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The Journal of Neuroscience, December 1, 1998, 18(23):9954-9961
Nerve Terminal Currents Induced by Autoreception of
Acetylcholine Release
Wen-Mei
Fu,
Houng-Chi
Liou, and
Yu-Hwa
Chen
Pharmacological Institute, College of Medicine, National Taiwan
University, Taipei, Taiwan 100
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ABSTRACT |
The activation of autoreceptors is known to be important in the
modulation of presynaptic transmitter secretion in peripheral and
central neurons. Using whole-cell recordings made from the free growth
cone of myocyte-contact motoneurons of Xenopus cell cultures, we have observed spontaneous nerve terminal currents (NTCs).
These spontaneous NTCs are blocked by d-tubocurarine (d-TC) and
 -bungarotoxin (-BuTx), indicating that endogenously released acetylcholine (ACh) can produce substantial membrane depolarization in
the nerve terminals. Local application of NMDA to the growth cone increased the frequency of spontaneous NTCs. When the electrical stimulations were applied at the soma to initiate evoked-release of
ACh, evoked ACh-induced potentials were recorded in the nerve terminals, which were inhibited by d-TC and hexamethonium but not by
atropine. Replacement of normal Ringer's solution with high-Mg2+, low-Ca2+ solution also
reversibly inhibited evoked ACh-induced potentials. The possible
regulatory role of presynaptic nicotinic autoreceptors on the synaptic
transmission was also examined. When the innervated myocyte was
whole-cell voltage-clamped to record synaptic currents, application of
hexamethonium inhibited the amplitude of evoked synaptic currents at a
higher degree than that of iontophoretic ACh-induced currents.
Furthermore, hexamethonium markedly reduced the frequency of
spontaneous synaptic currents at high-activity synapses. Pretreatment
of neurons with -BuTx also inhibited the evoked synaptic currents in
manipulated synapses. These results suggest that ACh released
spontaneously or by electrical stimulation may act on the presynaptic
nicotinic autoreceptors of the same nerve terminals to produce membrane
potential change and to regulate synaptic transmission.
Key words:
autoreceptor; neuronal nicotinic receptor; Xenopus
laevis; nerve terminal currents; synaptic transmission; acetylcholine
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INTRODUCTION |
The activation of autoreceptors is
known to be important in the modulation of presynaptic transmitter
secretion in the peripheral nervous system and CNS.
Presynaptic inhibitory 5-HT1 autoreceptors have been
identified in virtually all parts of the CNS (Gothert et al., 1996 ).
Dopaminergic, noradrenergic, and glutamatergic neurons are also
inhibited by the activation of presynaptic D2-like, 2, and metabotropic glutamate autoreceptors,
respectively (Boehm and Huck, 1996; Macek et al., 1996; Cragg and
Greenfield, 1997). The activation of GABAB autoreceptors is
indeed capable of reducing GABA release (Misgeld et al., 1995).
Nicotinic receptors are widely distributed in the mammalian CNS and
have been implicated in various physiological and pathological conditions, including cognition, Alzheimer's disease, Parkinson's disease, anxiety, and addiction to tobacco products (Nordberg et al.,
1989; Arneric et al., 1995). Nicotinic receptors are localized on both
presynaptic axon terminals and postsynaptic somatodendritic sites
(Clarke, 1993; Sargent, 1993). Most of the functions of postsynaptic
receptors involved in cholinergic mediation in the CNS have not been
well established. However, the positive modulation of neurotransmitter
release appears to be a widespread and potentially important role of
presynaptic nicotinic ACh receptor channels (nAChRs) (McGehee
and Role, 1995; McGehee et al., 1995). Presynaptic nAChRs are known to
positively modulate the release of various neurotransmitters, including
glutamate, norepinephrine, 5-hydroxytryptamine, dopamine, and
GABA (Wonnacott et al., 1989; Levin, 1992; Wessler, 1992; Guo et al.,
1998; Li et al., 1998). As for ACh release, although an abundant
literature describes the inhibitory presynaptic autoreceptors of the
muscarinic type (Starke et al., 1989), nicotinic autoreceptors have
been proposed also to regulate ACh release at motor nerve terminals
(Bowman et al., 1988) and in central cortical and hippocampal
synaptosomes (Rowell and Winkler, 1984; Araujo et al., 1988; Wilkie et
al., 1996). Nicotinic autoreceptors may constitute a potential
therapeutic target for enhancing cholinergic transmission in the
earlier stages of diseases, such as Alzheimer's disease. The concept
of ionotropic autoreceptors is established primarily by indirect
evidence measuring the overflow of radioisotope-labeled transmitter or
whole-cell recording of EPSC amplitude at postsynaptic cells.
Recently, direct recording of nicotinic responses in presynaptic nerve
terminals has been made in ciliary ganglia (Coggan et al., 1997).
Furthermore, measurements of intracellular Ca2+ in
single mossy fiber presynaptic terminals indicate that nAChRs containing the 7 subunit can mediate a Ca2+
influx that is sufficient to induce vesicular neurotransmitter release
(Gray et al., 1996). Here, we made whole-cell recordings from the nerve
growth cone and observed spontaneous nerve terminal currents (NTCs),
indicating that the activation of ionotropic autoreceptors by
endogenously released ACh can produce the change in membrane potential.
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MATERIALS AND METHODS |
Cell culture. Culture procedures have been described
previously (Tabti and Poo, 1991). Briefly, neural tubes and the
associated myotomal tissue were taken from stage 20-22
Xenopus embryos (Nieuwkoop and Faber, 1967) and allowed to
dissociate in Ca2+- and Mg2+-free
Ringer's solution supplemented with EDTA. The dissociated cells were
plated on clean coverslips and used for experiments after incubation in
culture medium for 1 d at room temperature (20-22°C). The
culture medium consisted of 50% (v/v) Ringer's solution (115 mM NaCl, 2 mM CaCl2, 1.5 mM KCl, and 10 mM HEPES, pH 7.6), 49% L-15
Leibovitz medium (Sigma, St. Louis, MO), 1% fetal bovine serum (Life
Technologies, Gaithersburg, MD), and antibiotics (100 U/ml penicillin
and 100 µg/ml streptomycin).
Electrophysiology. Whole-cell patch-clamp recording methods
followed those described previously (Hamill et al., 1981). NTCs were
recorded from growth cone by whole-cell recording [holding potential
(Vh) =  60 mV] in Ringer's solution by
using 1-d-old cell cultures at room temperature. Patch pipettes were
pulled with a two-stage electrode puller (pp-83; Narishige, Tokyo,
Japan), and the tips were polished immediately before the experiment
with use of a microforge (MF-83; Narishige). The solution inside the recording pipette contained 150 mM K gluconate, 1 mM NaCl, 1 mM MgCl2, and 10 mM HEPES, pH 7.2, and 1 mM amphotericin B was
added to internal solution to get a perforated patch. The membrane
currents were monitored by a patch-clamp amplifier (Axopatch 200A, Axon Instruments, Foster City, CA) and chart recordings from an
oscillographic recorder (Gould RS 3200, Valley View, OH). Data were
stored on a videotape recorder for later playback onto a storage
oscilloscope (5113; Tektronix) and for analysis by a microcomputer.
Spontaneous synaptic currents (SSCs) were monitored from innervated
myocyte by whole-cell voltage-clamp recordings (Vh = 60
mV) in Ringer's solution. The solution inside the recording pipette
contained 150 mM KCl, 1 mM NaCl, 1 mM MgCl2, and 10 mM HEPES,
pH 7.2. Evoked synaptic currents (ESCs) were elicited by stimulating
presynaptic neurons at the soma with a heat-polished glass
microelectrode (2-3 µm tip opening). The pipette was filled with
Ringer's solution. For suprathreshold stimulation of the neuron, a
square current pulse of 0.1 msec duration and 0.2-2 µA amplitude was
applied through the pipette. Such currents generally induced twitch
contraction of the muscle cell when applied to the soma of the
innervating neuron. For iontophoretic mapping of ACh sensitivity,
conventional micropipettes were made and filled with 3 M
ACh. The resistance of the ACh pipette was 100-200 M and required
2-6 nA of braking current. Mean amplitude of the membrane currents
induced by identical pulses of ACh (2 msec duration) applied at the
myocyte surface was used to assay ACh sensitivity. The mean SSC
amplitude of manipulated synapses was obtained from 50-300 SSC events
per neuron. The results were expressed as mean ± SE
(n) (n, cell number). The statistical significance was evaluated by Student's t test.
Cell manipulation experiment. In these cultures, motoneurons
either form a natural synapse resulting from a random encounter of
muscle cells by growing neurites or stay alone (myocyte-free, "naive
neuron"). Isolated spherical myocytes (myoballs) were used in the
experiment of manipulated contacts (Chow and Poo, 1985). Myoballs were
first loosened from the attachment to the glass substratum by
"rolling" the cell across the substratum surface with a
heat-polished tight-seal micropipette. The loosening of attachment
allowed the myocyte to be lifted up from the substratum and then
translocated to contact with the growth cone to form a manipulated
synapse. The SSC recordings were made as soon as the manipulated cells
contacted with "naive" nerve terminals, and evoked stimulation at
the soma was elicited a few minutes later.
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RESULTS |
Nerve terminal currents induced by autoreception of spontaneous
ACh release
Experiments were performed in 1-d-old Xenopus
nerve-muscle cocultures. In these cultures, some of the motoneurons
readily formed functional synapses with myocytes after a random
encounter of the myocyte by the growing neurites. The axons of some of
these neurons continued growing forward (Fig.
1, bottom right
corner), and these neurons were chosen to do the following
experiments. Whole-cell voltage-clamp recording was made on the free
growth cones of these myocyte-contact neurons. We observed inward
pulsatile spontaneous NTCs that resemble SSCs recorded from the
postsynaptic myocyte (Fig. 1a). As shown below, these NTCs
appear to be induced by quantal secretion of ACh from the nerve
terminal and the subsequent activation of the surface nAChRs of
the same nerve terminal. The average NTC frequency was 0.5 ± 0.1 Hz (n = 11), and the mean amplitude of NTCs was
16.9 ± 7.3 pA, which is much smaller than that of SSCs in these
1-d-old cultures (96.5 ± 5.3 pA; n = 22). When
the same recording was made from naive neurons that had not made any
contact with the cocultured myocytes, NTCs appeared only in 2 of 15 cases (at a frequency of 0.3 and 0.05 Hz, respectively), suggesting the
inductive role of myocytes in the spontaneous neurotransmitter secretory properties of these spinal neurons. All experiments about
spontaneous NTCs described below were thus performed on myocyte-contact
neurons.
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Figure 1.
Spontaneous nerve terminal currents induced by the
quantal release of ACh from the same nerve growth cone in 1-d-old
Xenopus cultures. Phase-contrast micrograph in the
bottom right corner shows the myocyte-contact neuron and
the arrangement of the patch pipette for the whole-cell recording of
nerve growth cone. Scale bar, 20 µm. N, Neuron;
M, myocyte; P, patch pipette.
a, Continuous trace depicts the membrane
currents recorded from the nerve growth cone before and after local
application of nicotine. Downward deflections are spontaneous NTCs
(Vh = 60 mV, filtered at 150 Hz). Local perfusion with
nicotine induced an inward current and reduced the frequency of NTCs.
Samples of NTCs before and after nicotine treatment are shown
below at higher time resolution (filtered at 10 kHz).
b, Application of d-TC inhibited the frequency of NTCs.
Pretreatment of culture with d-TC (c) or -BuTx
(d) inhibited the appearance of NTCs and
completely antagonized the nicotine-induced inward current.
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nAChRs are found in a variety of vertebrate peripheral nervous system
and CNS. These receptors can be divided into two distinct classes based
on -BuTx sensitivity. The majority of -BuTx-sensitive nAChRs
containing 7 and/or 8 subunits (Schoepfer et al., 1990; Sargent,
1993) have a relatively high permeability to Ca2+
and exert profound desensitization (Vijayaraghavan et al., 1992; McGehee et al., 1995). As shown in Figure 1a, local
application of nicotine with another glass micropipette (1 µm pipette
opening, intrapipette concentration at 10 µM) induced an
inward current in the nerve terminal and a reduction of NTC frequency,
which probably resulted from the desensitization of nAChRs. Application of 40 µM d-TC inhibited the frequency of NTCs,
which further characterizes the presynaptic nicotinic receptor (Fig.
1b). Pretreatment of the culture with 40 µM
d-TC (Fig. 1c) or 0.1 µM -BuTx (Fig.
1d) prevented the appearance of spontaneous NTCs and
completely antagonized the nicotine-induced currents, suggesting that
most of presynaptic nicotinic receptors at developing motoneurons
belong to an -BuTx-sensitive subtype. Recently, we found that
glutamate markedly increased the frequency of SSCs at embryonic
neuromuscular synapses via the activation of presynaptic NMDA and
non-NMDA receptors (Fu et al., 1995). SSC frequency increased markedly
in response to the local perfusion of glutamate at the synaptic
regions, whereas only a slight increase was observed when perfusion was
performed at the soma. Because an NMDA receptor is highly permeable to
Ca2+ (Ascher and Johnson, 1989), we further examined
the potentiating action of NMDA on ACh release. Local application of
NMDA to the growth cone with another micropipette (intrapipette
concentration at 100 µM) also induced an inward current
(Fig. 2a), indicating the
presence of an NMDA receptor in the nerve terminals. The spontaneous NTC frequency increased by more than 20-fold after treatment with NMDA
(11.2 ± 3.8 Hz; n = 3) (Fig. 2a),
presumably as a result of Ca2+ influx through NMDA
channels. The time course-response curves were shown in Figure
2b. Pretreatment with nicotinic antagonists d-TC (40 µM) or hexamethonium (10 µM) significantly
antagonized the NTC-increasing action of NMDA. The addition of 5 mM Mg2+ in Ringer's solution also
completely inhibited the action of NMDA. These results suggest that
NMDA increases [Ca2+]i to enhance
spontaneous quantal release of ACh from nerve terminals, and the
released ACh then acts on the presynaptic nicotinic autoreceptors of
the same nerve terminal in a feedback manner.
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Figure 2.
Potentiation of spontaneous nerve terminal
currents by NMDA. a, Continuous trace
depicts the membrane currents recorded from the nerve growth cone
before and after local application of NMDA. Downward deflections are
spontaneous NTCs (Vh = 60 mV, filtered at 150 Hz). Local
application of NMDA to the growth cone increased the frequency of NTCs.
Samples of NTCs before and after NMDA treatment are shown
below at higher time resolution. The time
course-response curves were shown in b. Each
curve connects data collected from one neuron.
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Nerve terminal potential change induced by the autoreception of
evoked ACh release
As mentioned above, spontaneous NTCs are caused by the feedback
action on -BuTx-sensitive nicotinic autoreceptors by the spontaneous
quantal ACh release from nerve terminals. We further examined the
nicotinic autoreception by the simultaneous secretion of multiple ACh
quanta evoked by electrical stimulation at the soma. As shown in Figure
3a, ACh release was elicited
by stimulating a naive neuron (a neuron without contact with a myocyte)
at the soma with a heat-polished glass microelectrode. The pipette was filled with Ringer's solution. A square current pulse of 0.1 msec duration and 3-5 V (0.1 Hz) was applied through the pipette. The patch
pipette was whole-cell current-clamped on the growth cone. Evoked
release of ACh induced a positive potential change at nerve growth
cone, which was inhibited by the local application of d-TC (40 µM; n = 3) with the third micropipette,
indicating that the synchronized release of ACh in response to
electrical stimulation also acts on the presynaptic nicotinic
autoreceptors (Fig. 3b). To further characterize the evoked
ACh-induced potential in the nerve terminals, the effects of other
nicotinic and muscarinic antagonists were examined. Application of
hexamethonium (10 µM; n = 3) (Fig.
4a), but not atropine (10 µM) (Fig. 4b), inhibited the evoked
ACh-induced potentials. Reversible inhibition of evoked ACh-induced
potentials by high Mg2+, low Ca2+
Ringer's solution (5 mM Mg2+ and 0.6 mM Ca2+) further strengthens the notion
that these potentials are caused by a neurotransmitter, which is
released in a Ca2+-dependent manner
(n = 3) (Fig. 4c).
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Figure 3.
Nerve terminal potentials caused by the evoked
release of ACh via the activation of nicotinic autoreceptors.
a, Phase-contrast micrograph shows the cultured spinal
neuron and the arrangement of the pipettes for whole-cell recording,
electrical stimulation (sti. pipette), and drug
application, respectively. Scale bar, 20 µm. b, The
trace represents the change in membrane potential of
nerve growth cone induced by stimulating the soma at 0.1 Hz. The nerve
growth cone was whole-cell current-clamped at resting membrane
potential. Note that local perfusion with d-TC inhibited the potential
change. The three to five superimposed potential signals were shown
below at higher time resolution.
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Figure 4.
Inhibition of evoked ACh-induced nerve terminal
potential by hexamethonium and low Ca2+ medium.
Nerve growth cone was whole-cell current-clamped at resting membrane
potential. Evoked ACh-induced nerve terminal potentials were elicited
by stimulating soma at 0.1 Hz. Note that hexamethonium
(a), but not atropine (b),
inhibited these depolarizing potentials. c, Replacement
of normal Ringer's solution with high-Mg2+,
low-Ca2+ Ringer's solution reversibly inhibited the
evoked ACh-induced nerve terminal potentials.
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Regulation of synaptic transmission by the activation of
presynaptic nicotinic autoreceptor
What is the regulatory role of these presynaptic ionotropic
autoreceptors in the synaptic transmission at developing motoneurons? The natural synapses of Xenopus nerve-muscle cocultures
were chosen for the following experiments. SSCs were recorded from the
innervated myocyte by using the whole-cell voltage-clamp method. The
frequency of SSCs was found to vary greatly from cell to cell, over two orders of magnitude. Whether the activation of a presynaptic nicotinic receptor is involved in the induction of high-synaptic activity was
tested by examining the effect of nicotinic receptor antagonist on
the SSC frequency at high-activity synapses ( 3 Hz). It was found that
hexamethonium (10 µM) markedly reduced the frequency of
SSCs at these high-activity synapses (Fig.
5a). The SSC frequency was
reduced from 6.8 ± 0.9 to 1.7 ± 0.3 Hz (n = 7). On the other hand, the SSC frequency of low-activity synapses was
only slightly reduced, probably because of the inhibition of
postsynaptic nicotinic receptors by hexamethonium (Fig. 5b).
To further demonstrate the role of presynaptic nicotinic receptors in
the regulation of evoked ACh release, ESCs were elicited by stimulating
presynaptic neurons at the soma. The ESC amplitude was inhibited by
34% after application of 10 µM hexamethonium (7.7 ± 1.2 and 5.1 ± 0.7 nA, before and after treatment with
hexamethonium, respectively; n = 6) (Fig. 5c). Because the iontophoretic ACh-induced currents were
inhibited by only 11% after treatment with hexamethonium (1.8 ± 0.3 and 1.6 ± 0.2 nA, before and after treatment with
hexamethonium, respectively; n = 4) (Fig.
5d), the higher degree of inhibition of ESCs may result from
the presynaptic nicotinic inhibition of hexamethonium. Therefore, the
activation of presynaptic nicotinic receptors may have positive
regulation of evoked ACh release. To further exclude the possible
postsynaptic inhibition by nicotinic antagonists, we examined the ESCs
by moving a myoball (M1) to form a manipulated synapse with a naive
neuron (Fig. 6a). After
obtaining the control evoked responses (Fig. 6b, left
side, middle trace), the culture was treated with
-BuTx (60 nM) for 20 min, which irreversibly inhibited
the presynaptic nicotinic receptors, and then was washed three times
with plain Ringer's solution. The second myoball (M2) from another
culture dish, which was not treated with -BuTx, was manipulated to
form a synapse at the same site, and the evoked responses were measured
again (Fig. 6b, right side, middle
trace). As shown in Figure 6b, bottom
panels, the ESC amplitude was inhibited by 39% after -BuTx
treatment (from 1.6 ± 0.2 to 0.9 ± 0.2 nA; n = 8; p < 0.05). Because the SSC
amplitude of two myoballs before and after -BuTx treatment did not
show a significant difference (M1, 188.8 ± 32.7 pA; M2,
165.2 ± 24.0 pA, respectively; n = 6; p > 0.05) (Fig. 6b, top panels)
excludes the possible residual postsynaptic inhibitory effect of
-BuTx. For comparison, two myoballs (M1 and M2) were manipulated to
contact with the same site of the control neuron, which was not treated
with -BuTx, in an interval of 30 min, and the evoked responses were
measured in M1 and M2, respectively. The ESC amplitude between
two manipulated myoballs shows no significant difference in this case
(M1, 1.4 ± 0.1 nA; M2, 1.80 ± 0.5 nA, respectively;
n = 4; p > 0.05). In addition, after
treatment of the neuron with -BuTx and washout, the ESC amplitude
was slightly inhibited by 19.7 ± 7.0% (n = 4) in
response to the application of 10 µM hexamethonium, which
primarily resulted from its postsynaptic inhibition. This result
indicates the marked reduction of presynaptic inhibition by
hexamethonium in the -BuTx-treated nerve terminal.
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Figure 5.
Positive feedback regulation of ACh release by the
activation of presynaptic nicotinic autoreceptors. The innervated
myocyte was whole-cell voltage-clamped at 60 mV. Downward deflections
indicated SSCs (filtered at 150 Hz). Application of nicotinic receptor
antagonist hexamethonium markedly inhibited the spontaneous ACh release
of the high-activity synapses (a) but only
slightly affected that of low-activity synapses
(b). c, A presynaptic neuron was
stimulated at the soma to induce ESCs at 0.1 Hz. Note that application
of hexamethonium inhibited the ESCs by 34%. d,
Identical iontophoretic pulses of ACh at 0.5 Hz were applied to the
surface of an isolated myocyte. Application of hexamethonium only
slightly inhibited the iontophoretic ACh-induced currents.
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Figure 6.
Pretreatment of neurons with -bungarotoxin
inhibited evoked synaptic currents in manipulated synapses.
a, The photograph shows that the ESCs were examined by
moving a myoball (M1) to form a manipulated synapse with
a naive neuron (N). After obtaining the
control ESCs by stimulating (Sti.) the soma at 0.1 Hz,
the M1 was removed away, and the culture was treated with -BuTx (60 nM) for 20 min and then washed three times with plain
Ringer's solution. The second myoball (M2) from another
culture dish, which was not treated with toxin, was then manipulated to
form a synapse at the same site, and the evoked responses were measured
again. Scale bar, 30 µm. b, The downward
deflections in the middle trace indicated SSCs and ESCs
(filled circles) (filtered at 150 Hz). -BuTx treatment
significantly inhibited the amplitude of ESCs but not that of SSCs. The
top panels show the representative superimposed
SSC events during a 10 sec period, and the bottom panels
show the four superimposed ESCs at higher time resolution.
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DISCUSSION |
The major findings reported here are that the activation of
-BuTX-sensitive nicotinic autoreceptors by spontaneously released ACh can induce NTCs in the same neuron. The appearance of NTCs is very
much like that of SSCs, which are recorded in postsynaptic cells.
Increase of intracellular Ca2+ by NMDA application
enhanced the frequency of NTCs. The NTCs were blocked by hexamethonium,
d-TC, and -BuTx, suggesting that the AChRs present on the nerve
terminals are predominantly the nicotinic type. The neuronal nAChRs are
involved in cholinergic transmission in the peripheral nervous system,
as well as in the CNS (Bertrand and Changeux, 1995; Role and Berg,
1996). To date, 11 members of the nAChR family have been identified and
cloned from vertebrate genomes (Lindstrom, 1996). One of the most
prominent classes of nAChRs contains the 7 and/or 8 gene product.
Such receptors have a relatively high permeability to
Ca2+ and bind -BuTx with high affinity (Couturier
et al., 1990; Schoepfer et al., 1990; Vijayaraghavan et al., 1992;
Seguela et al., 1993). This type of nAChR is fully blocked by low
concentrations of -BuTx, and the blockade is relatively
irreversible, as is true of -BuTx binding to skeletal muscle AChRs
(Smith et al., 1985). The conclusion that -BuTx-sensitive nAChRs are
responsible for the positive regulation of ACh release is supported by
the pharmacological evidence showing that block of presynaptic AChRs by
-BuTx can inhibit evoked ACh release or the SSC frequency at
high-activity synapses. Treatment of neurons with -BuTx and then
washout resulted in the inhibition of evoked synaptic currents of the
second manipulated myoball. This result arises from the blockade of
-BuTx-sensitive receptors on the presynaptic nerve terminals rather
than from postsynaptic receptors, because -BuTx blocked 39% of the
synaptic responses evoked by nerve stimulation but had little effect on the mean amplitude of SSCs between two manipulated myoballs. The positive feedback regulation of ACh release by the activation of an
-BuTx-sensitive nicotinic autoreceptor may result from the
Ca2+ influx directly through the AChR channel.
However, voltage-gated Ca2+ channels represent a
second pathway by which extracellular Ca2+ could
enter the cell. In the cultured Xenopus motoneuron, N-type Ca2+ channels are responsible for action
potential-evoked ACh release, because  -conotoxin completely
inhibited the evoked synaptic currents (data not shown). On the other
hand, L-type Ca2+ channels are involved in the
regulation of spontaneous ACh release at high-activity synapses (Fu and
Huang, 1994). It was demonstrated here that the activation of
presynaptic -BuTx-sensitive nicotinic autoreceptors by spontaneously
released ACh is able to produce substantial membrane depolarization,
which may thus open voltage-gated Ca2+ channels and
thereby augment Ca2+ entry. In addition, it was
found that the evoked release of ACh is also able to induce substantial
membrane depolarization. In view of the dependence of this evoked
response on extracellular Ca2+, the evoked-induced
potential change in nerve terminal may result from
Ca2+-dependent ACh release, which is also inhibited
by nicotinic antagonists d-TC and hexamethonium but not by the
muscarinic antagonist atropine. At high-activity synapses, the
presynaptic nicotinic autoreceptor can be tonically activated by the
ambient ACh. Here, it seems that the response of presynaptic nAChR
after bath application of nicotine desensitized more slowly than that
reported elsewhere (Couturier et al., 1990). Some nAChRs, including
7, may contain more than a single type of or  subunit. Such
differences may result in changes in desensitization properties
(Ramirez-Latorre et al., 1996; Wang et al., 1996).
The effects of the nicotinic antagonist d-TC on ACh release from adult
motor nerve terminals are the subject of much controversy. It is
generally accepted that d-TC possesses a prejunctional action at the
neuromuscular junction. This is manifest in twitch tension experiments
as tetanic fade, i.e., the inability of a muscle to sustain tension
during high-frequency stimulation and in electrophysiological experiments as an enhanced diminution of the amplitude of end-plate potentials during high-frequency stimulation of motoneurons (Magleby et
al., 1981; Gibb and Marshall, 1984). It is proposed that these putative
receptors form part of a positive-feedback system; activation of
presynaptic nicotinic autoreceptors by ACh enhances the mobilization and release of ACh during high-frequency stimulation of motoneurons. In
the current study, the presynaptic nAChRs are sensitive to the
inhibition by -BuTx, and thus, most nAChRs are highly
Ca2+ permeable. Here, we found that the activation
of presynaptic nicotinic receptors at developing motoneurons has
positive regulation in both spontaneous and evoked ACh release.
However, there is no tetanic fade phenomenon in these embryonic
motoneurons (Fu and Liu, 1997).
The -BuTx-sensitive nAChR would have the potential of influencing a
vast array of Ca2+-related events in the neurons
because of its high permeability to Ca2+. In
addition to regulating transmitter release, as is the case in chick
retinal cells and the pheochromocytoma cell line PC12, cholinergic
antagonists or -BuTx has been shown to promote the extension of
neurites (Lipton et al., 1988; Quik et al., 1990). Because both types
of cultures can synthesize and release ACh under some conditions
(Greene and Rein, 1977; Lipton, 1988), the -BuTx effects may result
from its inhibition of nicotinic autoreceptor activation. In the chick
ciliary ganglion, the -BuTx-sensitive nAChRs have been shown to have
a predominantly nonsynaptic location on neurons and may be concentrated
on pseudodendrites emerging from the soma (Jacob and Berg,
1983). Activation of this type of nAChRs on ciliary ganglion neurons in
dissociated cell culture inhibits neurite extension and induces a
partial retraction of the processes in a
Ca2+-dependent manner (Pugh and Berg, 1994). The
-BuTx effects can thus be interpreted as relieving an ongoing
ACh-induced inhibition of neurite outgrowth. From a preliminary study,
we found that bath application of -BuTx to 4 hr cultured
Xenopus spinal neurons also enhanced axonal growing rate,
indicating that activation of a nicotinic autoreceptor inhibits the
axonal growth (our unpublished observations). The nAChRs of
growth cone may play a role in neurite arrest after target contact. We
found here that the growth cone of myocyte-contact neuron exhibits more
NTCs than that of naive neurons. In addition, myocytes are also
able to secrete ACh (Fu et al., 1998). Presynaptic -BuTx-sensitive
nAChRs could thus provide a mechanism for terminating axonal growth
when the axon contacts with myocyte. Therefore, nicotinic autoreceptor
in the growth cone may play functional roles in nerve growth,
plasticity of neurites, and synapse formation (Chan and Quik,
1993).
In conclusion, our results provide to our knowledge the first
electrophysiological evidence that ionotropic autoreceptors can be
activated by the endogenously released neurotransmitter. We showed here
that the -BuTx-sensitive nAChRs in presynaptic nerve
terminals are ligand-gated ion channels and are cation selective. The
membrane potential change via the activation of nicotinic autoreceptors
by endogenously released ACh provides a possible mechanism for both
endogenous and exogenous cholinergic agents in the CNS. Activation of
autoreceptors by endogenously released ACh will further increase the
efficacy of cholinergic neurons. Presynaptic nicotinic autoreceptors
may play an important role in the regulation of synaptic transmission,
neuronal growth, and synaptogenesis.
| |
FOOTNOTES |
Received June 29, 1998; revised Sept. 14, 1998; accepted Sept. 22, 1998.
This work was supported by a grant from the National Science Council.
We thank I. S. Peng for help in the preparation of this manuscript.
Correspondence should be addressed to Dr. Fu at the above address.
| |
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Abstract
Introduction
Compound via MeSH
