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The Journal of Neuroscience, January 15, 1999, 19(2):726-736
Calcium Channel Types with Distinct Presynaptic Localization
Couple Differentially to Transmitter Release in Single Calyx-Type
Synapses
Ling-Gang
Wu1,
Ruth E.
Westenbroek2,
J. Gerard G.
Borst1,
William A.
Catterall2, and
Bert
Sakmann1
1 Abteilung Zellphysiologie, Max-Planck-Institut
für medizinische Forschung, D-69120 Heidelberg, Germany, and
2 Department of Pharmacology, University of Washington,
Seattle, Washington 98195-7280
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ABSTRACT |
We studied how Ca2+ influx through different
subtypes of Ca2+ channels couples to release at a
calyx-type terminal in the rat medial nucleus of the trapezoid
body by simultaneously measuring the presynaptic
Ca2+ influx evoked by a single action potential and
the EPSC. Application of subtype-specific toxins showed that
Ca2+ channels of the P/Q-, N-, and R-type controlled
glutamate release at a single terminal. The Ca2+
influx through the P/Q-type channels triggered release more effectively than Ca2+ influx through N- or R-type channels. We
investigated mechanisms that contributed to these differences in
effectiveness. Electrophysiological experiments suggested that
individual release sites were controlled by all three subtypes of
Ca2+ channels. Immunocytochemical staining
indicated, however, that a substantial fraction of N- and R-type
channels was located distant from release sites. Although these distant
channels contributed to the Ca2+ influx into the
terminal, they may not contribute to release. Taken together, the
results suggest that the Ca2+ influx into the calyx
via N- and R-type channels triggers release less effectively than that
via P/Q-type because a substantial fraction of the N- and R-type
channels in the calyx is localized distant from release sites.
Key words:
Ca2+ channels; presynaptic; calyx of
Held; voltage clamp; antibody; immunocytochemistry; P-type
Ca2+ channels; N-type Ca2+
channels; R-type Ca2+ channels; synaptotagmin; fura-2; rat
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INTRODUCTION |
Fast neurotransmitter release
depends strongly on the extracellular Ca2+
concentration (Dodge and Rahamimoff, 1967 ; Katz, 1969). By changing the
Ca2+ influx through all presynaptic
Ca2+ channels, a quantitative estimate of the
relation between intracellular Ca2+ concentration at
the release sites ([Casite]) and release may be obtained.
This relation is often approximated by:
![<UP>Release</UP> ∝ [<UP>Ca</UP><SUB><UP>site</UP></SUB>]<SUP><IT>n</IT></SUP>](/content/vol19/issue2/fulltext/726/img001.gif)
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(1)
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where n is between 3 and 4 (for review, see Wu and
Saggau, 1997).
Ca2+ channel subtypes have been classified as T-,
L-, N-, P-, Q-, and R-type on the basis of their different
pharmacological and biophysical properties (Dunlap et al., 1995).
Different Ca2+ channel subtypes have different
pore-forming  1 subunits. The 1A subunits
form P/Q-type, 1B subunits form N-type, and
1E subunits form R-type Ca2+ channels
(Dunlap et al., 1995). Most of these Ca2+ channel
subtypes can be blocked by specific toxins. These toxins have a high
affinity for Ca2+ channels and presumably unbind
from Ca2+ channels much slower than inorganic
Ca2+ channel blockers such as
Cd2+ (Yoshikami et al., 1989; Mintz et al., 1995).
The toxins can be used to measure the contribution of the different
channel subtypes to transmitter release. If both the volume-averaged
presynaptic Ca2+ concentration
([Caterminal]) and release are monitored in experiments in which a Ca2+ channel subtype is specifically
blocked, an estimate for the effectiveness (m) of that
subtype in controlling transmitter release (Wu and Saggau, 1997) can be
obtained from:
![<UP>Release</UP> ∝ [<UP>Ca</UP><SUB><UP>terminal</UP></SUB>]<SUP>m</SUP>](/content/vol19/issue2/fulltext/726/img002.gif)
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(2)
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Relations 1 and 2 have a similar format but different physical
meanings. The parameter m is defined here as a measure of how effectively Ca2+ influx into a terminal via a
particular subtype of Ca2+ channels triggers
release. The parameter n, most likely, is a measure of the
cooperative binding of intracellular Ca2+ to the
Ca2+ sensor at a release site (Dodge and Rahamimoff,
1967).
The values of m for different subtypes of
Ca2+ channels may differ in single terminals and can
be different from n (Mintz et al., 1995; Wu et al., 1998).
These differences may provide information about the spatial
organization of release sites and Ca2+ channels. For
example, if each release site is controlled by the
Ca2+ domain near a single open
Ca2+ channel, reducing the number of active
Ca2+ channels by applying a channel subtype-specific
toxin will cause a linear reduction of release, resulting in
m = 1 (Yoshikami et al., 1989; Augustine et al., 1991).
However, evidence suggests that multiple Ca2+
channels contribute to release in a single release site in many central
synapses (Mintz et al., 1995; Borst and Sakmann, 1996, 1999; Wu and
Saggau, 1997). When a release site is controlled by multiple
Ca2+ channels, several mechanisms may be responsible
for different values of m. As an example, assume that two
subtypes of Ca2+ channels (types 1 and 2), with each
contributing one half of the total Ca2+ influx, are
present in a terminal with two release sites. If the channel subtypes
are completely segregated, with one subtype being present exclusively
on the first release site and the other one only on the second,
blocking one subtype of Ca2+ channels will reduce
both Ca2+ influx and release by half, meaning that
m for both subtypes would be only 1. The value m
thus depends on the distribution of a subtype of
Ca2+ channels at different release sites (Mintz et
al., 1995; Reid et al., 1998; see ). An alternative mechanism
applies when type 1 Ca2+ channels are located so far
from the release sites that they do not contribute to release. In that
case, m is zero for type 1 and infinity for type 2 channels
when these channel types are blocked. If type 1 Ca2+
channels are, on average, more distantly located from the release sites
than type 2 channels, m for type 1 will be lower than for type 2. Thus, m also depends on the distance between the
channel and the release sites (Artalejo et al., 1994).
Here, we investigated mechanisms underlying differences in m
of Ca2+ channel subtypes at the medial nucleus of
the trapezoid body (MNTB) (Wu et al., 1998). In contrast to other
studies that determined the effectiveness of a Ca2+
channel subtype from a population of synapses (Wu and Saggau, 1994;
Mintz et al., 1995), we measured m by simultaneously
recording the presynaptic Ca2+ influx and release at
single synapses (Wu et al., 1998). Because of the large size of the
presynaptic calyx, the subcellular distribution of different subtypes
of Ca2+ channels can be studied with
immunocytochemical techniques (Westenbroek et al., 1992, 1995; Yokoyama
et al., 1995). We found that transmitter release from the calyx was
controlled by P/Q-, N-, and R-type channels. However, the effectiveness
of P/Q-type Ca2+ channels was higher than of N- and
R-type channels. This difference was most likely caused by a larger
fraction of N- and R-type than P/Q-type channels being located distant
from release sites.
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MATERIALS AND METHODS |
Slices were cut from the brainstems of 8- to 10-d-old Wistar
rats, transferred to a recording chamber and perfused at room temperature (23-24°C) with a solution containing (in
mM): 125 NaCl, 2.5 KCl, 1 MgCl2, 2 CaCl2, 25 dextrose, 1.25 NaH2PO4, 0.4 ascorbic acid, 3 myo-inositol, 2 sodium pyruvate, and 25 NaHCO3, pH 7.4, when bubbled with 95%
O2 and 5% CO2 (Borst et al., 1995). Whole-cell
current-clamp recordings from terminals were made with an AxoClamp-2B
(Axon Instruments, Foster City, CA) amplifier and glass pipettes (8-12
M ) containing (in mM): 115 potassium gluconate, 20 KCl,
4 MgATP, 10 Na2-phosphocreatine, 0.3 GTP, 10 HEPES, and 0.05 fura-2 (Molecular Probes, Eugene, OR), pH 7.2, adjusted with KOH.
Apart from serving as a Ca2+ indicator, the fura-2
fluorescence was also used at the end of the experiment to confirm the
presynaptic origin of the recording. Whole-cell voltage-clamp
recordings from postsynaptic cells were made with an Axopatch-200A
amplifier. Pipettes had a resistance of 1.5-2 M and were filled
with the same solution as the pipettes used for presynaptic recordings,
except they contained 0.5 mM EGTA instead of 50 µM fura-2. Series resistance in postsynaptic recordings
(<15 M) was always compensated to 98% (lag, 10 µsec).
Whole-cell Ca2+ current recordings from terminals
were made with an Axopatch-200A amplifier (Axon Instruments) and
pipettes with a resistance of 4-6 M that contained the same
intracellular solution as used for current-clamp recordings except that
potassium was replaced by cesium. In addition, 1 µM
tetrodotoxin and 0.1 mM 3,4-diaminopyridine (Sigma, St.
Louis, MO) were added to the extracellular solution, and 20 mM NaCl was replaced with 20 mM tetraethylammonium chloride (Sigma) to block sodium and potassium channels (Borst et al., 1995). Series resistance (<35 M)
compensation was set at 90% with a lag of 10 µsec, and prediction
was set at 60%. Subtraction of the passive response was by the P/-5
method. Terminals with a capacitance of <35 pF were selected to avoid long axons (Borst and Sakmann, 1998). For the waveform command, we used
the presynaptic action potential displayed in Figure
2A of Borst et al., 1995, interpolated to 20 µsec
per point with a cubic spline. Potentials were corrected for a
liquid junction potential of  11 mV between the extracellular and the
pipette solution. Holding potential in voltage-clamp experiments was
80 mV. Potentials or currents were low-pass filtered at 2-5 kHz and digitized at 20-50 kHz with a 16-bit analog-to-digital converter (Instrutech, Great Neck, NY).
The optical recording system comprised an upright epifluorescence
microscope (Axioskop; Achroplan 40×, NA 0.75, Zeiss), equipped with a
polychromatic illumination system (TILL Photonics, Munich, Germany), a dichroic mirror (400 nm), a long-pass (415 nm) emission filter, and two photodiodes at the image plane for signal and background subtraction, respectively. Excitation light was coupled to
the microscope via a light guide. Fura-2 measurements of
Ca2+ concentration were made by forming ratios
between two continuous recordings (100-500 msec) of fluorescence
(after background subtraction) at two excitation wavelengths (357 and
380 nm) with an interval of ~10 msec (Grynkiewicz et al., 1985).
Calibration parameters were obtained from in vivo
calibrations as described in Helmchen et al. (1997). Fluorescence
signals recorded by the photodiode (Hamamatsu) were filtered at 30 Hz
(8-pole Bessel filter). Since the Ca2+ transient
evoked by an action potential decays with a time constant >400 msec in
the presence of 50 µM fura-2 (Helmchen et al., 1997), filtering this transient at 30 Hz did not affect the measurement of its
amplitude. Fura-2 was far from saturation during single action
potentials, because (1) the peak Ca2+ concentrations
evoked by single action potentials were usually less than the
Kd (273 nM) of fura-2 measured
in vivo (Helmchen et al., 1997), and (2) paired-pulse action
potential stimulation (interval: 50 msec) caused approximately the same
Ca2+ influx for each action potential (data not
shown). The large Ca2+ influx during a presynaptic
action potential (Borst and Sakmann, 1996) and the favorable
surface-to-volume ratio of the terminal permitted us to resolve
Ca2+ influx during single action potentials, and to
measure the relation between release and presynaptic
Ca2+ influx at the level of a single synapse.
For simultaneous presynaptic and postsynaptic recordings, only synapses
in which the postsynaptic cells discharged an action potential in
response to afferent stimulation were selected for recording (Borst et
al., 1995). Single afferent stimuli were applied via a bipolar
electrode (3-30 V, 100 µsec) placed at the midline of the trapezoid
body. Stimulation interval was 20-30 sec, which is sufficiently long
to avoid synaptic depression (Von Gersdorff et al., 1997).
The degree of reduction in the presynaptic Ca2+ influx and
release during application of a toxin was evaluated after its effect reached equilibrium. Data were expressed as mean ± SEM.
 -Agatoxin-IVA (Aga) was a gift from Dr. N. A. Saccomano,
Pfizer, Groton, CT; -conotoxin-GVIA (Ctx) was purchased from Bachem
(Bubendorf, Germany) and Research Biochemicals (Natick, MA); and
-conotoxin-MVIIC was from Research Biochemicals. The toxins were
applied in the presence of 0.1 mg/ml cytochrome C to block nonspecific
binding sites. Cytochrome C did not significantly affect the EPSC
(n = 16; p > 0.5), or
 [Ca2+] (n = 3; p > 0.5;
paired t test).
For the immunocytochemical studies, 10-d-old Wistar rats were
anesthetized with Nembutal and then intracardially perfused with 4%
paraformaldehyde in PB (0.1 M sodium phosphate, pH 7.4) containing 0.34% L-lysine and 0.05% sodium
m-periodate (McLean and Nakane, 1974). The brains were
removed immediately from the cranium, post-fixed for 2 hr, and then
cryoprotected by sinking in 10 (w/v) and 30% (w/v) sucrose in PB at
4°C for 72 hr. Coronal sections (40 µm) were cut on a sliding
microtome and processed for immunocytochemistry using the
avidin-biotin complex method.
Free-floating sections were processed for immunocytochemistry by
rinsing the tissue in 0.1 M Tris buffer (TB) for 15 min, 0.1 M Tris-buffered saline (TBS) for 15 min, blocking in
2% avidin in TBS for 30 min, rinsing in TBS for 30 min, blocking in
2% biotin in TBS for 30 min, and rinsing in TBS for 30 min. The tissue
was then incubated in affinity-purified anti-peptide antibody anti-CNA5 (against 1A subunit, diluted 1:15), anti-CNB2 (against
1B subunit, diluted 1:15), or anti-CNE2 (against
1E subunit, diluted 1:15) simultaneously with
anti-synaptotagmin (diluted 1:200) for 1 hr at room temperature
followed by 36 hr at 4°C. All antibodies were diluted in 0.1 M TBS containing 0.075% Triton X-100 and 1% normal goat
serum. The sections were rinsed for 1 hr in TBS and then incubated in a
solution containing biotinylated goat anti-rabbit IgG (for anti-CNA5,
anti-CNB2, or anti-CNE2 antibodies) diluted 1:300 and anti-mouse IgG
Texas Red (for anti-synaptotagmin antibody) diluted 1:200 for 1 hr at
37°C. Tissue sections were then rinsed in TBS for 1 hr and incubated
in avidin D-fluorescein (diluted 1:300) and anti-mouse IgG
Texas Red (diluted 1:200) for 1 hr at 37°C, rinsed in TBS for 10 min,
rinsed in TB for 20 min, mounted onto gelatin-coated slides, and then
coverslipped using Vectashield.
The immunofluorescent staining was viewed using a Bio-Rad
(Hercules, CA) MRC 600 microscope located in the imaging facility of the W. M. Keck Center for Research in Neural Signaling at the University of Washington. The thickness of optical sections was typically 1 µm. Tissue sections double-labeled for N-type and P/Q-type Ca2+ channels were treated the same as
above but were incubated in anti-CNB2 (made in goat; diluted 1:15) and
anti-CNA5 (made in rabbit; diluted 1:15), followed by incubation in
biotinylated anti-goat IgG (diluted 1:300) and anti-rabbit IgG labeled
with Texas Red (diluted 1:200). Sections were then incubated in avidin D-fluorescein (diluted 1:300) and anti-rabbit IgG labeled
with Texas Red (diluted 1:200) for 1 hr at 37°C. To determine the
level of nonspecific staining, some of the control sections were
incubated without one or both of the primary antibodies, or replaced by normal rabbit serum. All staining reported here was abolished in the
absence of primary antibody. The generation, purification, and
characterization of anti-CNA5, anti-CNB2, and anti-CNE2 have been
reported previously (Westenbroek et al., 1992; Yokoyama et al., 1995;
Sakurai et al., 1996). The anti-synaptotagmin antibody was a generous
gift of Dr. Masami Takahashi, Mitsubishi-Kasei Life Sciences Institute,
Toyko, Japan (Yoshida et al., 1992).
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RESULTS |
P/Q-type channels control release effectively
The presynaptic Ca2+ influx and the
corresponding EPSCs evoked by single action potentials were
simultaneously recorded at single calyx-type synapses. Application of
the P/Q-type Ca2+ channel blocker -agatoxin-IVA
(Aga, 15-200 nM) reduced both the amplitude of the
presynaptic Ca2+ influx
([Ca2+]) and the EPSC without significantly
affecting the presynaptic resting membrane potential, the shape of the
action potential, or the resting intracellular Ca2+
concentration (Fig. 1A,
B). This effect could not be reversed after >30 min of wash
out (data not shown). The relation between the EPSC and the
[Ca2+] was nonlinear (Fig. 1C) and
could be fit with relation (2), where m = 3.7 ± 0.2 (n = 5 pairs of presynaptic and postsynaptic recordings, Fig.
1D). The effect of Aga was dose-dependent. It reached
a plateau at 100 nM (Fig. 1E), at which
[Ca2+] was reduced to 44 ± 2% (n = 9) and the EPSC was reduced to 3 ± 1% (n = 4). At 30 nM, Aga reduced [Ca2+] to 71 ± 3% (n = 3; Fig. 1E) and the EPSC to 26 ± 5% (n = 6), yielding the value m = 3.9 (log(0.71)/log(0.26)). Similar values (3.3-4.2) of m were
obtained at concentrations of 60-200 nM (from data
summarized in Fig. 1E). These results suggest that
the value of m is independent of the concentration of Aga.
The Kd for the block by Aga was ~30
nM, because at this concentration Aga reached about
half-maximal block of the [Ca2+] (Fig.
1E).
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Figure 1.
Effect of Aga on presynaptic
[Ca2+] and EPSC. A, Aga (100 nM) reduced concurrently both the
[Ca2+] and the EPSC evoked by single
presynaptic action potentials. The values of
[Ca2+] and of the EPSCs are given relative to
their respective average values before application of the toxin.
B, Sample traces of the presynaptic
Ca2+ influx (left), the presynaptic
action potential (top right), and the EPSC
(bottom right) before (a) and
after (b, as indicated in A) Aga
application. The stimulus was given at time 0. Each trace was taken
from a single sweep (same for all the following figures).
C, D, EPSCs plotted against the
[Ca2+] from panel A on linear
(C) and double logarithmic
(D) scales. The slope of the linear regression
line in D was 3.5. E, Summary of the
dose-dependent effect of Aga on the [Ca2+] and
the EPSC (each value was obtained from three to nine cells).
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N-type channels control release less effectively
Addition of the N-type channel blocker -conotoxin-GVIA (Ctx)
reduced both the [Ca2+] and the EPSC
simultaneously (Fig.
2A). The membrane
potential, the action potential, and the resting intracellular
Ca2+ concentration in the terminal did not change
significantly (Fig. 2B). The relation between the
EPSC and the [Ca2+] could be fit with relation
(2) with m = 1.3 ± 0.1 (seven pairs of
presynaptic and postsynaptic recordings, Fig. 2C). The value of m obtained with application of Ctx was significantly
lower than that with application of Aga (p < 0.01; t test). At 1 µM, Ctx reduced the
[Ca2+] to 73 ± 2% (n = 11) and the
EPSC to 64 ± 2% (n = 10, Fig. 2D). The effect of
Ctx was saturated at 1 µM, since no additional block on
either the [Ca2+] (n = 3) or the EPSC
(n = 3) was observed at 3 µM (Fig.
2D).
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Figure 2.
Effect of Ctx on presynaptic
[Ca2+] and EPSC. A, Ctx (1 µM) reduced both the [Ca2+] and
the EPSC evoked by single presynaptic action potentials with a similar
time course. Amplitudes of both the [Ca2+] and
the EPSC were normalized to the values during the control period.
B, Sample traces of the presynaptic
Ca2+ influx (left), the presynaptic
action potential (top right), and the EPSC
(bottom right) before (a) and
after (b, as indicated in A) Ctx
application. The stimulus was given at time 0. C, EPSCs
plotted against the [Ca2+] from
A on double logarithmic scales. The slope of the linear
regression line was 1.3. D, Summary of the effect of Ctx
on the [Ca2+] and the EPSC. Each value was
obtained from 3-11 cells. The effects of Ctx at 1 and 3 µM were not significantly different
(p > 0.5; t test).
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We previously observed that combined application of saturating
concentrations of -conotoxin-MVIIC (8 µM), a blocker
of P/Q- and N-type channels (Hillyard et al., 1992; McDonough et al., 1996), Aga (100 nM), and Ctx (1 µM) reduces
the [Ca2+] to 26 ± 2% (n = 8) and
the EPSC to 0.9 ± 0.2% (n = 4; Wu et al., 1998). Similar
results were obtained when Aga and Ctx were applied together in the
absence of -conotoxin-MVIIC (Wu et al., 1998, see also Fig. 4). The
block of [Ca2+] by the combined toxin
application was similar to the sum of the block by applying either Aga
or Ctx alone, suggesting that Aga and Ctx block separate populations of
Ca2+ channels. The resistant
[Ca2+] is mediated via R-type channels, which
have m = 1.4 ± 0.1 (n = 4 synapses; Wu et
al., 1998). Reducing the extracellular Ca2+
concentration from 2 to 1 mM results in n = 2.7 ± 0.2 (n = 5 synapses; Wu et al., 1998). Table
1 shows the average percentages of the
[Ca2+] evoked by single action potentials from
three subtypes of Ca2+ channels and their values of
m. The sum of the three components was slightly >100%,
probably because of measurement error.
The difference in m is not caused by different
Ca2+ current kinetics
In the squid giant synapse, broadening presynaptic action
potentials increases EPSCs (Augustine et al., 1991). The relation between the EPSC and the presynaptic Ca2+ influx was
estimated to be approximately linear from this study, suggesting that
during an action potential Ca2+ channel domains do
not overlap at this synapse (Augustine et al., 1991). If one subtype of
Ca2+ channels opens much more briefly than others,
its Ca2+ domains are less likely to overlap. We
wondered whether the difference in the values of m at the
MNTB synapse could be caused by a difference in the time course of
Ca2+ currents. Presynaptic Ca2+
currents elicited by an action potential waveform command
(ICa(AP)) were recorded in the presence
of Na+ and K+ channel blockers
(Borst and Sakmann, 1996). Application of Ctx (1 µM)
reduced the amplitude of the ICa(AP) to 79 ± 1% (n = 6; Fig. 3A),
similar to its inhibitory effect on the [Ca2+]
(Fig. 2). This effect was not accompanied by a significant change in
the waveform of the current measured at half width
(p > 0.5; paired t test; n = 5;
Fig. 3B). Similarly, application of -conotoxin-MVIIC, a
blocker for N- and P/Q-type Ca2+ channels, revealed
no significant difference in the time course of the
ICa(AP) between the R-type and the total current
(Wu et al., 1998). These results suggest that the lower value of
m for N- and R-type channels is not caused by a difference
in the kinetics of the ICa(AP).
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Figure 3.
Presynaptic Ca2+ currents
elicited by an action potential waveform command
(ICa(AP)) before and after Ctx
application. A, Application of Ctx (1 µM)
reduced the ICa(AP). B,
Sample traces of the ICa(AP) before
(Ctrl) and after Ctx application, the latter of
which was also scaled (Ctx scaled) for comparison with
the Ctrl trace. C, The
I-V relation before
(Ctrl) and after Ctx application. The difference
between these two I-V curves yielded the
Ctx-sensitive I-V curve
(Diff), which activated at potentials more
positive than 30 mV. In contrast, the threshold for activation of
Ctx-insensitive currents (Ctx) was at approximately 40 mV.
D, Sample Ca2+ currents elicited by a
10 msec step pulse to 30 and 0 mV before (left) and after
(right) Ctx application. Note that currents elicited at
30 mV did not change significantly after Ctx application.
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In addition to studying the time course of the
ICa(AP), we also examined the currents
elicited by 10 msec depolarizing steps from a holding potential of 80
mV. The peak current-voltage (I-V) curves were obtained before and after Ctx application (n = 6; Fig.
3C,D). The difference between these two
I-V curves is the Ctx-sensitive N-type current,
which activated at potentials more positive than 30 mV (Fig.
3C,D), at least 10 mV more positive than the
other two subtypes of Ca2+ currents. Ctx (1 µM) inhibited the current elicited at 0 mV to 76 ± 3% (n = 6) of control. A similar block was observed at 10 to 30 mV. These results were similar to the effect of Ctx on
[Ca2+] or ICa(AP) (Figs.
2, 3).
Multiple subtypes of Ca2+ channels
control release at single release sites
Next, we investigated whether the difference in the value of
m could be accounted for by differential distribution of
Ca2+ channel subtypes at different release sites.
Because Aga blocked 97 ± 1% of the EPSC (Fig.
1E), we assumed that P/Q-type channels participate in
controlling release at all release sites. In a calyx, about half of the
Ca2+ influx is via P/Q-type channels, and the other
half is approximately equally divided between N- and R-type channels
(Table 1). We investigated three hypotheses that may account for the
lower values of m for N- and R-type channels (see
introductory remarks). First, N- and R-type channels may be associated
with different release sites. Second, N- and R-type channels may be
located at every release site, but they may be further from the
Ca2+ sensor than P/Q-type channels. Third, there may
be distant Ca2+ channels, which are located so far
away from release sites that they do not contribute to release during a
single action potential. The fraction of distant N- and R-type channels
may be larger than that of distant P/Q-type channels.
If N- and R-type channels do not control release at the same release
site, the Ca2+ influx at each release site should be
contributed about half by P/Q-type channels and half by either N- or
R-type channels. This arrangement of Ca2+ channels
would result in a lower value of m for N- and R-type channels (Reid et al., 1998; see also for details). It predicts that when P/Q-type channels are completely blocked, blocking N-type channels will reduce release by  50%, because only half of
release sites are associated with N-type channels. In the presence of
Aga (100 nM) to completely block P/Q-type channels,
application of Ctx (1 µM) reduced the
[Ca2+] by 52 ± 2% (n = 5) of the
value immediately before Ctx application (Fig.
4), as expected from Table 1.
However, Ctx reduced the EPSC by 78 ± 4% (n = 4) of the
value immediately before Ctx application, which is clearly higher than
the predicted 50%. Thus, the hypothesis that N- and R-type channels
are associated with different release sites is not supported. N-type
channels are present in at least 78% of release sites. These results
suggest that transmitter release at most release sites is controlled by
three subtypes of Ca2+ channels, P/Q-, N-, and
R-type. As an approximation, we assumed that all three subtypes of
channels control release at every release site.
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Figure 4.
Effect of Ctx on [Ca2+]
and EPSC in the presence of Aga. A, An experiment
showing that Ctx (1 µM) reduced both the
[Ca2+] and the EPSC in the presence of Aga (100 nM). In the bottom panel, the EPSC is
plotted on a different scale. If the maximum amplitude of the
postsynaptic current was less than twice the SD of the baseline noise,
the response was classified as a failure. B, In the
presence of Aga (100 nM), the block (%) of the
[Ca2+] and of the EPSC by Ctx (1 µM) were significantly different
(p < 0.01; paired t test).
The percentages were normalized to the values immediately before Ctx
application.
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EGTA does not preferentially block release mediated by
N-type Ca2+ channels
If N- and R-type channels near release sites were located further
from the Ca2+ sensor than P/Q-type channels, the
Ca2+ entering via N- or R-type channels is less
likely to bind to the Ca2+ sensor than that entering
the terminal via P/Q-type channels. This will result in a lower value
of m for N- and R-type channels. One prediction of this
hypothesis is that the Ca2+ entering via N- or
R-type channels will diffuse across a longer distance to reach the
Ca2+ sensor, and thus will be more likely to be
bound by an exogenous Ca2+ buffer. We tested whether
release controlled by the Ca2+ influx through N-type
channels is more susceptible to the block by a high concentration of
the slow Ca2+ buffer EGTA. EPSCs were recorded while
a pipette containing 10 mM EGTA was sealed to the
corresponding terminal in the cell-attached configuration. After
obtaining a baseline value for the EPSC amplitude, the whole-cell
configuration was established in the presynaptic recording. The EPSC
decreased to a new steady-state level in ~3 min (Fig.
5A), probably reflecting
diffusion of EGTA from the presynaptic pipette into the terminal (Borst
and Sakmann, 1996). Application of Ctx (1 µM) further
reduced the EPSC by 38 ± 5% (n = 5) of the value at the new
steady-state level (Fig. 5A). Ctx blocked a similar fraction
of the EPSC in the presence or absence of EGTA (Fig. 5B).
These results suggest that calcium ions that reach the
Ca2+ sensor diffuse approximately the same distance,
irrespective of the subtype of channels through which they enter.
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Figure 5.
Effect of Ctx on EPSC after EGTA was dialyzed into
the terminal. A, While the EPSC was recorded, a
cell-attached recording was made on the presynaptic terminal with a
pipette containing 10 mM EGTA. A suction pulse
(arrow) was applied to establish the whole-cell
configuration, allowing EGTA to diffuse from the pipette into the
terminal. The EPSC decreased rapidly and reached a new baseline value.
Ctx (1 µM) was then applied to the bath, which further
decreased the EPSC. B, Comparison of the block of the
EPSC by Ctx (1 µM) in the control (Ctrl;
n = 10) and after EGTA (n = 5) was dialyzed into the
presynaptic terminal. In both cases, the block was normalized to the
value immediately before Ctx application.
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|
Double labeling with antibodies to Ca2+
channels and synaptotagmin
If a larger fraction of N- and R-type channels than P/Q-type
channels were located far from release sites, from which
Ca2+ entering will be less likely to bind to the
Ca2+ sensor that triggers release, the value of
m for N- or R-type will be lower than that for P/Q-type
channels. To address this hypothesis, we examined the distribution of
Ca2+ channels in the terminal by double labeling
with antibodies to Ca2+ channels (Westenbroek et
al., 1992, 1995; Yokoyama et al., 1995) and to synaptotagmin, a
synaptic vesicle protein (Brose et al., 1992). Confocal microscopic
examination of tissue sections labeled with monoclonal antibodies
against synaptotagmin (Yoshida et al., 1992) revealed staining that was
restricted to the presynaptic calyx terminal enveloping the cell body
of MNTB neurons (Fig. 6B). In contrast,
immunostaining for the 1A subunit of P/Q-type Ca2+ channels (Westenbroek et al., 1995) was
localized in punctate clusters in the release face of the calyx-type
synapse along the surface of the cell, as well as scattered throughout
the postsynaptic cell body (Fig. 6A). Staining in the
soma presumably represents newly synthesized P/Q-type channels in the
endoplasmic reticulum and Golgi complex, which were more prominent in
these neurons in young rats than we previously observed in adults
(Westenbroek et al., 1995). Merged images showed that staining for
1A was colocalized with staining for synaptotagmin at
sites along the release face of the calyx (Fig. 6C,
yellow-orange regions). Although some punctate staining of
1A appeared to be in the cytosol of the terminal in a
single optical section (about 1 µm), inspection of adjacent sections
suggested that it originated from the irregularly shaped release face
as well. This staining was carried out using anti-CNA5 antibodies,
which recognize the rbA isoform of 1A (Starr et al.,
1991; Sakurai et al., 1996). A similar pattern of staining was observed
with the anti-CNA6 antibodies against the BI isoform (Mori et
al., 1991; Sakurai et al., 1996). Altogether, these results show that
many areas of the calyx synapse that were labeled for synaptotagmin
were also labeled for both isoforms of the 1A subunits of P/Q-type Ca2+ channels.
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Figure 6.
Distribution of the 1 subunit of
classes A, B, and E Ca2+ channels in synapses in the
MNTB. A, B, Tissue section
double-labeled using antibodies to the 1 subunit of
class A Ca2+ channels (A,
arrows) and anti-synaptotagmin
(B), illustrating their distribution in the
synapse surrounding neurons located in the MNTB. C,
Merged image of A and B illustrating
regions of colocalization (yellow;
arrowheads) between the 1 subunit of
class A Ca2+ channels (green)
and synaptotagmin (red), demonstrating the presence of
these channels at the release face of the synapse.
D, E, Tissue section
double-labeled using antibodies to the 1 subunit of
class B Ca2+ channels (D,
arrows) and anti-synaptotagmin
(E), illustrating their distribution in the
synapse surrounding MNTB neurons. F, Merged image of the
staining observed in D and E,
illustrating few regions of colocalization
(yellow, arrowheads) between class
B Ca2+ channels and synaptotagmin in the synapse and
the presence of class B Ca2+ channels in other
regions of the synapse. G, H, Tissue
section double-labeled with antibodies to the 1 subunit
of class E Ca2+ channels (G,
arrows) and anti-synaptotagmin antibodies
(H), illustrating the presence of
synaptotagmin at the release face of the synapse and the distribution
of class E channels at other sites in the synapse. I,
Merged image of the staining shown in G and
H, illustrating very few sites of colocalization
(yellow) of these two proteins.
Arrows illustrate sites of class E
Ca2+ channels outside the release face of the
synapse. Scale bars: A-F, 10 µm;
G-I, 5 µm.
|
|
Examination of tissue sections labeled with antibodies to
1B subunit of N-type Ca2+ channels
revealed staining of this channel along both the release face and the
nonrelease face of the calyx, as well as substantial intracellular
staining in the cell body of postsynaptic neurons (Fig.
6D). N-type Ca2+ channel staining
of the calyx was often adjacent to or surrounding the staining observed
with anti-synaptotagmin antibodies rather than superimposed on it (Fig.
6, compare D, E). Merged images showed areas of
superimposition of staining for synaptotagmin and N-type
Ca2+ channels (Fig. 6F,
yellow-orange staining), but many areas of synaptotagmin
staining did not have colocalized N-type Ca2+
channels (Fig. 6F, red staining),
and many areas of staining for N-type Ca2+ channels
were not stained for synaptotagmin (Fig. 6F,
bright green staining). Immunostaining for
N-type Ca2+ channels was also present along the
outer surface of the calyx and appeared to extend along the surface
membrane of calyx to areas adjacent to the axon, where no synaptotagmin
staining was observed (data not shown).
Antibodies against the 1E subunits of R-type
Ca2+ channels were mostly not colocalized with
synaptotagmin antibodies (Fig. 6, compare G,
H). Merged images show few areas of superimposition of staining for 1E and synaptotagmin (Fig.
6I). These R-type channels appeared present primarily
along the outer surface of the calyx and only rarely on the inner
surface that surrounds the neurons and contains the sites of
neurotransmitter release. Staining for 1E also extended
to areas adjacent to the axon where no staining for synaptotagmin was observed.
Double-labeling studies using antibodies to N-type and P/Q-type
Ca2+ channels revealed distinct distributions of
these channels. P/Q-type Ca2+ channels are located
in punctate clusters in the calyx membrane (Fig.
7B), whereas N-type channels
are more diffusely distributed throughout the calyx (Fig.
7A). Merging these images shows that N-type
Ca2+ channels often are colocalized with P/Q-type
channels (Fig. 7C, yellow-orange staining) but
also are often located elsewhere in the calyx (Fig. 7C,
green staining). The double-labeled images are
consistent with the conclusion that N-type Ca2+
channels are colocalized with P/Q-type Ca2+ channels
in release sites, but are also localized elsewhere in the calyx
terminals.
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Figure 7.
Double labeling of class A and class B
Ca2+ channels in the MNTB.
A, B, Double labeling of a
tissue section from the MNTB using antibodies to the class B
(A, arrows) and class A
(B, arrows) 1 subunits of
Ca2+ channels. C, Merged image of
staining shown in A and B to illustrate
regions of only class B staining (green), or
regions of only class A staining (red) and regions of
colocalization (yellow,
arrowheads) of these two channels in the synapses and
neurons located in the MNTB. Scale bar:
A-C, 10 µm.
|
|
| |
DISCUSSION |
We have demonstrated that three classes of Ca2+
channels, R- (Wu et al., 1998), P/Q-, and N-type control transmitter
release at single release sites in single calyx-type terminals in the rat MNTB. The value of m for P/Q-type channels was higher
than for N- and R-type channels, meaning that P/Q-type channels trigger release more effectively than N- and R-type. This difference was not
caused by a difference in their kinetic properties or by a greater
diffusional distance between the N-type or R-type
Ca2+ channels that contributed to transmitter
release and the Ca2+ sensor that triggered release.
Double immunocytochemical labeling showed that P/Q-type
Ca2+ channels containing 1A subunits
were colocalized mostly with synaptic vesicle clusters, whereas N-type
channels containing 1B and R-type channels containing
1E were only partly colocalized with vesicle clusters.
These results suggest that the subcellular distribution of
Ca2+ channels within a terminal is one of the
factors that determines their effectiveness in triggering release. As
summarized in Figure 8, our results are
best explained by assuming that a larger fraction of N- and R-type
channels are localized distant from release sites. However, within a
release site, all three subtypes of channels are localized at a similar
distance from the Ca2+ sensor.
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Figure 8.
A schematic view of the distribution of
Ca2+ channels in the calyx of Held (not drawn to
scale). Within a release site, three subtypes of channels, P/Q-, N-,
and R-type channels are equally close to the docked vesicle. The local
Ca2+ domains created by the opening of channels
overlap within the release site. Some Ca2+ channels,
labeled as "distant Ca2+ channel", are located
so far from this or other release sites that their
Ca2+ domains do not contribute to release. A larger
fraction of N- and R-type than P/Q-type channels are distant
Ca2+ channels.
|
|
Multiple subtypes of Ca2+ channels in
the calyx of Held
Takahashi et al. (1996) reported that the majority (96%) of the
presynaptic Ca2+ current at the rat MNTB synapse is
Aga-sensitive P/Q-type and that Ctx has no effect on the presynaptic
Ca2+ current. This is not consistent with our
results (Table 1). The rats used by Takahashi et al. (1996) were 8- to
18-d-old, whereas we used 8- to 10-d-old rats. A developmental change
of presynaptic Ca2+ channel subtypes in the MNTB
(Iwasaki and Takahashi, 1998) might partly account for this
discrepancy, although in contrast to our results, Iwasaki and Takahashi
(1998) did not observe a contribution of N-type Ca2+
channels to synaptic transmission in 10-d-old rats. Several lines of
evidence support that three subtypes rather than a single subtype of
Ca2+ channels are present in 8- to 10-d-old rats.
Aga blocked slightly more than half of the total presynaptic
Ca2+ current at 100 nM. Ctx blocked
about a quarter of the presynaptic Ca2+ current and
~35% of the EPSC at saturating concentrations. Ctx from two sources
(Bachem and Research Biochemicals) was used, and no significant
difference was noticed. The threshold for activation of the
Ctx-sensitive current was at least 10 mV more positive than that of the
Ctx-insensitive current, indicating that the biophysical properties of
the N-type current are different from the Ctx-insensitive current. In
addition, the N- and P/Q-type channel blocker -conotoxin-MVIIC
reaches its maximal effect at 8 µM by blocking about
three quarters of the Ca2+ current (Wu et al.,
1998), similar to the summed effect of coapplication of Aga and Ctx
(Table 1). Coapplication of -conotoxin-MVIIC, Aga, and Ctx at
saturating concentrations causes a similar effect as applying only
-conotoxin-MVIIC (Wu et al., 1998). The
-conotoxin-MVIIC-sensitive current showed a slowly activating
component when activated at 30 to 20 mV, whereas
-conotoxin-MVIIC-insensitive R-type current does not have this
component (Wu et al., 1998). This result suggests that the R-type
current is kinetically different from other subtypes of currents.
Furthermore, immunostaining showed that 1A subunits of
P/Q-type, 1B subunits of N-type, and 1E
subunits of R-type Ca2+ channels are mostly or
partly localized at the presynaptic release sites. Taken together, the
pharmacological evidence shows the presence of three subtypes of
Ca2+ channels in a single terminal, which differ in
their threshold of activation, current kinetics, and the composition of
their 1 subunits.
In neuronal somata, the percentages of different
Ca2+ currents evoked by a depolarizing voltage step
may be different from that evoked by an action potential (McCobb and
Beam, 1991; Scroggs and Fox, 1992). Whether this is also the case in
synaptic terminals had previously not been examined. Ctx and
-conotoxin-MVIIC (Wu et al., 1998) reduced the
Ca2+ influx by an action potential to a similar
degree as the current evoked by a depolarizing voltage step. These
results suggest that none of the three subtypes of
Ca2+ channels is preferentially activated by action potentials.
Different effectiveness of Ca2+
channel subtypes
If release rates are close to maximal, the relation between
Ca2+ influx and release becomes less steep. Blocking
a small fraction of Ca2+ channels would then cause a
relatively small effect on release and thus cause an apparently smaller
effectiveness of Ca2+ channels in controlling
release (Turner et al., 1993; Wheeler et al., 1996). Could the low
value of m for the N-type or the R-type
Ca2+ channels observed in our experiments be caused
by saturation of the release process? Because Aga, at 30 nM, gave a similar reduction in
[Ca2+], but a much larger reduction in the EPSC
than 1 µM Ctx, this possibility is unlikely. When
extracellular Ca2+ concentration was reduced from 2 to 1 mM, a large effect on the release was also observed
(Wu et al., 1998), again suggesting that at physiological extracellular
Ca2+ concentrations, release rates are submaximal.
The value of m for P/Q- and N-type channels has also been
measured for populations of other synapses (Wu and Saggau, 1994; Mintz
et al., 1995; Qian et al., 1997). The value of m is slightly lower for the N-type (m = 3.5) than for the P/Q-type
channels (m = 4.1-4.2) in guinea pig and rat
hippocampal synapses (Wu and Saggau, 1994; Qian et al., 1997). This
difference is more pronounced (m = 2.5 for the N-type
and 4.0 for the P-type) at cerebellar parallel fiber synapses (Mintz et
al., 1995). At MNTB synapse the largest difference is in the values of
m for P/Q- and N-type channels (Table 1). Consistent with
results in cerebellar and hippocampal synapses, the m for
the P/Q-type channels is also the highest in the MNTB synapse and it
seems possible that the high m value observed by Mintz et
al. (1995) for the P/Q-type channels is related to the presence of
toxin-resistant channels with a relatively low effectiveness in the
parallel fiber terminals, similar to the situation in the MNTB.
Ca2+ domains caused by the opening of three subtypes
of channels are likely to overlap at single release sites at MNTB
synapses, consistent with our earlier results (Borst and Sakmann, 1996, 1998, 1999) and with results obtained in hippocampal (Wu and Saggau, 1994) and cerebellar (Mintz et al., 1995) synapses. At the MNTB synapse
at least three Ca2+ channels, each of a different
subtype, can contribute to release of a vesicle in the calyx. Although
probably >60 Ca2+ channels open for each vesicle
that is released during an action potential (Borst and Sakmann, 1996),
a significant fraction of N- and R-type Ca2+
channels may be distant channels that do not contribute to release evoked by a single action potential.
Different localization of Ca2+
channel subtypes
Double labeling with antibodies to different
Ca2+ channel subtypes and to the vesicle protein
synaptotagmin provided a direct comparison of localization of
Ca2+ channel subtypes and release sites at a nerve
terminal. The 1A subunits of P/Q-type
Ca2+ channels are highly effective in triggering
release and are colocalized in clusters with synaptotagmin, apparently
at the release face of the calyx, whereas the 1B
subunits of N-type and 1E subunits of R-type
Ca2+ channels are partly or mostly not colocalized
at release sites and P/Q-type channels. The correlation between the
effectiveness in triggering release and colocalization with
synaptotagmin suggests that Ca2+ channel
localization can determine its effectiveness in triggering release.
Given a similar low value of m for N- and R-type channels
(Table 1), why does it appear that a larger fraction of
1E subunits of R-type than 1B subunits of
N-type Ca2+ channels are not located at release
sites? The m value for R-type Ca2+
channels was measured using the blocker Ni2+, which
reduced presynaptic Ca2+ influx primarily, but not
exclusively, by blocking R-type Ca2+ currents (Wu et
al., 1998). Thus, the m value measured this way could have
been an overestimate. Alternatively, there may be two subtypes of
R-type channels (Tottene et al., 1996; Wu et al., 1998), one of which
is not recognized by the antibody against the 1E subunit
and is located at the release site.
One mechanism contributing to localization of Ca2+
channels at release sites is thought to be binding of the synaptic
protein interaction (synprint) site on N- and P/Q-type
Ca2+ channels to SNARE proteins (Sheng et
al., 1994; Rettig et al., 1996). Disruption of this interaction reduces
the effectiveness of Ca2+ entry through N-type
channels in triggering transmitter release at cholinergic synapses
between pairs of cultured sympathetic ganglion neurons and between
cultured motor neurons and muscle cells (Mochida et al., 1996; Rettig
et al., 1997). The different localization of Ca2+
channels observed here could reflect competition among
Ca2+ channel subtypes for localization at release
sites, with P/Q-type channels having a higher affinity than N-type or
R-type channels for the SNARE complex in the calyx.
Contribution of channel subtypes to
transmitter release
This particular arrangement of Ca2+ channel
subtypes at terminals may have an important functional impact on
various aspects of synaptic transmission. For example, distant
Ca2+ channels located far from release sites may
contribute little to the local increase in Ca2+
concentration that triggers transmitter release (Fig. 8), but may
contribute to the residual Ca2+ concentration
following an action potential which influences different forms of
short-term synaptic plasticity such as paired-pulse facilitation and
post-tetanic potentiation (Zucker, 1996). Several neurotransmitters and
neuromodulators inhibit transmitter release by modulation of
presynaptic Ca2+ channels (Wu and Saggau, 1997).
Modulation of the highly effective Ca2+ channel
subtypes will have a larger effect on transmitter release, whereas
modulation of the less effective channel subtypes will cause a smaller
change of transmitter release. Modulation of distant Ca2+ channels will only affect release during
high-frequency signaling.
| |
FOOTNOTES |
Received Aug. 19, 1998; revised Oct. 28, 1998; accepted Oct. 29, 1998.
L.G.W. was supported by the Alexander von Humboldt Foundation and Human
Frontier Science Program. J.G.G.B. was supported by a Training and
Mobility of Researchers fellowship. R.E.W. and W.A.C. were supported by
National Institutes of Health Grant NS22625. We thank Drs. Erwin Neher
and Bernard Katz for helpful comments on this manuscript.
Correspondence should be addressed to Dr. Ling-Gang Wu, Abteilung
Zellphysiologie, Max-Planck-Institut für medizinische Forschung, Jahnstrasse 29, D-69120 Heidelberg, Germany.
| |
APPENDIX |
Nonuniform distribution of different subtypes of
Ca2+ channels at different release sites leads to a
lower value of m
Lowering the extracellular Ca2+ concentration
decreases the driving force for the Ca2+ influx
through every Ca2+ channel, although there might be
minor differences between Ca2+ channel subtypes in
their affinity for extracellular Ca2+. The
n (= 2.7 ± 0.2; 5 synapses) measured this way (Wu et
al., 1998) is likely to reflect the cooperativity of
Ca2+ in triggering release (Augustine et al., 1991;
Mintz et al., 1995). Thus, we regarded the value of n in
each release site as 2.7 (Table 1). Since Aga blocked 97 ± 1% of
the EPSC, we assumed that P/Q-type channels contributed to release at
all release sites. Table 1 shows the percentage of the presynaptic
Ca2+ influx contributed by each subtype of channels.
By scaling the measured percentages down by 8%, the sum of three
components (mean only) is exactly 100%, which simplified the
calculations below. After scaling, P/Q-type channels contributed
~50% of the total Ca2+ influx, whereas N- and
R-type each contributed ~25%. Thus, 50% of the
Ca2+ influx at each release site is contributed by
P/Q-type channels. N- and R-type channels share their targeted release
sites with P/Q-type channels.
If N- and R-type channels are separated in every release site, P-
and N-type channels control release in 50% of release sites, whereas
P- and R-type channels control release in the other 50% of
release sites. When N-type channels (~25% of total channels, Table
1) are blocked, at 50% of release sites Ca2+ will
enter exclusively via P/Q-type channels, and the remaining 50% of
release sites will be unaffected. The remaining fraction of release
(Releasenormalized) after the block of N-type channels is:
Releasenormalized = 50%*(0.52.7) + 50%*(12.7) = 58%. The apparent power can be
measured from relation (2), 58% = (1 0.25)m,
m = 1.9, close to the measured value (m = 1.3 ± 0.1). Similar calculations were made for R-type channels,
yielding similar results. This view could account at least partly for
the lower values of m (see also Reid et al., 1998).
| |
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Top
Abstract
Introduction
