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The Journal of Neuroscience, June 1, 2000, 20(11):4217-4225
Role and Origin of the GABAergic Innervation of Dorsal Raphe
Serotonergic Neurons
Damien
Gervasoni1,
Christelle
Peyron1,
Claire
Rampon1,
Bruno
Barbagli1,
Guy
Chouvet2,
Nadia
Urbain2,
Patrice
Fort1, and
Pierre-Hervé
Luppi1
1 Institut National de la Santé et de la
Recherche Médicale (INSERM) U480, 2 INSERM U512,
Université Claude Bernard Lyon I, 69373 Lyon cedex 08, France
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ABSTRACT |
Extracellular electrophysiological recordings in freely moving cats
have shown that serotonergic neurons from the dorsal raphe nucleus
(DRN) fire tonically during wakefulness, decrease their activity during
slow wave sleep (SWS), and are nearly quiescent during paradoxical
sleep (PS). The mechanisms at the origin of the modulation of activity
of these neurons are still unknown. Here, we show in the unanesthetized
rat that the iontophoretic application of the GABAA
antagonist bicuculline on dorsal raphe serotonergic neurons induces a
tonic discharge during SWS and PS and an increase of discharge rate
during quiet waking. These data strongly suggest that an increase of a
GABAergic inhibitory tone present during wakefulness is responsible for
the decrease of activity of the dorsal raphe serotonergic cells during
slow wave and paradoxical sleep. In addition, by combining retrograde tracing with cholera toxin B subunit and glutamic acid decarboxylase immunohistochemistry, we demonstrate that the GABAergic innervation of
the dorsal raphe nucleus arises from multiple distant sources and not
only from interneurons as classically accepted. Among these afferents,
GABAergic neurons located in the lateral preoptic area and the pontine
ventral periaqueductal gray including the DRN itself could be
responsible for the reduction of activity of the serotonergic neurons
of the dorsal raphe nucleus during slow wave and paradoxical sleep, respectively.
Key words:
dorsal raphe; GABA; serotonin; single-unit recordings; retrograde tracing; sleep-waking
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INTRODUCTION |
In the mammalian CNS, most of the
serotonergic neurons are found within the dorsal raphe nucleus (DRN)
(Dahlström and Fuxe, 1964 ). By means of their widespread
projections throughout the entire brain, these neurons are thought to
play a crucial role in various physiological and behavioral functions,
including sleep (Jouvet, 1972; Jacobs et al., 1990; Jacobs and Azmitia,
1992). Accordingly, extracellular electrophysiological recordings in freely moving cats have shown that DRN serotonergic neurons fire tonically during wakefulness (W), decrease their activity during slow
wave sleep (SWS), and are nearly quiescent during paradoxical sleep
(PS) (PS-off cells) (McGinty and Harper, 1976; Trulson and Jacobs, 1979). The decrease of activity of these neurons during SWS or
PS could be caused by a tonic GABAergic inhibition. Indeed, it has been
shown that GABA-immunoreactive terminals contact serotonin-positive neurons in the rat DRN (Wang et al., 1992) that also express
GABAA receptors (Gao et al., 1993). Moreover,
iontophoretic application of GABA in anesthetized rats strongly
inhibits DRN serotonergic neurons, and co-iontophoresis of the
GABAA antagonists bicuculline or picrotoxin
antagonizes this effect (Gallager and Aghajanian, 1976; Gallager,
1978). Furthermore, GABA-mediated IPSPs observed in vitro in
DRN serotonergic cells using focal stimulation are blocked by
bicuculline applications (Pan and Williams, 1989). In addition, Levine
and Jacobs (1992) showed in cats that the iontophoretic application of
bicuculline reverses the typical suppression of DRN serotonergic
neurons activity seen during SWS but has no effect on maintained
activity during W and the suppression of activity occurring during PS.
More recently, Nitz and Siegel (1997) in cats using the in
vivo microdialysis technique found that GABA levels are similar
during W and SWS and that PS is accompanied by a selective increase in
GABA release. To explain the discrepancies between the two studies,
Nitz and Siegel (1997) hypothesized that (1) a small increase in GABA
release, possibly beyond the resolution of the microdialysis technique,
might be sufficient to reduce DRN unit discharge during SWS and (2) the
inability of iontophoresed bicuculline to reverse PS cessation of DRN
unit discharge could be caused by incomplete antagonism of DRN
GABAA receptors as a result of increased GABA
release. Therefore, to determine whether GABA plays a role in the
decrease of activity of serotonergic cells of the DRN during SWS and
PS, we tested in unanesthetized rats the effect of iontophoretic
applications of bicuculline on these neurons during SWS, PS, and W. Furthermore, to localize candidate GABAergic neurons potentially
responsible for the inhibitions found, we then combined injections of
the retrograde tracer cholera-toxin B subunit (CTb) in the DRN with the
immunohistochemistry of glutamic acid decarboxylase (GAD, GABA enzyme
of synthesis).
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MATERIALS AND METHODS |
Electrophysiology
Fixation of the head-restraining system. The
procedure used has been described previously (Darracq et al., 1996;
Gervasoni et al., 1998). Male Sprague Dawley rats (280-320 gm,
n = 15; IFFA Credo) were anesthetized with
pentobarbital (45 mg/kg, i.p.) and mounted conventionally in a
stereotaxic frame (David Kopf), i.e., with ears and nose bars. The bone
was exposed and cleaned. The skull was placed at a 15° angle (nose
tilted down) to spare the transverse sinus overlying the DRN during the
subsequent electrode penetrations. Three stainless steel screws were
fixed in the parietal and frontal parts of the skull and three steel
electrodes were inserted into the neck muscles to monitor the
electroencephalogram (EEG) and the electromyogram (EMG), respectively.
The bone was then covered with a thin layer of acrylic cement
(Superbond, Sun Medical Co.), except the region overlying the
DRN and the lambdoid suture. At this time, the head-restraining system
was put in place. It consists of a "U"-shaped piece of aluminum
with four bolts in each angle cemented to the skull of the rat that can
be easily fixed to a flexible carriage, itself fastened to a commercial stereotaxic apparatus with dummy ear bars. This device allows a
painless stereotaxic restraint with a high mechanical stability. The U
piece fixed to the carriage with four nuts was centered above the DRN
entry region and embedded in a mount of dental cement with the EEG
screws and wires and their six-pin connector. After the dental cement
dried out, the four bolts were then unscrewed from the U, now firmly
jointed to the rat's skull. The animal was removed from the
stereotaxic apparatus and allowed to recover from surgery and
anesthesia during a period of 48 hr, before the habituation began. The
head restraining system (5 gm weight) was well tolerated by the rats
that were able to feed and drink normally.
Training and habituation. During 8-10 successive days,
repetitive trials of increasing duration were performed to well
habituate the rats to the restraining and recording systems. The rat
was comfortably supported by a hammock with the head painlessly secured to the restraining frame. At the end of the training period, the rat
could stay calm for periods of 5-7 hr during which quiet W, SWS, and
PS could be observed. The day before the first recording session, under
pentobarbital anesthesia, a 4 mm hole was made above the DRN and the
dura was removed under microscopic control. The brain surface was
cleaned at the beginning of each daily recording session under local
lidocaine anesthesia. All animals were housed and cared for
according to the National Institutes of Health (NIH) Guide for
the Care and Use of Laboratory Animals (NIH Publication 80-23).
The protocol of this study has been approved by our local ethical
committee and the French Ministry of Agriculture (Authorization 03-505), and efforts were made to reduce the number of animals used.
Polygraphic recordings. Vigilance states were discriminated
with the cortical EEG and neck EMG. During W, desynchronized (or activated) low-amplitude EEG was accompanied by a sustained EMG activity with phasic bursts (twitches). SWS was clearly distinguished by high-voltage slow waves (1.5-4.0 Hz) and spindles (10-14 Hz) and
disappearance of phasic muscular activity in an immobile animal with
closed eyes. A decrease in the EEG amplitude associated with a flat EMG
(i.e., muscle atonia) signaled the onset of PS episodes further
characterized by a pronounced theta rhythm (5-9 Hz). For each
vigilance state, a spectral analysis of the EEG was made on-line using
the Fast-Fourier Transform.
Micropharmacology. Extracellular recordings from individual
DRN neurons were obtained with glass microelectrodes (3-5 µm tip diameter, 10-20 M , impedance measured at 10 Hz) filled with 2% (w/v) Pontamine Sky Blue (PSB) in 0.5 M sodium acetate
solution and connected to a preamplifier (P16, Grass). Single-unit
activity was visualized (signal-to-noise ratio of at least 3:1) on a
digital storage oscilloscope (2211 Tektronix) as filtered (AC, bandpass 0.3-10 kHz) and unfiltered signals (DC) and listened to with an audiomonitor (AM8, Grass). The AC trace was used for the on-line count
of action potentials with an amplitude-sensitive spike discriminator (Neurolog Spike Trigger, Digitimer Ltd.). The unfiltered signal was
used for on-line identification of the recorded neurons (spike shape
and duration) and qualitative observations of possible alterations of
spike waveform during pharmacological effects. Discriminator output
pulses, analog signals proportional to the magnitudes of iontophoretic
currents, as well as EEG and EMG recordings were collected on a
computer via a CED interface using the Spike 2 software (Cambridge
Electronic Design). To combine DRN single-unit recordings with
microiontophoresis, a four-barrel micropipette (10-15 µm tip
diameter) glued alongside the recording micropipette was used, as
described previously (Akaoka et al., 1992). Each barrel was filled with
one of the following solutions:
8-hydroxy-2-(Di-n-propylamino)-tetralin (8OH-DPAT, 10 mM, pH 4; Sigma, L'Isle d'Abeau Chesnes,
France), GABA (400 mM, pH 4; Sigma), bicuculline
methiodide (25 mM, pH 4; Sigma), and NaCl 0.9%
(all drugs were dissolved in distilled water). Small negative retention
currents (2-5 nA) were used to avoid leakage of the active substances
by diffusion. Current balancing techniques and current tests (Stone,
1985) were routinely performed via the saline-containing barrel. Dorsal
raphe serotonergic neurons were first localized using the DRN
stereotaxic coordinates. The micropipettes with a 15° caudorostral
inclination were placed on the brain surface 4 mm posterior to the
lambda, 0-0.4 mm lateral to the midline. DRN neurons were found
5800-6000 µm below the brain surface. Neurons were identified as
serotonergic if they met the criteria defined previously by McGinty and
Harper (1976), Trulson and Jacobs (1979), and Levine and Jacobs (1992):
i.e., (1) a slow and regular activity during quiet waking (1-4 Hz), (2) long-duration action potential (>2 msec), (3) changes in activity directly correlated with changes in behavioral state, and (4) subsequent histological localization in the DRN.
Iontophoretic studies were conducted as follows. When a DRN unit was
found, computer data collection was started, and a period of at least 2 min of spontaneous discharge was acquired before any drug application.
For each neuron, one iontophoretic application of bicuculline (range
30-150 nA, 19-130 sec) was made. Bicuculline ejection was stopped at
the beginning of the increase in firing judged by listening to the cell
discharge and the increase of the impulse activity on the computer
record. In some neurons, GABA was applied in a cyclic way using
short-duration pulses (3-5 sec). At the end of four to five
consecutive daily recording sessions (4-6 hr each) on the same animal,
PSB was deposited by iontophoresis in the same location as the last
studied neurons (50% duty cycle for 10 min,  10 µA). The PSB
deposit was then localized on 25 µm sections obtained with a cryostat
and stained with neutral red. In all rats, the PSB deposit was
localized in the DRN, and no trace of the numerous tracks made with the
micropipettes during the recording sessions was visible.
Data analysis. The firing rate of DRN neurons was analyzed
off-line using Spike 2 software. All spike counts were taken from computer records of integrated impulse activity (1 sec bin width). Basal and post-drug firing rates were compared for periods matching for
an equivalent behavioral state using polygraphic criteria and EEG
spectral analysis. For each cell, the mean and SDs of basal firing rate
were determined by averaging spike counts made for at least three
separate 10 sec epochs in one given vigilance state before bicuculline
ejection. After the application of bicuculline, the discharge rate of
the neurons quickly increased and then remained at an elevated stable
value (plateau). The firing rate of the neurons during the effect was
measured during the plateau phase. The onset of the plateau (latency,
seconds) was defined as the time interval between the onset of the
bicuculline application and the moment at which mean discharge value
exceeded mean baseline activity by two SDs. The recovery time was
defined as the time-interval between the offset of the ejection and the
moment at which the firing rate had returned to a stationary level
within two SDs of the baseline.
In a first group of neurons, the effect of bicuculline occurred during
a continuous period of one of the three vigilance states. The mean
discharge rate and SEM of these neurons in control conditions and under
the bicuculline-induced plateau was calculated and compared using ANOVA
and post hoc tests with the vigilance state as a factor. To
take into account all variables, a multiple regression analysis (general linear model, Systat Software, SPSS) was performed with the bicuculline-induced increase of discharge, the latency or the
recovery time as dependent variable, and the independent variables being either quantitative (intensity and duration of bicuculline applications) or qualitative (vigilance state).
For two other groups of neurons, the animals either displayed short
successive periods of W and SWS (W-SWS transitions) or awoke from PS
(PS-W transitions) during the plateau effect of bicuculline as defined
above. For each of these neurons, we thus considered basal and plateau
discharge rates for two behavioral states. The mean basal firing rate
was calculated with the same method as for the first group (see above).
The firing rate during the plateau effect of bicuculline was then
calculated during periods of the same duration of either W and SWS or
PS and W. The basal and post-drug mean firing rates during W and SWS on
the one hand and PS and W on the other hand were then compared using
ANOVA for repeated measures followed by Tukey's test for post
hoc comparisons. The significance level for all statistical
analyses was set at p < 0.05. All data are expressed
as mean ± SEM.
Retrograde tracing and immunohistochemistry of GAD
The experimental protocol of the tract-tracing method has been
described in detail in our previous papers (Luppi et al., 1990; Peyron
et al., 1996, 1998). Briefly, male rats (n = 10, 260-310 gm) were deeply anesthetized. A glass micropipette (3-5 µm
tip diameter) filled with 1% CTb (List Biological Laboratories,
Campbell, CA) solution [0.1 M phosphate buffer
(PB), pH 6] was lowered into the DRN according to stereotaxic
coordinates and extracellular recordings of the activity of
serotonergic neurons (Aghajanian et al., 1972; Sprouse and Aghajanian,
1986). Then, the tracer was ejected iontophoretically by a 0.5-1.0
µA pulsed positive current during a period of 10 min. Five days
later, 80 µg of colchicine (Sigma) in 4 µl of NaCl 0.9% was
injected with a Hamilton syringe in one lateral ventricle. After 2 d, the animals were perfused with a Ringer's lactate solution
containing 0.1% heparine, followed by 500 ml of a fixative composed of
4% paraformaldehyde and 0.2% picric acid in PB, pH 7.4. The brains
were post-fixed for 2 hr in the same fixative at 4°C.
Coronal sections (20 µm) were then successively incubated in (1) a
goat antiserum to CTb (1:40,000 with 2% BSA; List Biological) over
3-4 d at 4°C; (2) a biotinylated rabbit anti-goat IgG (1:2000; Vector Laboratories, Burlingame, CA) for 90 min at room temperature; and (3) an ABC-HRP solution (1:1000; Elite kit, Vector) for 90 min at
room temperature. Then, the sections were immersed in a 0.05 M Tris-HCl buffer, pH 7.6, containing 0.025%
3,3'-diaminobenzidine-4 HCl (DAB; Sigma), 0.003%
H2O2, and 0.6% nickel
ammonium sulfate for 15 min at room temperature. These CTb-stained
sections were further incubated in (1) a 3% swine serum for 90 min
(Life Technologies, Rockville, MD), (2) a rabbit antiserum to GAD with
1% of swine serum over 3-4 d at 4°C (1:10,000; Chemicon
International, Temecula, CA), (3) a donkey biotinylated anti-rabbit IgG
(1:1000; Vector); and (4) ABC-HRP (1:1000; Elite kit, Vector), both
for 90 min at room temperature. Finally, the sections were immersed for
15 min at room temperature in the same DAB solution as above without nickel. All incubations and rinses were made in KPBS 0.02 M
at pH 7.4 except for the DAB. Controls in the absence of CTb or GAD antibodies and in the presence of BSA or swine serum, respectively, were routinely performed. On sections submitted to the double immunohistochemical procedure without the presence of CTb antiserum, no
blue-black granular reaction product was visible, whereas on sections
incubated without the GAD antibody, neurons with a cytoplasm labeled in
brown could not be identified. Further supporting the specificity of
our GAD immunostaining, singly CTb-labeled neurons did not display a
brown coloration on double-stained sections, and the global
distribution and the number of GAD-immunoreactive neurons were in line
with previous studies (Mugnaini and Oertel, 1985; Ford et al., 1995).
Section drawings were made with a Leitz Orthoplan microscope equipped
with an X/Y sensitive stage and a video camera connected to a
computerized image analysis system (Biocom, Lyon, France). To precisely
determine the respective contribution of each afferent to the GABAergic
innervation of the DRN, we plotted and counted in three rats
bilaterally retrogradely labeled (CTb+) and double-labeled (CTb+/GAD+)
cells on one section for each afferent structure. Numbers given in the
text correspond to the mean number of CTb+/GAD+ versus CTb+ cells on
one side of a section for a given structure.
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RESULTS |
Neurochemical nature of the recorded neurons
The single-unit activity of 85 neurons (from 15 rats) was studied
during the iontophoretic application of bicuculline. These neurons were
considered as being serotonergic neurons from the DRN based on the
following criteria: (1) their long-duration action potential (>2
msec), (2) a tonic discharge during W (1.56 ± 0.06 Hz) and a
decrease of activity during SWS (0.50 ± 0.05 Hz) (Fig. 1), and (3) subsequent localization in
the DRN by the PSB deposit. The PSB deposit made in the recording site
for each rat the last day of recordings was in all cases localized in
the DRN (Fig. 2).
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Figure 1.
Illustration of the activity of
a DRN neuron during quiet waking
(W), slow-wave sleep
(SWS), and paradoxical sleep (PS).
A, The electromyogram (EMG), the
electroencephalogram (EEG), the unit activity of the
neuron, and its integrated firing rate (in Hertz) are displayed. Each
vigilance state is discriminated with the EMG, the EEG, and its power
spectrum (B-D) in the low-frequency range
(1.5-19 Hz), and the high- frequency range (19.5-50 Hz)
shown at higher gain. During W (characterized by a
low-amplitude EEG and a sustained EMG activity with phasic
bursts), the DRN neuron discharges tonically at 1.6 Hz. During SWS
[characterized by high-voltage spindles (10-14 Hz) and delta
waves (1.5-4.0 Hz) on the EEG and a low muscular activity], the DRN
neuron progressively decreases its firing rate to 0.3 Hz. During the
subsequent PS episode [characterized by a desynchronized
(activated) low-amplitude EEG with theta waves (5-9 Hz) and a flat
EMG], the DRN neuron is virtually silent (0.02 Hz).
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Figure 2.
A, Effect of
iontophoretic pulses (50 nA, for 4 sec every 14 sec) of 8OH-DPAT (a
5HT1A receptor agonist) on a DRN neuron during W. The tonic
activity of this neuron (1.8 Hz) is completely
inhibited by 8OH-DPAT applications. This result strongly
suggests that the recorded neuron is serotonergic. B,
Photomicrograph illustrating a small PSB deposit localized in
the center of the DRN on a frontal section counterstained with neutral
red. The PSB was iontophoretically applied (10 µA, 10 min) in the site in which neurons were recorded during
the last day of experiments. It must be also noted that no lesion is
visible in the DRN despite the multiple penetrations of the pipette
assembly.
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In addition, 21 of these neurons (from eight rats) were recorded during
a PS episode. They presented a mean discharge rate of 0.09 ± 0.01 Hz during PS.
Thus, the neurons recorded in this study showed the same pattern of
discharge across the sleep-waking cycle as that of DRN serotonergic
neurons in cats (McGinty and Harper, 1976; Trulson and Jacobs, 1979;
Levine and Jacobs, 1992).
The effect of an iontophoretically applied 5HT1A
receptor agonist (8OH-DPAT) on neuronal activity during quiet W was
also investigated on 37 of the recorded neurons (from 12 rats). The activity of all of these neurons was completely suppressed by 8OH-DPAT
with ejection current of 40-65 nA during 4-5 sec (Fig. 2). The
suppression of activity lasted for 5.4 ± 0.9 sec. These results
are similar to those reported for serotonergic neurons from the DRN
recorded in anesthetized rats (Aghajanian et al., 1972; Sprouse and
Aghajanian, 1986). Altogether, these results strongly support the
serotonergic identity of the neurons recorded in the present study.
Effect of GABA and bicuculline on DRN serotonergic neurons
Iontophoretic applications of GABA were performed on 24 DRN
serotonergic neurons (recorded from 11 animals) during quiet W. Applications of GABA (30-60 nA, 3-5 sec) on these neurons completely inhibited their spontaneous activity. The application of bicuculline (60-100 nA, 22-94 sec) before GABA applications completely blocked the GABA-induced inhibitions on all neurons recorded (Fig.
3).
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Figure 3.
Effect of an iontophoretic application of
bicuculline on a DRN serotonergic cell during successive short periods
of W (microarousals) and SWS. In baseline conditions, the DRN neuron
discharges at 0.3 Hz during SWS and 2.0 Hz during the first
microarousal (at 240 sec). Forty-five seconds (at 278 sec) after the
onset of the bicuculline application (100 nA, 59 sec), the neuron
increases its discharge rate. Note that during the effect, the
discharge rate of the neuron is similar during the short period of W
(4.9 Hz) (at 300 sec) and the subsequent SWS (4.8 Hz). This indicates
that GABA is responsible for the decrease of activity of the DRN
serotonergic cells during SWS. The application of GABA (50 nA, for 4 sec every 14 sec) induced a complete cessation or a decrease of
activity of the neuron before and during the beginning of the
bicuculline application (up to 260 sec). During the remaining time of
the application of bicuculline and up to 40 sec after its cessation,
GABA is no longer effective to induce an inhibition. The ability of
GABA to decrease the firing of the cell reappeared at 356 sec.
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Effect of bicuculline applications during W, SWS, or PS on DRN
serotonergic neurons
In a first group of 66 neurons, the effect of bicuculline occurred
during one of the three vigilance states (Table
1). Iontophoretic application of
bicuculline during W, SWS, or PS induced a progressive and sustained
increase of the discharge rate of DRN neurons without inducing a change
in the vigilance state. The firing rate significantly increased from
1.56 ± 0.13 to a plateau rate of 4.43 ± 0.42 Hz (p < 0.001, Tukey's post hoc test)
during quiet W (n = 19 neurons from eight animals) and
from 0.57 ± 0.08 to 4.14 ± 0.48 Hz during SWS
(p < 0.001) (n = 34 neurons
from nine animals). During PS, while DRN neurons were practically
silent (0.06 ± 0.03 Hz), they showed a remarkable increase of the
firing rate to a plateau of 4.22 ± 0.73 Hz
(p < 0.001) (n = 13 neurons
from eight animals) after bicuculline application (Fig.
4). The latency for the appearance of the
effect was of 58.61 ± 6.31 sec during W, 60.71 ± 4.74 sec during SWS, and 64.83 ± 9.76 sec during PS. The recovery time was
79.12 ± 9.0 sec for neurons recorded during W, 55.07 ± 7.89 sec for SWS neurons, and 30.83 ± 7.21 sec for neurons recorded during PS. Multiple linear regression analysis showed that the increased firing rate under bicuculline, the latency, and the recovery
time were not statistically different between the three vigilance
states (p > 0.05).
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Table 1.
Firing rates of DRN serotonergic neurons recorded in
control conditions and during the effect of bicuculline
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Figure 4.
Effect of an iontophoretic application of
bicuculline on a DRN serotonergic cell during PS. In control
conditions, the DRN neuron does not discharge during PS (100-120 sec).
Thirty seconds after the onset of the bicuculline application (70 nA,
42 sec), the neuron increased its discharge rate to a mean frequency of
3.6 Hz. The effect lasted 43 sec and disappeared 31 sec after the end
of the bicuculline application. Note that the PS period is not
disrupted by the application of bicuculline.
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In a second group of 13 neurons (from five rats), the animals
successively displayed short periods of W (microarousals) and SWS in
control conditions and during the plateau effect of bicuculline. Although under control conditions these DRN neurons presented a
statistically significant decrease (p < 0.001)
in discharge rate during SWS (0.58 ± 0.07 Hz) compared with
microarousals (1.53 ± 0.13 Hz), they showed under bicuculline
virtually the same plateau rate during SWS and microarousals (4.55 ± 0.38 and 4.74 ± 0.38 Hz, respectively)
(p = 0.64, Tukey's post hoc test)
(Fig. 3).
In a third group of eight neurons (from four rats), the animals awoke
from PS during the maximal effect of bicuculline. In baseline
conditions, these neurons were nearly silent during PS (0.08 ± 0.05 Hz) and had a tonic discharge rate during quiet W (1.15 ± 0.27 Hz) (p < 0.001). Under bicuculline (Fig.
5), their discharge rate was not
significantly different between PS (4.65 ± 1.18 Hz) and the
subsequent awakening (4.93 ± 0.91 Hz) (p = 0.85, Tukey's post hoc test).
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Figure 5.
Effect of an iontophoretic application of
bicuculline (50 nA, 38 sec) on a DRN neuron during a transition from PS
to W. The effect of bicuculline started 28 sec after the onset of the
application (at 50 sec) and ceased 31 sec after its offset. In control
conditions, this DRN neuron fired at 1.3 Hz during W and was silent
during PS. In contrast, under bicuculline, it presented a strong tonic
discharge rate of similar value (3.8 Hz) during PS and the subsequent
W. This result strongly suggests that the decrease of activity of DRN
neurons during PS is mediated by GABA.
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Finally, it should be noted that applications of 50-150 nA current
(25-73 sec) via the saline-filled barrel (current test) did not affect
the spontaneous activity of DRN neurons whatever the vigilance state
(n = 10 neurons from seven rats). In addition, in all
cases the waveform characteristics of the recorded spikes were not
modified during the application of bicuculline (Fig. 6).
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Figure 6.
Raw electrophysiological waveforms of action
potentials of a DRN neuron in control conditions and during the effect
of an iontophoretic application of bicuculline (70 nA, 56 sec). The
filtered (top traces, bandpass 0.3-3 kHz on Grass P16
amplifier) as well as nonfiltered (bottom traces) traces
clearly show the high signal-to-noise ratio of our recordings. The
action potential is not significantly affected during the bicuculline
effect, therefore ruling out possible artifacts. Note also the long
duration of the action potentials typical of serotonergic
neurons.
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Origin of the GABAergic innervation of the DRN
After CTb injections restricted to the DRN (Fig.
7A), the distribution of the
retrogradely labeled cells was in agreement with our previous reports
(Peyron et al., 1996, 1998). The largest number of retrogradely labeled
cells immunoreactive to GAD (CTb+/GAD+ cells) was found in the lateral
hypothalamic area (rostral part, 16 CTb+/GAD+ cells/32 CTb cells per
section on one side, caudal part, 20/67) (Figs. 7C,
8B). A substantial number of double-labeled cells was
also observed in the lateral preoptic area (13/50) (Figs. 7B, 8A), the posterior hypothalamic area
(13/45), the substantia nigra reticular part (7/12 rostrally and 13/33
caudally), the ventral tegmental area (7/12) (Fig.
8C), the ventral pontine
periaqueductal gray (Fig. 7D) including the DRN itself (5/27
rostrally and 10/28 caudally), and the rostral oral pontine reticular
nucleus (7/38) (Fig. 8D). A moderate number of
double-labeled cells was seen in the ventral pallidum (4/10), the
medial preoptic nucleus (5/9), the lateral parabrachial nucleus (3/23)
(Fig. 8E), and the dorsal paragigantocellular nucleus
(3/7) (Fig. 8F). Finally, a small number of CTb+/GAD+
neurons was seen in the magnocellular preoptic nucleus (2/5), the
paraventricular hypothalamic nucleus (2/4), the lateral habenula
(2/16), the tuberomamillary nucleus (1/1), and the raphe magnus and
gigantocellular  nuclei (1/2) (Fig. 8F).
View larger version (150K):
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Figure 7.
A, Photomicrograph illustrating a small CTb
injection site limited to the ventral part of the DRN. Scale bar, 300 µm. B-D, Photomicrographs showing GAD
(light brown) and CTb (black granules)
double-labeled neurons (arrow), singly labeled
GAD immunoreactive neurons, and singly CTb-labeled neurons
(double arrow) in the lateral preoptic area
(B), the lateral hypothalamic area
(C), and the ventral periaqueductal gray
(D) after a CTb injection in the DRN. Scale bars,
25 µm. Note that the singly CTb-labeled cells display no brown
coloration, indicating the absence of cross-reactivity between our two
immunohistochemical reactions.
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Figure 8.
Schematic representation of the GABAergic
afferents to the DRN from rostral to caudal levels. Drawings of 20 µm
frontal sections are shown. Each point corresponds to a
retrogradely labeled cell (CTb+), and each star
corresponds to a double-labeled cell (CTb+/GAD+). 3,
Oculomotor nucleus; 7, facial nucleus;
3V, third ventricle; Arc, arcuate
nucleus; ATg, anterior tegmental nucleus;
Aq, aqueduct; BSTM, bed nucleus of the
stria terminalis, medial division; CIC, central nucleus
of the inferior colliculus; CG, central gray;
CNf, cuneiform nucleus; CPu, caudate
putamen; DMH, dorsomedial hypothalamic nucleus;
DPGi, dorsal paragigantocellular nucleus;
f, fornix; ic, internal capsule;
icp, inferior cerebellar peduncle; IP,
interpeduncular nucleus; LDTg, laterodorsal tegmental
nucleus; lfp, longitudinal fasciculus of the pons;
LHb, lateral habenular nucleus; LL,
lateral lemniscus; LPO, lateral preoptic area;
ml, medial lemniscus; MCPO, magnocellular
preoptic nucleus; MITg, microcellular tegmental nucleus;
MPO, medial preoptic nucleus; MVe, medial
vestibular nucleus; ox, optic chiasm; Pn,
pontine nuclei; Py, pyramidal tract, R,
red nucleus; rs, rubrospinal tract; SC,
superior colliculus; scp, superior cerebellar peduncle;
SI, substantia innominata; SNR,
substantia nigra, reticulata; SO, supraoptic nucleus;
Sp5O, spinal 5 nucleus, oral part; SpVe,
spinal vestibular nucleus; ZI, zona incerta.
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DISCUSSION |
In this report we show that when the GABAergic input to
serotonergic neurons of the DRN is blocked during W, SWS, or PS by iontophoretic application of bicuculline, their discharge rate loses
its relationship to the vigilance state. These results strongly suggest
that GABA is responsible for the difference of activity of serotonergic
neurons between W, SWS, and PS. This conclusion is strengthened by our
results showing that when the effect of bicuculline occurred on neurons
recorded at W-SWS or PS-W transitions, the difference in discharge
rate between SWS and W (or PS and W) seen in control conditions was no
longer visible. Indeed, if a neurotransmitter other than GABA was
responsible for the decrease of activity of these cells during SWS and
PS, it would still be active under bicuculline, and therefore a
difference in discharge rate between W and SWS or W and PS should
persist. This should be the case if the increase of activity seen in
our experiments after ejections of bicuculline during SWS or PS was
caused for example by unspecific effects, such as those reported in
some in vitro studies (Heyer et al., 1982; Johnson and
Seutin, 1997; Debarbieux et al., 1998). It might be also hypothesized
that we applied too much bicuculline and therefore the increases of
discharge rate that we saw could be caused by a disinhibition of
excitatory interneurons within the DRN. We cannot rule out the
possibility that such an indirect effect participates in the increase
of activity seen. However, it cannot explain the fact that when the
plateau effect of bicuculline occurred on neurons recorded at W-SWS or PS-W transitions, they present the same tonic discharge rate across the different vigilance states in contrast to control conditions.
Our results are only partly in agreement with previous data. Indeed,
Levine and Jacobs (1992) found in cats that the iontophoretic application of bicuculline on DRN serotonergic neurons during PS has no
effect. The discrepancies between the two studies could be attributable
to species differences. Indeed, presumed serotonergic neurons recorded
in cats (Levine and Jacobs, 1992) have a discharge rate during W and
SWS superior to that seen here in rats (2.53 Hz vs 1.5 Hz and 1.49 Hz
vs 0.5 Hz), suggesting that the regulation processes might differ
between the two species. In addition, Levine and Jacobs (1992) applied
bicuculline on neurons during a continuous period of each of the
vigilance states. Therefore, in contrast to us, they did not make the
important observation that during W-SWS or PS-W transitions the
difference of activity of a given DRN serotonergic neuron disappears
under bicuculline. Finally, our results are strongly supported by
results showing that a significant increase of the GABA release occurs
in the cat DRN during PS as compared with SWS (Nitz and Siegel, 1997).
In conclusion, our data and those of Nitz and Siegel (1997) strongly
support the hypothesis that GABA is the only neurotransmitter
responsible for the inactivation of the DRN serotonergic neurons during PS.
In addition, we and Levine and Jacobs (1992) found that the application
of bicuculline during SWS restores a tonic firing in DRN serotonergic
cells. These results indicate that an increase of the GABAergic
inhibition of the DRN serotonergic neurons could be responsible for
their decrease of activity during SWS. However, only a small
nonsignificant decrease of the GABA release was observed with
microdialysis in the DRN between W and SWS (Nitz and Siegel, 1997).
Nevertheless, these authors made the following hypothesis to explain
the discrepancy: "a small increase in the release of GABA possibly
beyond the resolution of the microdialysis technique, might be
sufficient to reduce DRN unit discharge in SWS."
Finally, our results, in contrast to those of Levine and Jacobs (1992),
show that bicuculline application during W induces an increase in the
activity of DRN serotonergic neurons. These results suggest the
existence of a tonic GABAergic inhibition of the DRN serotonergic cells
during quiet W. It would be interesting to determine whether this tonic
inhibition decreases during active W, during which in cats the
serotonergic neurons of the DRN reach a discharge rate in the same
range (5.97 Hz) as that seen under bicuculline (Trulson and Jacobs,
1979). The existence of such tonic inhibition during quiet W is
supported by results showing that spontaneous GABA-mediated IPSPs occur
in neurons from numerous brain structures in vitro (Otis et
al., 1991; for review, see Mody et al., 1994). Furthermore, recent
results showed that microdialysis of bicuculline in the DRN of
unanesthetized rats during their active period (at night) is followed
by a strong increase of the serotonin release in the DRN and the
nucleus accumbens (Tao et al., 1996). We also recently provided
evidence with the method used here that the noradrenergic cells from
the locus coeruleus are also tonically inhibited by GABA during SWS,
PS, and W (Gervasoni et al., 1998). Altogether these results suggest
that many neurons from the CNS might be under a tonic GABAergic
inhibition during the entire sleep-wake cycle.
In the second part of our study, we showed that the DRN receives
GABAergic inputs from neurons located in a large number of distant
regions from the forebrain to the medulla in addition to the local
ventral pontine periaqueductal gray, including the DRN itself. It
should be mentioned here that in our material, it was not possible to
visualize the GABAergic neurons localized in the CTb injection site and
its immediate surroundings. Although most GABAergic neurons localized
in the DRN are concentrated more laterally than serotonergic neurons
(Ford et al., 1995) and therefore are only partially masked by the
sites, we might have underestimated the importance of their input. Our
results nevertheless clearly show that GABA is not only contained in
interneurons, in contrast to the classic concept. They greatly extend
the notion (for review, see Ottersen et al., 1995) that long GABA
projections are much more common than previously thought and that one
population of neurons can be inhibited by several groups of GABAergic
neurons located in different structures. They raise the question of the functional role of such complexity. One possibility is that some of
these GABAergic afferents terminate on non-serotonergic neurons located
in the DRN. In particular, they could terminate on GABAergic interneurons and be primarily involved in disinhibition of the serotonergic cells. However, Wang et al. (1992) have shown by electron
microscopy that only a few GABAergic terminals contact non-serotonergic
cells in the DRN. It is also possible that, as in other systems
(Somogyi et al., 1998), GABAergic afferents are presynaptic and/or
contact different parts of the serotonergic neurons, e.g., the cell
body and different dendritic regions. Finally, it is likely that each
GABAergic afferent is active under different physiological conditions.
In particular, on the basis of our electrophysiological data, we expect
that one or several of these GABAergic afferents are "turned on" or
increase their activity selectively during SWS and PS and are
responsible for the progressive decrease of activity of the DRN
serotonergic neurons during these sleep states. Among the GABAergic
structures revealed in our study, a few are good candidates for such roles.
The most likely candidates for the inhibition of the serotonergic DRN
neurons during SWS are the GABAergic neurons distributed over the
entire extent of the lateral preoptic area. A large number of studies
indicate that the lateral preoptic area plays an important role in
sleep onset and maintenance. For example, lesion of the lateral
preoptic area induced insomnia, whereas its stimulation induced SWS
(Sterman and Clemente, 1962; McGinty and Sterman, 1968; Lucas and
Sterman, 1975; Sallanon et al., 1989; Asala et al., 1990; John et al.,
1994). Neurons that increase their activity during sleep have been
recorded in this area (Kaitin, 1984; Szymusiak and McGinty, 1986;
Koyama and Hayaishi, 1994; Szymusiak et al., 1998). More recently, it
has been shown that GABA or c-fos-positive neurons observed after long
periods of sleep specifically in the ventrolateral preoptic area
project to the tuberomamillary nucleus (Sherin et al., 1996, 1998). We
also recently showed that noradrenergic cells from the locus coeruleus
receive a GABAergic input specifically from the ventrolateral preoptic
area (Peyron et al., 1995; Luppi et al., 1999) and are tonically
inhibited by GABA during SWS (Gervasoni et al., 1998). From these
results, it can be hypothesized that GABAergic neurons covering the
entire lateral preoptic area might inhibit DRN serotonergic neurons
during SWS. In contrast, the GABAergic neurons inhibiting the
histaminergic and noradrenergic nuclei during this sleep state would be
mainly localized in the ventrolateral preoptic area. Additional
physiological studies are necessary to confirm these hypotheses.
The GABAergic afferents responsible for the inhibition of the
serotonergic neurons of the DRN during PS should be located in the
lower brainstem. Indeed, it has been shown in decerebrate animals that
PS-like episodes are still associated with a cessation of activity of
these neurons (Hoshino and Pompeiano, 1976). The GABAergic afferent
from the ventral pontine periaqueductal gray, including the DRN itself,
is the best candidate for such inhibition. This pathway has already
been described on slices in which focal iontophoretic application of
NMDA in the ventral periaqueductal gray, including the DRN, induced
bicuculline sensitive IPSPs in DRN serotonergic neurons (Jolas and
Aghajanian, 1997). Moreover, Aghajanian et al. (1978) recorded in
anesthetized rats neurons in the DRN with a pattern of activity
reciprocal to that of serotonergic neurons. Some non-serotonergic
neurons recorded in the DRN across the sleep-wake cycle have been
found to specifically increase their discharge rate during PS (Shima et
al., 1986; Kocsis and Vertes, 1992). In addition, Yamuy et al. (1995)
observed a large number of serotonergic negative-/c-fos-positive cells
in the DRN and lateral to it after a long period of PS obtained by
pontine injection of carbachol. Maloney et al. (1999) recently saw
after a PS rebound induced by deprivation an increase in the number of
c-fos+/GAD+ neurons in the periaqueductal gray and the DRN. In
conclusion, our results and the results of others suggest that GABAergic neurons from the ventral pontine periaqueductal gray, including the DRN itself, might be responsible for the inhibition of
DRN serotonergic neurons during REM sleep. Additional physiological studies are nevertheless needed to confirm this hypothesis.
In addition to the lateral preoptic area and the ventral pontine
periaqueductal gray, we report that the DRN receives numerous other
GABAergic afferents. Although they could also play a role in the
inhibition of serotonergic neurons during sleep, to our knowledge no
data are available to support this view. One possibility is that these
structures are responsible for the tonic GABAergic inhibition that we
found during W. In particular, the strong GABAergic projection from the
lateral and posterior hypothalamic areas could play such role because
they contain neurons specifically active during W (Vanni-Mercier et
al., 1984).
In conclusion, our data indicate that an increase of a GABAergic
inhibitory tone present during wakefulness is likely responsible for
the decrease of activity of the dorsal raphe serotonergic cells during
slow wave and paradoxical sleep. On the basis of our anatomical
results, we further propose that GABAergic neurons located in the
lateral preoptic area and the pontine ventral periaqueductal gray,
including the DRN, could be responsible for this reduction of activity
during slow wave and paradoxical sleep, respectively. Additional
physiological experiments are now necessary to test these hypotheses.
| |
FOOTNOTES |
Received Aug. 8, 1999; revised March 20, 2000; accepted March 20, 2000.
This work was supported by Institut National de la Santé et de la
Recherche Médicale (U480), Centre National de la Recherche Scientifique (ERS 5645), Université Claude Bernard Lyon I, and the 1996 European Sleep Research Society-Synthélabo
European Research Grant. We thank C. Guillemort (GFG Co.,
Pierre-Bénite, France) for his help in designing the
head-restraining system, and G. Debilly and F. Lorent for their expert
assistance in statistical analysis.
D.G. and C.P. contributed equally to this work.
Correspondence should be addressed to Dr. Damien Gervasoni, INSERM
U480, Faculté de Médecine, 8 Avenue Rockefeller, 69373 Lyon
cedex 08, France. E-mail:
gervasoni{at}sommeil.univ-lyon1.fr.
| |
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TOP
ABSTRACT
INTRODUCTION
Compound via MeSH
