletion of
cytosolic ATP does not underlie the prolongation of the time course of
compensatory endocytosis observed with a long depolarization.
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Figure 6.
The time course of Ca2+
recovery predicts the time course of endocytosis. A,
B, Top panels show the capacitance
records from synaptic terminals of bipolar neurons dialyzed with
internal solution containing 10 mM ATP and stimulated to
exocytose with either a 500 msec (A) or 1 sec
(B) depolarization from 60 to 0 mV.
Bottom panels, The ratiometrically calculated
intraterminal Ca2+ determined with fura-2.
Insets show the corresponding Ca2+
current. The thickness of the trace that
precedes and follows the inward current carried by
Ca2+ is attributable to the superimposed sine wave
stimulus used to monitor membrane capacitance. Curves in
the top panels are the time course of membrane recovery
predicted from the recovery time course of intraterminal
Ca2+. Curves were drawn according to the following:
Cm(t) = a + be  t, where
 (t) = 0.54(1 1/(1 + (0.460/[Ca2+])4)), from von Gersdorff
and Matthews (1994b). C, Black bars show
the mean rate of endocytosis experimentally observed in terminals with
10 mM ATP after depolarizations of the indicated durations
from 60 to 0 mV. Gray bars show the rate of
endocytosis predicted from the recovery time course of intraterminal
Ca2+. For mild to moderate duration depolarizations,
the time course of endocytosis matched the time course of endocytosis
predicted by the time course of recovery of intraterminal
Ca2+ in terminals with 10 ATP. However, after a 2 sec depolarization, there was a statistically significant difference
between the measured and the predicted rates of endocytosis
(p < 0.005). After a 5 sec depolarization,
the measured and predicted rates were also significantly different
(p < 0.07). For 500 msec,
n = 4 responses, 2 terminals. For 1 sec,
n = 2 responses, 1 terminal. For 2 sec,
n = 4 responses, 3 terminals. For 5 sec,
n = 5 responses, 3 terminals. Data are expressed as
mean ± SEM.
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The question of whether the reported relationship between
Ca2+ and the time course of endocytosis
(von Gersdorff and Matthews, 1994b) still held when ATP was high was
addressed next. If this relationship did not hold, this would also lend
support to the hypothesis that inhibition of endocytosis by elevated
intraterminal Ca2+ was not directly
mediated by Ca2+ but rather by ATP
depletion. After the closure of voltage-gated Ca2+ channels, intraterminal
Ca2+ typically recovered with a time
course described by a single exponential function (Fig. 6). The
predicted time course of endocytosis was calculated from this using the
published relationship between intraterminal
Ca2+ and the rate of membrane retrieval
(von Gersdorff and Matthews, 1994b). The time course of endocytosis
predicted by the intraterminal Ca2+ (Fig.
6A, curve) is superimposed on the record
of membrane capacitance (Fig. 6A, dots).
There is good agreement between the time course of endocytosis that was
predicted by recovery of internal Ca2+ and
the observed time course of endocytosis. Figure 6B
shows a similar analysis of a 1 sec depolarization. As has been noted previously for long depolarizations (von Gersdorff and Matthews, 1994;
Neves and Lagnado, 1999), the capacitance record exhibited a brief
delay between the end of membrane addition and the start of
endocytosis, and this delay was mimicked by the time course of
endocytosis predicted from the time course of
Ca2+ recovery (Fig. 5B).
To better compare the predicted time course of endocytosis with the
observed time course, both time courses after the delays were fitted
with single exponential functions, and the resultant rate constants
were compared (Fig. 6C). For the terminals stimulated with a
250-500 msec depolarization, the predicted rate constant of
endocytosis and the observed rate constant for endocytosis were
indistinguishable (predicted rate constant, 0.576 ± 0.044 sec1; observed rate constant, 0.562 ± 0.080 sec1; n = 4).
Similarly, the predicted rate constant of endocytosis and the observed
rate constant of endocytosis evoked by 1 sec depolarizations were in
good agreement (predicted, 0.694 ± 0.02 sec1; observed, 0.625 ± 0.165 sec1; n = 2). These
findings suggest that, for mild to moderate stimulation protocols, the
rate of fast endocytosis does follow a fourth-order dependence on the
average cytosolic Ca2+ (von Gersdorff and
Matthews, 1994), provided that the requirement for ATP is met. For
depolarizations 2-5 sec in duration, the observed time course of
endocytosis was significantly slower than that predicted by the rate of
recovery of intraterminal calcium (observed rate constant, 0.254 ± 0.068 sec1; predicted rate constant,
0.613 ± 0.039 sec1;
n = 10), consistent with previous reports (von
Gersdorff and Matthews, 1994). Although the difference between the
observed rate of endocytosis and the rate predicted by the cytosolic
calcium achieved statistical significance only for depolarizations  2 sec in duration, there was a trend for the disparity between the observed rate and the predicted rate of endocytosis to increase with
increasing stimulus duration. This is consistent with an activity-dependent suppression in the apparent rate of fast
endocytosis. The mechanism(s) underlying this apparent slowing is
unknown, but the present experiments with high intraterminal ATP
suggest that local depletion of ATP is not likely to be the major mechanism.
| |
DISCUSSION |
Although there have been indications that ATP may be required for
membrane retrieval, the present study is the first to specifically examine the role of ATP in fast compensatory endocytosis in a synaptic
terminal. The data indicate that ATP, apart from its role in regulating
intraterminal Ca2+, is required for fast
compensatory endocytosis that follows glutamate exocytosis in retinal
bipolar neurons. Interestingly, the inhibition of endocytosis by
ATP--S was evident after the very first round of exocytosis and as
early as 1 min after achieving the whole-cell recording configuration.
This suggests that fast compensatory endocytosis has an acute and
dynamic requirement for ATP.
The inability of GTP--S and GDP--S to affect fast compensatory
endocytosis in synaptic terminals indicates that hydrolysis of ATP,
rather than GTP, may be acutely required. This is an important observation because it implies that the mechanism of fast compensatory endocytosis is different from that of the rapid endocytosis observed in
calf adrenal chromaffin cells after an exocytotic burst, which is
inhibited by both GTP--S and GDP--S (Artalejo et al., 1995; Nucifora and Fox, 1999). Furthermore, these results suggest that dynamin, a GTPase with a well documented role in membrane fission in
receptor-mediated endocytosis (Cremona and De Camilli, 1997; Schmid et
al., 1998), may play little role in compensatory synaptic endocytosis,
although this remains to be directly tested. It is also conceivable
that a large Ca2+ signal, such as that
produced by a combination of flash-photolysis of caged calcium and
membrane depolarization (Heidelberger, 1998), may reveal a form of
rapid endocytosis that is sensitive to GTP in synaptic
terminals. However, the present study focused on the regulation of
compensatory endocytosis that follows exocytosis triggered by
Ca2+ influx through voltage-gated channels
because of the physiological relevance of this type of stimulation. As
such, the data provide a clear indication that ATP, but not GTP, is
acutely required for the fast compensatory endocytosis that follows
exocytosis triggered by Ca2+ influx in
synaptic terminals.
Provided that at a minimum of 1 mM ATP was supplied
internally, the rate of synaptic endocytosis was independent of ATP
concentration and followed the previously described fourth-order
relationship between the rate of synaptic endocytosis and intraterminal
Ca2+ quite well (von Gersdorff and
Matthews, 1994). This is an important conformation because, in addition
to reports that high intraterminal Ca2+
can suppress endocytosis in nerve terminals (von Gersdorff and Matthews, 1994; Hsu and Jackson, 1996; Rouze and Schwartz, 1998; Neves
and Lagnado, 1999; Cousin and Robinson, 2000), intracellular Ca2+ has also been suggested to favor fast
endocytosis (Engisch and Nowycky, 1998; Klingauf et al., 1998;
Sankaranarayanan and Ryan, 2001) or have little effect on membrane
retrieval (Ramaswami et al., 1994; Wu and Betz, 1996). Interestingly,
the discord between the rate of endocytosis predicted by the
Ca2+ time course and the experimentally
observed rate after strong stimulation was not ameliorated by high ATP.
This suggests that local depletion of ATP, in addition to not mediating
the Ca2+ dependence of endocytosis under
standard conditions, does not underlie the profound slowing of the time
course of endocytosis that is observed after strong stimulation
protocols (von Gersdorff and Matthews, 1994a,b; Neves and Lagnado,
1999; present study). Together, these observations establish that ATP
plays a different role in regulating compensatory endocytosis in
synaptic terminals than Ca2+.
So where might the ATP-dependent step in compensatory synaptic
endocytosis lie? The capacitance approach, because it monitors membrane
addition and retrieval, indicates that ATP is required for membrane
fission. Therefore, the observed acute requirement for ATP in
compensatory synaptic endocytosis must reflect either a requirement at
the membrane fission step (Fig.
7A) or a step that is
absolutely a prerequisite for and temporally associated with membrane
fission (Fig. 7B). Precedence for the first role comes from
receptor-mediated endocytosis, in which ATP has been suggested to be
necessary for the creation of a coated vesicle from a coated pit
(Smythe et al., 1989; Schmid and Carter, 1990; Schmid and Smythe,
1991). This interaction could be mediated by actin, an ATPase that may
act as a force generator during fission (Lamaze et al., 1997; Qualmann
et al., 2000). A prefission role for ATP may be subserved by ATPases
such as N-ethylmaleimide-sensitive factor (NSF) or
Hrs-2, both of which are implicated in early steps of membrane
retrieval by virtue of their roles in dissembling and/or sorting
soluble NSF attachment protein receptor (SNARE) proteins (Hay
and Scheller, 1997; Kawasaki et al., 1998; Bean et al., 2000).
In particular, ATP--S-bound NSF is known to inhibit disassembly of
the 20S SNARE complex, whereas without ATP, this stable complex is not
formed (Hanson et al., 1997). Thus, by locking the 20S complex,
ATP--S may uniquely inhibit protein sorting with the consequence
that newly added membrane is unable to be retrieved by the fast
compensatory pathway. Alternative explanations are also possible. ATP
could regulate an early step in compensatory endocytosis via a
phosphorylation reaction that is poorly supported by ATP--S. In
addition, ATP--S could conceivably inhibit endocytosis by
thiophosphorylating a protein important for triggering endocytosis when
in its dephosphorylated state. This would be consistent with the
observation that the rate of endocytosis is enhanced when protein
phosphorylation is inhibited (Henkel and Almers, 1996; Kavalali et al.,
1999). Unfortunately, the ATP requirement of the calcium channels in
synaptic terminals does not allow this hypothesis to be readily
examined. However, in experiments in which intraterminal
Ca2+ was elevated via flash-photolysis of
caged Ca2+, compensatory endocytosis was
lost when ATP was not included in the internal solution (Heidelberger
et al., 1994; Heidelberger, 1998), favoring the hypothesis that ATP
hydrolysis, rather than dephosphorylation of a protein, may be required
for endocytosis. However, as stated previously, the global elevation of
cytosolic Ca2+ in photolysis experiments
makes a mechanistic interpretation of these data difficult. Clearly, it
will be of great interest to determine the underlying mechanism of ATP
action in the fast compensatory endocytosis pathway. The present
results lead the way by suggesting that, in a glutamatergic synaptic
terminal, ATP is involved in a step or steps necessary for membrane
fission after the Ca2+-dependent vesicular
release of neurotransmitter.
View larger version (17K):
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|
Figure 7.
Possible locations of an early requirement for ATP
in the fast compensatory endocytosis pathway in synaptic terminals.
A, ATP may be required for the membrane fission step of
the fast compensatory pathway, perhaps by acting as an energy source.
B, ATP may be required for a postfusion step that is
prerequisite for membrane retrieval via the fast compensatory pathway
but not be needed for fission. This ATP-dependent step might reflect
the disassembly and sorting of SNARE complexes. In addition, the
possibility that ATP may both play a prefission role and act at the
fission step is not excluded.
|
|
| |
FOOTNOTES |
Received April 18, 2001; revised June 6, 2001; accepted June 13, 2001.
This work was supported by National Institutes of Health Grant EY12128,
the Esther A. and Joseph Klingenstein Fund, and the Alfred P. Sloan
Foundation. I thank Erwin Neher and Gary Matthews for their
contributions to the early phases of this project. I thank Andrew Bean
and Neal Waxham for stimulating discussions and for performing the HPLC
analysis of nucleotide solutions (N. Waxham). I thank Alice
Chuang and the Core Grant for Vision Research (National Eye Institute
Grant EY10608) for providing statistical support and Kate Pearson for
her excellent technical assistance.
Correspondence should be addressed to Ruth Heidelberger, Department of
Neurobiology and Anatomy, University of Texas Houston Health Science
Center, Houston, TX 77025. E-mail: ruth.heidelberger{at}uth.tmc.edu.
| |
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ABSTRACT
INTRODUCTION
