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Next Article 
Volume 17, Number 18,
Issue of September 15, 1997
pp. 6839-6849
Copyright ©1997 Society for Neuroscience
Serotonergic Inhibition of the T-Type and High Voltage-Activated
Ca2+ Currents in the Primary Sensory Neurons of
Xenopus Larvae
Qian-Quan Sun and
Nicholas Dale
School of Biological and Medical Sciences, St. Andrews University,
St. Andrews, Fife, KY16 9TS United Kingdom
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
The primary sensory Rohon-Beard (R-B) neurons of
Xenopus larvae are highly analogous to the C fibers of
the mammalian pain pathway. We explored the actions of 5-HT by studying
the modulation of Ca2+ currents. In ~80% of the
acutely isolated R-B neurons, 5-HT inhibited the high
voltage-activated (HVA) currents by 16% (n = 29)
and the T-type currents by 24% (n = 41). The
modulation of the T-type and the HVA currents was mimicked by selective
5-HT1A and 5-HT1D agonists: 8-OH-DPAT and
L-694,247. The effects of the agonists were blocked by their respective
5-HT1A or 5-HT1D antagonists: p-MPPI and GR127935, suggesting that both
5-HT1A and 5-HT1D receptors were involved.
Approximately 70% of the actions of 5-HT on HVA currents was occluded
by  -conotoxin-GVIA (N-type channel blocker), whereas the rest of the
modulation (~30%) was occluded by <100 nM
-agatoxin-TK (P/Q-type channel blocker). This suggests that 5-HT
acts on N- and P/Q-type Ca2+ channels. Neither the
modulation of the T-type nor that of the HVA currents was accompanied
by changes in their voltage-dependent kinetics. Cell-attached
patch-clamp recordings suggest that the modulation of the T-type
channel occurs through a membrane-delimited second messenger. We have
studied the functional consequences of the modulation of T-type
Ca2+ channels and have found that these channels
play a role in spike initiation in R-B neurons. Modulation of T-type
channels by 5-HT therefore could modulate the sensitivity of this
sensory pathway by increasing the thresholds of R-B neurons. This is a
new and potentially important locus for modulation of sensory pathways in vertebrates.
Key words:
5-HT1A receptor;
5-HT1D receptor;
T-type Ca2+ currents;
-conotoxin-GVIA;
-agatoxin-TK;
spike initiation;
Xenopus;
Rohon-Beard
neurons
INTRODUCTION
Serotonin (5-HT) released from
the descending fibers of the raphe nucleus plays an important role in
limiting the access of nociceptive information from the spinal cord to
higher centers (Millan, 1995 ). The receptors and mechanisms by which
5-HT exerts this antinociceptive action in the spinal cord have been
studied incompletely. 5-HT1A (Eide et al., 1990; Crisp et
al., 1991; Lucas et al., 1993; Del Mar et al., 1994),
5-HT1B (Eide et al., 1990) and 5-HT2A/2C (Xu et
al., 1994) receptors have been implicated in the modulation of
nociception. However, the roles of 5-HT1D receptors in the
modulation of sensory transmission remain unknown.
The cellular actions of serotonin on sensory neurons also are
understood incompletely. One possible action is to inhibit
Ca2+ entry into sensory neurons (Del Mar et al.,
1994). In other CNS neurons N-type or P/Q-type high voltage-activated
(HVA) calcium channels can be modulated by serotonin, mostly via
5-HT1A receptor and membrane-delimited G-protein pathways
(Pennington et al., 1991; Koike et al., 1994; Bayliss et al., 1995;
Foehring et al., 1996). These calcium channels are known to be involved
in triggering synaptic transmission (Luebke et al., 1993; Luebke and
Dunlap, 1994; Wall and Dale, 1994; Wheeler et al., 1994) (for review, see Dunlap, 1997). By contrast, T-type channels are not involved in
transmitter release but, instead, influence the firing properties of
CNS neurons (Llinás and Yarom, 1981; Crunelli et al., 1989; Suzuki and Rogawski, 1989; White et al., 1989; Zhang et al., 1993). The
effects of 5-HT on T -type channels are variable. In some CNS neurons
5-HT has no action on T-type channels (e.g., motoneurons; Bayliss et
al., 1995), whereas in others it acts to increase the T-type current
(Berger and Takahashi, 1990; Fraser and MacVicar, 1991). However,
neither the functions of T-type channels in sensory transmission nor
its modulation by 5-HT has been described.
Previous reports have demonstrated that 5-HT mediates presynaptic
inhibition of transmitter release from Xenopus primary
sensory neurons: Rohon-Beard (R-B) neurons (Sillar and Simmers,
1994). We therefore examined the effects of 5-HT on voltage-dependent Ca2+ channels in acutely isolated R-B neurons. Our
aims were to characterize the voltage-dependent Ca2+
channels modulated by 5-HT, identify the types of receptors involved, and explore some of the possible functional consequences. We found that
5-HT inhibits both the N-, P/Q-type HVA currents and the T-type
currents. Although the modulation of HVA currents could contribute to
the presynaptic inhibition of transmitter release from R-B neurons
(Sillar and Simmers, 1994), the modulation of T-type currents suggests
an additional and important locus for modulation of sensory
pathways.
MATERIALS AND METHODS
Preparation of the acutely isolated spinal neurons
Acutely isolated spinal neurons were prepared by methods based
on those described by Dale (1991). In accordance with the United Kingdom Animals (Scientific Procedure) Acts of 1986, stage 40-42 Xenopus larvae (Nieuwkoop and Faber, 1956) were anesthetized
in a solution of MS222 (0.5 mg/ml; Tricaine, Sigma, Poole, UK); pinned to a rotatable SYLGARD table in HEPES saline with the following composition (in mM): 117.4 Na+, 3 K+, 1 Mg2+, 2 Ca2+, 2 NO3 , 2.4 HCO3, 124 Cl, 10 HEPES, and 10 glucose at pH 7.4; and their spinal cords were removed
carefully, transferred to a dish containing 0.1-0.3 mg/ml DNase in
HEPES saline, and incubated at room temperature for 3 min. After this,
the spinal cords were placed in a dish containing 8 mg/ml Pronase
(Sigma) in a low chloride trituration saline, composed of (in
mM) 117.4 Na+, 115 MeSO3, 3 K+, 1 Mg2+, 2 Ca2+, 2 NO3, 2.4 HCO3, 9 Cl, 10 HEPES, and 10 glucose at pH 7.4 and incubated at room temperature for 2 min. They were transferred to a dish of dissociation saline composed of
(in mM) 115 Na+, 115 MeSO3, 3 K+, 2 EDTA, 3 Cl, 10 HEPES, 10 glucose, and 10 piperazine-N, N -bis (2-ethanesulfonic acid,
PIPES) at pH 7.0 for 1 min and then to a dish of PIPES saline composed
of (in mM) 115 Na+, 115 MeSO3, 3 K+, 0.1 Mg2+, 0.1 Ca2+, 3 Cl, 20 glucose, and 10 PIPES at pH 7.0 for 3 min.
The spinal cords were triturated gently in a saline containing 3 mg/ml
DNase in a microfuge tube until the cords had dissociated. Finally, the cells were transferred to 35 mm poly-D-lysine-coated dishes
in HEPES saline and allowed to settle and stick to the substrate for at
least 1 hr before recording.
Patch-clamp recordings
Owing to their unique morphological characteristics,
Rohon-Beard neurons were readily identifiable under phase-contrast
microscopy, based on the criteria of Dale (1991): a large spherical
soma (mean diameter 23 µm), a large nucleus (mean diameter 12 µm),
and dark nucleolus. Whole-cell calcium currents and unitary calcium
channel recordings were obtained as described by Hamill et al. (1981). Electrodes were fabricated with a Sutter Instrument P97 puller (Novato,
CA) from capillary glass obtained from World Precision Instruments (TW
150F; Sarasota, FL) and Clark Electromedical Instruments (GC150F-10;
Pangbourne, UK), coated with SYLGARD, and fire-polished. A List L/M-PC
amplifier together with a DT2831 interface (Data Translation) was used
to record and digitize the voltage and current records. Data were
acquired to the hard disk of an IBM-compatible PC, although an optical
disk was used for long-term storage of experimental records. The
whole-cell recordings had access resistances ranging from 4 to 12 M .
Between 70 and 85% of this access resistance was compensated for
electronically. The adequacy of the voltage clamp was accessed by
studying the I-V relations obtained from a series of
voltage steps separated by 5 mV. The criterion for effective space
clamp was a smoothly activating current. For the recording of
Ca2+ currents, external solutions were composed of
(in mM) 57.5 Na+, 57.5 TEA, 2.4 HCO3, 3 K+, 10 Ca2+, 1 Mg2+, 10 HEPES, 1 4-aminopyridine (4-AP), pH 7.4, adjusted to 260 mOsm/l, and TTX (140 nM). The pipette solution contained (in mM) 100 Cs+, 1 Ca2+, 6 Mg2+, 20 HEPES, 5 ATP, and 10 EGTA, pH 7.4, adjusted
to 240 mOsm/l. Unitary channel recordings (cell-attached mode) were
made by methods described by Chen and Hess (1990); the membrane
potential outside the bath was zeroed with the following external
solution: 110 mM K-MeSO3, 10 mM EGTA, and 10 mM HEPES, titrated to pH 7.4 with KOH. The pipette solution contained 110 mM
BaCl2 and HEPES 10 mM, pH 7.5. Leak subtraction
was performed on unitary channel and whole-cell recordings by either of
two methods. For one method the current of interest was blocked
(Y3+ 30 µM or Cd2+
120 µM), and the remaining leak currents were subtracted
from the equivalent experimental records from the same cell. In the other method a scaled negative version of the experimental pulse protocol was given to the same cell. This subsequently was scaled up
and added to the experimental records. In both cases the leak currents
were obtained immediately before or after each set of experimental
records. Drugs were applied through a multibarreled microperfusion
pipette that was positioned within 1 mm of the cell. All experiments
were performed at room temperature, 18-22°C. Experiments using
nifedipine were performed in dark conditions.
Chemicals used
Serotonergic agonists and antagonists. The
following serotonergic agonists and antagonists were used:
7-trifluoromethyl-4-(methyl-1-piperazinyl) pyrrolo[1,
1-a]-quinoxaline dimaleate (CGS12066B, Tocris Cookson, Bristol, UK),
5-carboxyamidotryptamine (5-CT, RBI, Natick, MA), 5-hydroxytryptamine
(5-HT, RBI), N-[4-methoxy-3-(4-methyl-1-piperazinyl) phenyl]-2-methyl-4-(5-methyl-1, 2, 4-oxadiazol-3-yl) [1,
1-biphenyl]-4-carboxamide (GR127935, GlaxoWellcome Research and
Development, Research Triangle Park, NC), R(+)-8-OH-DPAT
(DPAT, RBI), ketanserin tartrate (RBI),  -methyl-5-hydroxytryptamine
(-M-5-HT, Tocris Cookson), 2-[5-[3-(4-methylsulphonylamino) benzyl1,2,4-oxadiazol-5-yl]-1 H-indole-3-yl]ethanamine
(L-694,247, Tocris Cookson), 1-(2-methoxyphenyl)-4-[4-(2-phthalimido)
utyl] piperazine (NAN-190, RBI),
4-[Iodo-N-[2-[4-(methoxyphenyl)-1-piperazinyl]ethyl]-N-2-pyridinyl-benzamide (p-MPPI, RBI), and N-desmethylclozapine
(RBI). 5-CT, L-694,247, clozapine, and NAN-190 were dissolved initially
by a few drops of dimethylsulphoxide and stored in a freezer.
Ion channel blockers. The following ion channel blockers
were used: tetrodotoxin (TTX, Sigma), -agatoxin IVA and
-agatoxin-TK (agatoxin, Alomone Labs, Jerusalem, Israel),
-conotoxin GVIA (-CgTx, Bachem, Torrance, CA), -conotoxin
MVIIC (Alomone Labs), nifedipine (Sigma), tetraethylammonium chloride
(TEA, Aldrich), and yttrium nitrate (Y3+,
Sigma).
Statistics
All data are presented as mean ± SD unless otherwise
stated. Analysis by Student's t test was performed for
paired and unpaired observations. Differences in frequency of
occurrence were assessed by using a 2 × 2 contingency table
and  2 parameter. p values of <0.05 were
considered as a significant level.
Fitting
The Levenberg-Marquardt algorithm was used to fit the Hill
equation to dose-response data. This gave the best-fitting parameters and their SEs. For all other fitting procedures, the simplex algorithm was used.
RESULTS
Serotonin reversibly reduced both the HVA and T-type
Ca2+ currents
Whole-cell Ca2+ currents recorded from
acutely isolated R-B neurons possess both T-type and HVA currents.
These can be distinguished by their voltage dependence of activation
and inactivation. T-type currents were elicited at test potentials
above  60 mV and almost totally inactivated in a 100 msec test pulse.
HVA currents were evoked at potentials of 20 mV or more and came to
dominate the whole-cell current at potentials above 10 mV (Fig.
1A). Using a twin pulse
from a holding potential of 90 mV, we elicited both the T-type and
the HVA currents, and we examined the effects of 5-HT on both. In
~80% of the neurons examined, 5-HT reversibly reduced both the
T-type and the HVA Ca2+ currents (Fig.
1B).
Fig. 1.
Both the HVA and the T-type
Ca2+ currents were reduced by 5-HT in acutely
isolated R-B neurons. A, R-B neurons possess both the
HVA and the T-type Ca2+ currents.
A1, Whole-cell
Ca2+ currents were recorded by using
steps from a holding potential of 80 mV to test potentials between
60 and +30 mV in a stage 42 Xenopus R-B neuron.
A2, I/V curve
measured from the peak (showing the T-type and HVA currents) and end
(showing only the HVA currents) of the Ca2+ currents
(symbols correspond to measurements in
A1). B1, T-type and HVA currents were
elicited in the same neuron by test steps of 30 and +10 mV,
respectively, from a holding potential of 90 mV. Both were reduced by
1 µM 5-HT (shown by asterisk); unlabeled
traces are control and wash. B2, Courses of the effects of 5-HT showing that they were totally reversible on both currents in the same neuron (symbols
correspond to measurements in
B1).
[View Larger Version of this Image (17K GIF file)]
Inhibition of the HVA currents by 5-HT was
not voltage-dependent
The modulation of the HVA currents by serotonin was examined
in R-B neurons. 5-HT never caused the slowing of activation of the
Ca2+ currents (Fig.
2A1)
that usually occurs during direct G-protein modulation (for review, see
Hille, 1994). In five neurons there was no voltage sensitivity to the
block by 5-HT (Fig. 2A2). In
most cases, voltage-dependent G-protein inhibition can be relieved by
giving a positive prepulse immediately preceding the test pulse. We
therefore tested whether prepulses could lessen the block of HVA
currents by 5-HT. In five of five neurons tested, the inhibition of HVA
currents by 5-HT was not, even partially, relieved by a very positive
prepulse (Fig. 2B), suggesting that the inhibition of
HVA currents by 5-HT occurred only via voltage-independent mechanisms.
Fig. 2.
Voltage-independent inhibition of the HVA
Ca2+ currents by 5-HT.
A1, Ca2+
currents elicited by steps from a holding potential of 80 mV (asterisk = 1 µM 5-HT).
A2, The inhibition of HVA
currents by 5-HT (1 µM) was independent of membrane
potential (n = 5); I5-HT, current in presence of 5-HT;
ICon, current in the control. B1, Example showing that the
inhibition of the HVA currents in RB neurons was not changed by
applying a +120 mV prepulse (asterisk = trace
elicited by test pulse with 120 mV prepulse in 1 µM
5-HT). B2, Summary showing no
significant difference between the mean inhibition of the HVA currents
before and after applying a 120 mV prepulse in five R-B neurons.
[View Larger Version of this Image (13K GIF file)]
5-HT receptor subtypes involved in the inhibition of the
HVA currents
To identify the serotonin receptors involved in the modulation of
HVA calcium currents, we applied selective agonists and antagonists.
The effects of 8-OH-DPAT (100 nM), a selective
5-HT1A agonist (Middlemiss and Fozard, 1983), were fully
blocked by the selective 5-HT1A antagonist
p-MPPI (100 nM; Kung et al., 1994) in six
examined neurons (Fig.
3A2,B).
The actions of L-694,247, a specific 5-HT1D agonist (Beer
et al., 1993), were not blocked by the selective 5-HT1A
antagonists NAN-190 (100 nM) and p-MPPI (100 nM) but were blocked by GR127935 (100 nM), a
selective 5-HT1D antagonist (Skingle et al., 1993) in six
examined neurons (Fig.
3A1,B). This
suggests that both 5-HT1A and 5-HT1D receptors
were involved in the inhibition of the HVA Ca2+
current.
Fig. 3.
The inhibition of HVA Ca2+
currents by 5-HT is dose-dependent and mediated via 5-HT1A
and 5-HT1D receptors.
A1, The selective
5-HT1D agonist L-694,247 (100 nM) inhibited HVA
currents. The effects of L-694,247 (100 nM) were blocked by
the selective 5-HT1D antagonist GR127935 (100 nM). A2, The
selective 5-HT1A agonist 8-OH-DPAT (100 nM)
also inhibited the HVA currents. The effects of 8-OH-DPAT (100 nM) were totally blocked by the selective
5-HT1A antagonist p-MPPI (100 nM). B, Summary of the antagonist effects on
the agonists of 8-OH-DPAT and L-694,247 (*p < 0.05 vs agonists alone). C, The inhibition of HVA currents by
5-HT was dose-dependent (n = 7-39 for each dose).
The smooth line is the best-fitting Hill equation.
[View Larger Version of this Image (23K GIF file)]
In those neurons that responded, the addition of 5-HT produced a
dose-dependent reversible reduction of HVA currents with a half-block
concentration (IC50) of 40.8 ± 20.4 nM (Fig. 3C). The 5-HT1D agonist
L-694,247 had a similar IC50 (38.1 ± 10.4 nM, n = 16) for the inhibition of HVA
currents. The observed maximum reduction of HVA currents was 29%,
whereas the mean maximum inhibition by 5-HT (1 µM) was
16.2 ± 2.4% (n = 39). Recovery from the effects of 5-HT on the HVA currents was rather slow on washout. In six cells
the time course for wash was fit with a single exponential curve. This
gave a mean time constant of 22.5 ± 3.4 sec (n = 6) for the recovery of the HVA current from inhibition by 5-HT.
HVA calcium channel identity
To identify further the HVA channel types possessed by
Xenopus R-B neurons, we used -conotoxin, fraction GVIA
(-CgTx), which is a selective N-type Ca2+ channel
blocker (Feldman et al., 1987), -agatoxin-TK, which is a P/Q-type
channel blocker (Teramoto et al., 1995), and nifedipine, a selective
blocker of L-type channels. -CgTx (1 µM) irreversibly blocked 70.4 ± 2.8% (n = 16) of the HVA currents
(Fig. 4A,B). Thus in R-B neurons the HVA calcium
currents were carried mostly through -CgTx-sensitive (N-type)
channels. -Agatoxin-TK (200 nM) irreversibly blocked
25.5 ± 3.2% (n = 6) of the total HVA currents
(Fig. 4A). The actions of -agatoxin-TK on HVA
currents probably were saturated at ~40 nM, because the
higher dose of 200 nM did not produce further block. The
-agatoxin-sensitive current did not show significant inactivation
(e.g., Fig. 4A2), suggesting
that R-B neurons possess many more P-type channels than Q-type
channels (Teramoto et al., 1995). Nifedipine (10 µM) did
not block the HVA currents in three of eight R-B neurons and blocked
only very small amounts of the HVA current in the other five neurons
(mean block 5.5 ± 1.8%, p > 0.1 vs control;
Fig. 4A), suggesting that R-B neurons possess only a
very small number of L-type channels. In five neurons examined, 100 µM Cd2+ blocked the remainder of the
HVA current after combined treatment with -CgTx and -agatoxin
(~5%; Fig. 4A), suggesting that R-B neurons also
possess a very small amount of R-type channels (Birnbaumer et al.,
1991). Thus the calcium influx via HVA currents was carried mostly by
N- and P-type channels in the sensory neurons of
Xenopus.
Fig. 4.
The identity of the calcium channels inhibited by
5-HT in RB neurons. A1, Time
courses of the effects of calcium channel blockers -agatoxin-TK (100 nM), -CgTx (1 µM), nifedipine (10 µM), and Cd2+ (100 µM)
on the HVA currents. A2, Calcium
currents elicited by steps to 10 mV from a holding potential of 50 mV
during the application of the blockers (same neuron as in
A1).
A3, Summary of the effects of
calcium channel blockers on the HVA currents in R-B neurons.
B1, Recording showing that the inhibition of HVA currents by 5-HT (1 µM) was mostly
occluded by -conotoxin (1 µM) in a R-B neuron.
B2, Recording showing that the
inhibition of HVA currents by 5-HT (1 µM) was partially
occluded by -agatoxin-TK (100 nM), whereas the remaining inhibition was totally occluded by 1 µM -conotoxin
(asterisk = HVA currents recorded in 5-HT on top of
Ca2+ channel blockers).
B3, Summary of the inhibition of the HVA currents by 5-HT alone and additional inhibition on top of
calcium channel blockers (*p < 0.05 and
**p < 0.01 vs 5-HT alone).
[View Larger Version of this Image (26K GIF file)]
We next characterized the identity of the HVA channels modulated
by 5-HT in R-B neurons by applying 5-HT alone and in the presence of
-CgTx (1 µM) or -agatoxin-TK (100 nM)
to determine whether the blocking action of the two drugs was additive
or occlusive. 5-HT inhibited the HVA current by 18.4 ± 1.4%
(n = 18; p < 0.01 vs control) when
applied alone. In the presence of -CgTx (1 µM), 5-HT
produced only 6.2 ± 1.3% further inhibition (n = 16; p < 0.01 vs 5-HT alone; Fig.
4B1,B3).
Therefore, ~65% of the inhibition of HVA currents was occluded by
-CgTx. This substantial occlusion suggests that N-type
Ca2+ channels were the predominant target of 5-HT.
In six neurons the effects of 5-HT also were attenuated significantly
by 100 nM agatoxin: 5-HT on top of agatoxin only blocked a
further 11.6 ± 1.2% inhibition of HVA currents, which is
significantly less than 5-HT alone (p < 0.05 vs
5-HT alone; Fig.
4B2,B3), suggesting that P/Q-type channels account for ~30% of the inhibition of HVA currents by 5-HT. On top of both -CgTx and -agatoxin-TK, 5-HT produced almost no further inhibition (2.1 ± 0.4%,
n = 5; Fig.
4B2,B3).
This suggests that N- and P/Q-type calcium channels together account
for almost all of the inhibition of HVA currents by 5-HT.
The downstream functional consequences and the signaling pathways
for the modulation of the HVA channels, such as N-type and P/Q-type
channels, by G-protein-coupled receptors have been widely described
(for review, see Hille, 1994; Wickman and Clapham, 1995; Dunlap, 1997).
The most novel aspects of our results are the modulation of neuronal
T-type channels, which differ in their kinetic properties from the HVA
channels. These differences mean that HVA and T-type channels perform
different roles in the control of neuronal excitability. We therefore
have concentrated on characterizing modulation of the T-current in more
detail.
Serotonin inhibits T-type Ca2+ currents via
5-HT1A and 5-HT1D receptors
The effect of 5-HT on T-type Ca2+ current was
examined by using a repeated pulse protocol with a test potential of
30 mV (or more) from a holding potential of 90 mV. In acutely
isolated R-B neurons, the addition of 5-HT produced dose-dependent
inhibition (Fig.
5A1).
The maximum inhibition was 54% of the control T-type
Ca2+ current, whereas the mean maximum inhibition
for 5-HT (1 µM) was 24.0 ± 2.2% (n = 41).
Fig. 5.
Inhibition of the T-type calcium currents by
serotonergic agonists. A, Representative traces
(asterisk represents recordings in 100 nM
selective agonists; unlabeled traces are control and wash) and
dose-response relations showing the block of T-type currents by
selective serotonergic agonists: 5-HT
(A1), 8-OH-DPAT
(A2), and L-694,247
(A3); n = 7-41 for each point. The solid line is
the best fit of the Hill equation. A4, The inhibition of T-type
currents by L-694,247 (100 nM) and 8-OH-DPAT (100 nM) was additive. B, Summary of the mean inhibition of T-type currents by selective serotonergic agonists at
maximum dose in R-B neurons: 5-HT (1 µM,
n = 41), 8-OH-DPAT (100 nM,
n = 23), L-694,247 (100 nM,
n = 22), CGS-12066B (1 µM, n = 8), -M-5-HT (1 µM,
n = 7), and 5-CT (100 nM,
n = 5) (**p < 0.01 vs
control).
[View Larger Version of this Image (22K GIF file)]
The time course for wash of the serotonergic modulation of T-type
currents could be fit with a single exponential curve. This gave a mean
time constant of 9.8 ± 2.6 sec (n = 6) for
recovery from inhibition by 5-HT, which was one-half of that for the
recovery time course seen during modulation of the HVA currents
measured in the same neurons. This large difference in the speed of
recovery from inhibition for the T-type and HVA currents suggests that different underlying second messengers may be involved. To identify the
5-HT receptors involved in modulation of the T-type current, we applied
specific agonists and antagonists to the R-B neurons.
5-HT agonists
A range of selective 5-HT1 agonists including
8-OH-DPAT, L-694,247, 5-CT (Beer et al., 1992; Hoyer et al., 1994), and
a 5-HT1/2 agonist, -methyl-5-HT (Ismaiel et al.,
1990)reversibly inhibited the T-type Ca2+ currents
(Table 1, Fig. 5A,B). However,
the 5-HT1B receptor agonist CGS-12066B (Neale et al.,
1987), from 10 nM to 1 µM (n = 8), had almost no effect on T-type Ca2+ currents
(Fig. 5B, Table 1). The effects of 5-HT, 8-OH-DPAT, and
L-694,247 were very potent with IC50 values <1
nM (Fig. 5A, Table 1). Thus, a diversity of
agonists that act on 5-HT1 receptors (except
5-HT1B) inhibited T-type Ca2+
currents by similar amounts at very low concentrations (<10
nM). In three of three examined R-B neurons, the actions
of saturating doses of L-694,247 (100 nM) and 8-OH-DPAT
(100 nM) were additive (Fig.
5A4), strongly suggesting that they
act on different receptors.
5-HT antagonists
To confirm the identities of the serotonin receptor subtypes
involved in the inhibition of the T-type Ca2+
current, we used specific antagonists (Fig.
6, Table 1). Our results are consistent
with an involvement of 5-HT1A and 5-HT1D receptors. In brief, the effects of 5-HT, 8-OH-DPAT, 5-CT, and -methyl-5-HT were blocked by the 5-HT1A antagonist
p-MPPI (Kung et al., 1994) (Fig. 6, Table 1). In addition, a
second 5-HT1A antagonist, NAN-190 (100 nM; Liau
et al., 1991), also reduced the effect of 8-OH-DPAT and 5-CT by similar
amounts (68.5 ± 5.6%, n = 5 and 52.1 ± 3.3%, n = 6, respectively) but, strangely, had no
effect on the actions of 5-HT (data not shown). Neither
p-MPPI nor NAN-190 blocked the effects of L-694,247 (Fig.
6B, Table 1). However, 5-HT1D antagonist
GR127935 (Skingle et al., 1993) blocked the effects of 5-HT and
L-694,247 without affecting 8-OH-DPAT (Fig. 6B, Table
1). 5-HT2 receptors were unlikely to be involved because
neither ketanserin nor clozapine, which are both 5-HT2A/2C antagonists (Awouters, 1985; Kuoppamaki et al., 1993), had any effects
on 5-HT or -methyl-5-HT. Thus both 5-HT1A and
5-HT1D receptors are involved in the inhibition of T-type
current, a conclusion further strengthened by the additive effects of
the specific antagonists (Fig.
6A3,B3).
Fig. 6.
Effects of selective antagonists on the inhibition
of T-type calcium currents by selective agonists in
Xenopus R-B neurons. Both p-MPPI (100 nM, A1) and GR127935
(100 nM, A2) partially blocked the effect of 5-HT (1 µM).
A3, p-MPPI (100 nM) and GR127935 (100 nM) produced an additive
block of the effect of 5-HT (1 µM). p-MPPI
blocked the effect of 8-OH-DPAT (100 nM,
A4), whereas GR127935 (100 nM) blocked the effect of L-694,247 (100 nM,
A5).
B1, Summary of the block by the
selective antagonists on 8-OH-DPAT (100 nM)
(**p < 0.01 vs 8-OH-DPAT).
B2, Summary of the block by
antagonists on L-694,247 (100 nM) (**p < 0.01 vs L-694,247). B3, Summary of the block by selective antagonists on 5-HT (1 µM) (**p < 0.01 vs 5-HT).
[View Larger Version of this Image (32K GIF file)]
Modulation of T-type channel does not occur through a freely
diffusible second messenger pathway
To test whether the modulation of T-type channels was mediated via
a freely diffusible second messenger or by a membrane-delimited pathway, we examined the effects of 5-HT on T-type channel activity recorded in the cell-attached mode. The membrane potential was zeroed
with high potassium extracellular saline. In 16 of 55 patches recorded,
T-type unitary channel activities were elicited by repeated test steps
of 50 or 60 mV from holding potentials of 50-90 mV. The high
Ba2+ levels will screen surface charge on the
membrane; therefore, the absolute membrane potential experienced by the
channels is likely to be shifted to more negative potentials by as much
as 20-30 mV (Hille, 1992). Thus the test protocol is similar, but not
be exactly equivalent, to those used to evoke T-type currents in the
earlier whole-cell recordings performed with normal levels of divalent
cations. In eight patches located near the neuronal process, but not
the nucleus, quasi-macroscopic T-type currents were elicited by almost
every test pulse (Fig. 7A),
suggesting that these patches contained many T-type channels. In
patches from six neurons that had a large number of T-type channels,
the averaged currents were not modulated by 5-HT (Fig. 7B).
Given the reliability of the modulation of the whole-cell T-type
currents by 5-HT (nearly 90% of the cells responded to 5-HT), we would expect to see at least five of these patches being modulated if 5-HT
were acting via a freely diffusible second messenger pathway. The lack
of response therefore suggests that 5-HT cannot act via a freely
diffusible second messenger but may instead use a membrane-delimited pathway, such as direct modulation by G-proteins.
Fig. 7.
Effects of 5-HT on T-type unitary channel
recordings. A1, Consecutive
unitary T-type Ba2+ currents were elicited by steps
from potentials equivalent to the membrane potential of approximately
90 to 30 mV (after allowing for the screening effect of high
Ba2+ levels on membrane surface charge) in a
cell-attached patch. All traces are leak-subtracted.
A2, Average unitary T-type Ba2+ current record obtained by averaging of 50 consecutive recordings in the same patch. The solid line
is the best fit of the single exponential equation; time constant ( ) = 23.5 msec. B1, 5-HT (1 µM) did not modulate the average (50-100 consecutive
traces) unitary T-type Ba2+ currents recorded in
cell-attached patches. In Cell A there were no changes
in the T-type current. In Cell B, however, the averaged currents were reduced, but this did not reverse on washing, suggesting that the reduction may result from a "run down" of channel
activity. B2, Summary of the
effects of 5-HT (1 µM) on T-type unitary channel
recordings in six R-B neurons.
[View Larger Version of this Image (21K GIF file)]
5-HT did not change the kinetics of the T-type currents
We explored whether the inhibition of T-type channels by 5-HT
might be voltage-dependent. The amount of inhibition of T-type currents
remained constant from membrane potentials of 50 mV (mean inhibition
26.0 ± 4.2%, n = 4) to 20 mV (mean inhibition 25.2 ± 3.7). In five cells in which T-type tail currents were reduced, 5-HT did not change the voltage dependence of T-type current
activation (Fig. 8A).
Similarly, the voltage dependence of steady-state inactivation remained
unchanged (Fig. 8B). In six of six neurons, when the
reduced T-type currents were scaled up to the same magnitude as
control, the currents elicited by test potentials from 50 to 30 mV
in 5-HT overlapped with their corresponding control traces (Fig.
8C1). However, at membrane potentials
more positive than 30 mV at which the HVA currents start to develop,
the scaled traces did not overlap in three neurons (e.g., Fig.
5A). This probably was attributable to contamination of the
T-type currents by the HVA currents and was not seen in neurons that
had been pretreated with 1 µM -conotoxin-GVIA (data
not shown). This therefore suggests that 5-HT reduced the T-type
currents without altering the macroscopic kinetics. This was confirmed
by looking at the time course of inactivation at a range of voltages.
Once again 5-HT had no effect on the kinetics of inactivation (Fig.
8C). Thus, unlike most examples of G-protein-mediated modulation of HVA channels, serotonin reduced the T-type currents without significantly altering the voltage or time dependence of
channel gating.
Fig. 8.
5-HT did not alter the kinetic characteristics of
the whole-cell T-type calcium currents.
A1, Leak-subtracted T-type tail
currents (shown by arrow) were elicited by a series of
test pulses (80 to 20 mV in 5 mV steps) from a holding potential of
100 mV in control. A2, Summary
showing that 5-HT (1 µM) had no effect on the activation
of the T-type currents in five R-B neurons. The data were fit with the
Boltzmann relation (solid line):
I/Imax = {1 + exp[(V + V1/2)/K]}1.
Squares, Control (V1/2 = 37.2 mV; K = 7.6); filled
circles, 5-HT (1 µM)
(V1/2 = 38.8 mV;
K = 7.3).
B1, The T-type currents, measured
at the peak, undergo steady-state inactivation. B2, 5-HT (1 µM) had
no effect on the steady-state inactivation of the T-type currents in
four R-B neurons. The data were fit with the Boltzmann relation
(solid line). Squares, Control
(V1/2 = 74.7 mV;
K = 5.2); filled circles, 5-HT (1 µM) (V1/2 = 75.2 mV;
K = 5.4). C1,
Top left, T-type currents recorded in control and 1 µM 5-HT (shown by asterisk). Top
right, The T-type currents recorded in 5-HT were scaled up to
the same peak magnitude as control to show that the two traces overlap
almost completely. The time-dependent inactivation of the T-type
currents was measured by fitting with a single exponential
(solid line). C2, 5-HT (1 µM) had no effect on the time-dependent
inactivation in three R-B neurons. Squares, Control;
filled circles, 5-HT (1 µM).
[View Larger Version of this Image (17K GIF file)]
The reduction of T-type currents by serotonin increased R-B neuron
firing threshold
We next explored the function roles of the T-type currents
and the consequences of modulation of this current by 5-HT for sensory
transmission. The trivalent cations, Y3+,
La3+, and other lanthanides, have been reported to
block differentially the T-type and HVA Ca2+
channels. The smaller cations are more potent T-type antagonists, and
the IC50 for Y3+ blocking of T-type
channels is ~0.1 nM (Mlinar and Enyeart, 1993). We tested
the dose-response of Y3+ on T-type and HVA
currents. At doses of 10 nM or less, Y3+
could reversibly block the T-type currents while having no effect on
the HVA currents in R-B neurons (Fig.
9). We therefore used Y3+ (1-10 nM) as a selective T-type
channel blocker to test possible functional roles of T-type
currents.
Fig. 9.
Differential block of the T-type and HVA
Ca2+ currents by
Y3+ in R-B neurons. A,
Time series measurements in a R-B neuron showing the dose-response
for Y3+ on T-type currents
(A1) and HVA currents
(A2) recorded in the same neuron.
A3, Example of the HVA and T-type
currents recorded simultaneously in the same neuron, as shown in
A1 and
A2 (asterisks = 10 nM Y3+). B, Summary
of the effects of Y3+ (10 nM) on the
T-type currents and HVA currents (**p < 0.01 vs control).
[View Larger Version of this Image (23K GIF file)]
Under current clamp, R-B neurons were injected with repeated 5 msec depolarizing command currents (365.5 ± 15.9 pA at a resting potential of approximately 50 mV, n = 10) to evoke
repeated action potentials (Fig.
10A1).
To examine whether the T-type channels could be involved in setting
spike threshold, we carefully measured the threshold current that could
just evoke spikes in the R-B neurons and observed the effects of
Y3+ (1-10 nM) and 5-HT (10 nM) at this threshold level of current injection. This low
concentration of 5-HT greatly blocks the T-type current but has little
effect on the HVA current (compare Fig. 5A1 with 3C). At a resting
membrane potential of 48.5 ± 6.4 mV, n = 10, at
which T-type channels were inactivated (see Fig. 8B),
neither Y3+ nor 5-HT had any effects on the neuron
firing (Fig. 10B1). By
injecting a negative holding current (22.5 ± 4.2 pA,
n = 10), we set the membrane potentials of these
neurons to a more negative value of approximately 90 mV (90.5 ± 4.8 mV, n = 10). At these membrane potentials
Y3+ (10 nM) clearly reduced the R-B
neuron firing probability (Fig. 10B2,C), suggesting
that the T-type channels played a role in spike initiation. 5-HT also
reduced the probability of R-B neuron firing (Fig.
10B2,C). Therefore
modulation of T-type channels by 5-HT could increase the firing
threshold of R-B neuron and potentially modulate the sensitivity of
this sensory pathway.
Fig. 10.
Effects of the selective T-type
Ca2+ channel blockers and 5-HT on R-B neuron
firing. A1, Current-clamp
recording in a R-B neuron, using steps of current injection to detect
the threshold current that evoked an action potential.
A2, Y3+ (10 nM; asterisk), which selectively blocked
T-type currents, blocked the action potential evoked at threshold
current injection. B1,
Current-clamp recording from a R-B neuron showing that injection of
repeated current pulses just above the threshold caused reliable
firing. At resting membrane potentials more positive than 50 mV,
neither Y3+ (10 nM) nor 5-HT (10 nM) had any effects on neuron firing.
B2, At more negative resting
membrane potentials (90 mV), both Y3+ (10 nM) and 5-HT (10 nM) reversibly reduced the
probability of firing in the neuron. C, Summary of the
effects of Y3+ (10 nM) and 5-HT (10 nM) on the probability of R-B neuron firing in response to
repetitive threshold current injection at a resting membrane potential
of 90 mV, where the probability was measured as the number of pulses
that evoked a spike/total number of pulses during control, drug
treatment, and wash (**p < 0.01 vs control or
wash).
[View Larger Version of this Image (40K GIF file)]
DISCUSSION
The larva of the South African amphibian, Xenopus
laevis, is a simple model for studying the spinal mechanisms of
sensory modulation. Around the time of hatching, the spinal cord
contains only eight classes of differentiated neuron (Roberts and
Clarke, 1982). The trunk skin of the tadpole is innervated by the free nerve endings of a single, homogeneous population of mechanosensory afferents called Rohon-Beard neurons (Hughes, 1957). The R-B neurons are highly analogous to human C fibers. Like C fibers, R-B neurons are
unmyelinated and possess free nerve endings, use glutamate as a
transmitter (Sillar and Roberts, 1988) and substance P as a
cotransmitter (Clarke et al., 1984), and have capsaicin receptors (Kuenzi and Dale, 1996). The acutely isolated R-B neurons have a
distinctive morphology, maintain similar membrane properties to their
in vivo counterparts, and can be recognized easily in vitro (Dale, 1991). The R-B neurons therefore can be used as a highly advantageous model for studying the neuromodulation of sensory
pathways.
Identity of serotonergic receptors
We found that T-type currents were blocked by the
5-HT1A agonist 8-OH-DPAT and the 5-HT1D agonist
L-694,247. The IC50 values for both agonists were very
similar to those reported in mammals (Middlemiss and Fozard, 1983; Beer
et al., 1993). The effect of the 5-HT1A agonist was blocked
only by the 5-HT1A antagonist p-MPPI (Kung et
al., 1994), whereas the effect of L-694,247 was blocked only by the
5-HT1D antagonist GR127935 (Skingle et al., 1993). Therefore, these receptors have a very similar pharmacology to the
mammalian 5-HT1A and 5-HT1D receptors, and we
propose that they are the amphibian equivalents of these receptors.
5-HT1A receptors have been described previously in
amphibian spinal cord (Holohean et al., 1992; Tan and Miletic, 1992).
The 5-HT1A receptor can inhibit Ca2+
entry through HVA channels into afferent terminals of nociceptors in
mammalian spinal cord (Del Mar et al., 1994). 5-HT1A
receptors also have been reported to be involved in the
voltage-dependent G-protein-coupled inhibition of the HVA currents in
other CNS neurons (Pennington et al., 1991; Koike et al., 1994; Bayliss et al., 1995; Foehring, 1996). Unlike these previous reports, the
inhibition of the HVA currents by 5-HT1A receptors in
Xenopus R-B neurons is not voltage-dependent.
5-HT1D receptors have been found mostly in the
mammalian brain and in pigeon (Bruinvels et., 1992; Hoyer et al., 1992)
(for review, see Waeber and Palacios, 1990) but not yet in the
amphibian nervous system. 5-HT1D receptors seem to exist in
those species in which the 5-HT1B receptor is absent and
may play a role in these species equivalent to that of the
5-HT1B receptor in rat and mouse (for review, see Zifa and
Fillion, 1992). Our findings that 5-HT1D receptors are
present in Xenopus are the first to suggest that
5-HT1D receptors exist in the amphibian nervous system and
are consistent with previous reports that the 5-HT1B
receptors are absent in frog (for review, see Zifa and Fillion,
1992).
The 5-HT1D receptor inhibits synaptic transmission
(Jones et al., 1995) and acts as an autoreceptor in the mammalian raphe nucleus (Davidson and Stamford, 1995). The actions of
5-HT1D receptor on Ca2+ currents and its
role in the sensory transmission have not been reported; therefore, our
results are the first to show that 5-HT1D receptors also
are involved in limiting sensory transmission by inhibiting T-type and
HVA Ca2+ channels. In the Xenopus spinal
cord 5-HT1D receptors also are found in a class of
glycinergic inhibitory premotor interneurons (Q. Q. Sun and N. Dale, unpublished results) that contribute to the control of locomotion
in Xenopus. Therefore, the 5-HT1D receptor may
play a important role both in the descending supraspinal control of
sensory transmission and in the regulation of locomotion patterns in
Xenopus.
Modulation of the T-type currents
Although some neurotransmitters have been documented to
inhibit T-type currents, presumably via G-protein-mediated processes (Formenti and Sansone, 1991), serotonin has been reported to enhance rather than inhibit T-type currents in CNS neurons (Berger and Takahashi, 1990; Fraser and MacVicar, 1991). In contrast to this, we
found that serotonin reversibly inhibited T-type currents in R-B
neurons.
5-HT has been reported previously to mediate presynaptic
inhibition of transmitter release from R-B neurons in
Xenopus (Sillar and Simmers, 1994). However, T-type channels
generally are not thought to be involved in supporting synaptic
transmission. The modulation of T-type currents therefore suggests an
additional and important locus of modulation: initiation of R-B neuron
discharge in response to sensory stimuli. R-B neurons have a very
negative resting potential (approximately 90 mV; Spitzer and
Lamborghini, 1976), so the T-type calcium current is unlikely to be in
an inactivated state in these neurons at rest. Because the T-type
currents are the only voltage-gated inward currents activated in these
neurons between 60 and 30 mV, they may play an important role in
triggering action potentials. Small reductions of the T-type calcium
current therefore could modulate the responsiveness of Rohon-Beard
neuron to sensory stimuli. We found that both selective T-type channel blockers and low doses of 5-HT greatly reduced the probability of R-B
neuron firing in response to threshold current injection at resting
membrane potentials of 90 mV but not at more positive membrane
potentials of 50 mV at which the T-type channels were inactivated.
This strongly supports our hypothesis that T-type channels play a role
in the spike initiation in R-B neurons and that the modulation of
T-type channels may raise the R-B firing threshold. We also found that
the T-type currents were much more sensitive to serotonin agonists
(IC50 = 0.1 nM for 5-HT) than HVA currents
(IC50 = 40 nM for 5-HT). During 5-HT release
the T-type channels are thus likely to be modulated first when the concentrations of 5-HT are low. In our cell-attached recordings we
found that in patches located near the neuronal process, but not the
nucleus, quasi-macroscopic T-type can be elicited. The most effective
locus for the T-type channels to influence spike initiation would be in
the peripheral neurites close to the site of mechanotransduction. We
therefore propose that both the 5-HT receptors and T-type channels are
in the peripheral neurites and that modulation of these channels alters
the sensitivity of the sensory pathway.
Modulation of the N- and P/Q-type HVA
Ca2+ currents
5-HT inhibits N- and P/Q-type HVA calcium currents in neocortical
pyramidal neurons (Foehring, 1996), in rat motor neurons (Bayliss,
1995), or N-type currents in sensory neurons (Del Mar et al., 1994) and
other CNS neurons (Pennington et al., 1991; Koike et al., 1994).
Consistent with these reports, our results showed that N- and P/Q-type
HVA Ca2+ current was inhibited by 5-HT in R-B
neurons.
N- and P/Q-type calcium channels are involved in supporting synaptic
transmission in the CNS and peripheral nervous systems (Luebke et
al., 1993; Luebke and Dunlap, 1994; Wall and Dale, 1994; Wheeler et
al., 1994) (for review, see Dunlap, 1997). Therefore, the reduction of
N- and P-type currents could contribute to the previously reported
presynaptic inhibition of transmitter release from R-B neurons (Sillar
and Simmers, 1994).
The modulation of N-type and P/Q-type currents in R-B neurons was not
accompanied with slowing of activation and was voltage-independent, which is different from most of the examples of G-protein-mediated modulation (for review, see Hille, 1994; Wickman and Clapham, 1995) in
which a kinetic-slowing is always accompanied with the reduction of HVA
currents. The difference in voltage dependence for modulatory
components may have different functional implications under various
physiological conditions. The voltage-dependent modulation, which can
be removed by preceding stimulation, would be phasic in nature, whereas
the voltage-independent modulation would persist under conditions of
repetitive firing.
Distinctive biochemical pathways may underlie the modulation of
T-type and HVA currents
In R-B neurons both HVA and T-type currents were inhibited by
5-HT in a voltage-independent manner via the same receptors. However,
the modulation of T-type channels differed from the HVA channels in
that it had ~100 times greater sensitivity to 5-HT and that the time
course for wash was twice as fast. These differences may reflect the
involvement of distinctive biochemical mechanisms. Our results suggest
that the reduction of T-type currents occurred through a
membrane-delimited pathway, possibly a direct G-protein-channel interaction. In the mammalian CNS the most common signal transduction pathway for the modulation of N- and P/Q- channels is via a
voltage-dependent interaction between the calcium channels and the
G-protein   subunits (Ikeda, 1996; Waard et al., 1997) (for
review, see Dunlap, 1997). However, in those cases in which the
modulation is voltage-independent, it may be mediated by protein kinase
C (Diverse-Pierluissi et al., 1995). Further studies to address the
participation of various signal transduction pathways, such as whether
the G-proteins involved are PTX-sensitive and if cAMP/PKA or PKC is
involved in the modulation, certainly will be very useful.
FOOTNOTES
Received April 30, 1997; revised June 17, 1997; accepted June 26, 1997.
We are grateful to the Royal Society (UK) for generous support and to
the Committee of Vice Chancellors and Principals for an Overseas
Research Studentship award to Q.Q.S. We also thank Dr. F. M. Kuenzi for helpful comments on an earlier version of this paper and
GlaxoWellcome for the kind gift of GR127935.
Correspondence should be addressed to Dr. Nicholas Dale at the above
address.
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