Involvement of 5-HT1A Receptors in Homeostatic and Stress-Induced Adaptive Regulations of Paradoxical Sleep: Studies in 5-HT1A Knock-Out Mice

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The Journal of Neuroscience, June 1, 2002, 22(11):4686-4692

Involvement of 5-HT_1A Receptors in Homeostatic and Stress-Induced Adaptive Regulations of Paradoxical Sleep: Studies in 5-HT_1A Knock-Out Mice
Benjamin Boutrel, Christelle Monaca, René Hen², Michel Hamon, and Joëlle Adrien
Institut National de la Santé et de la Recherche Médicale U288, NeuroPsychoPharmacologie Moléculaire, Cellulaire et Fonctionnelle, Faculté de Médicine Pitié-Salpêtrière, 75634 Paris Cedex 13, France, and ² Center for Neurobiology and Behavior, Columbia University, New York, New York 10032

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

For the last two decades, the involvement of 5-HT_1A receptors in the regulation of vigilance states has been studied extensivelythanks to pharmacological tools, but clear-cut conclusion hasnot been reached yet. By studying mutant mice that do not expressthis receptor type (5-HT_1A $-$ / $-$ ) and their wild-type 129/Sv counterparts,we herein demonstrate that 5-HT_1A receptors play key roles inthe control of spontaneous sleep-wakefulness cycles, as well asin homeostatic regulation and stress-induced adaptive changesof paradoxical sleep. Both strains of mice exhibited a diurnalsleep-wakefulness rhythm, but 5-HT_1A $-$ / $-$ animals expressed higheramounts of paradoxical sleep than wild-type mice during both thelight and the dark phases. In wild-type mice, pharmacologicalblockade of 5-HT_1A receptors by WAY 100635 (0.5 mg/kg, i.p.) promotedparadoxical sleep, whereas the 5-HT_1A agonist 8-OH-DPAT (0.25-1mg/kg, s.c.) had an opposite effect. In contrast, none of the5-HT_1A receptor ligands affected sleep significantly in 5-HT_1A $-$ / $-$ mice. However, 5-HT_1B receptor stimulation by CP 94253 (1-3 mg/kg,i.p.) induced a reduction in paradoxical sleep in both strains,this effect being more pronounced in 5-HT_1A $-$ / $-$ mutants. Finally,in contrast to wild-type mice, 5-HT_1A $-$ / $-$ mutants did not exhibitany rebound of paradoxical sleep after either a 9 hr instrumentalparadoxical sleep deprivation or a 90 min immobilization stress.Altogether, these data indicate that, in the mouse, 5-HT_1A receptorsparticipate in the spontaneous and homeostatic regulation, aswell as in stress-induced adaptive changes of paradoxicalsleep.

Key words: sleep-wakefulness; 5-HT_1A receptors; sleep deprivation; immobilization stress; knock-out mice; paradoxical sleep homeostasis

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The implication of serotonin (5-hydroxytryptamine, 5-HT) receptors of the 5-HT_1A type in the regulation of vigilance stateshas been the matter of numerous investigations using appropriatepharmacological tools (Portas et al., 2000; Ursin, 2002). In particular,the inhibitory effect of systemic treatment with various 5-HT_1Areceptor agonists, notably the prototypical one 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT), on paradoxical sleep (PS) is consideredas a key observation in support of the idea that 5-HT_1A receptorsplay an important role in the regulation of this vigilance statein mammals (Dzoljic et al., 1992; Monti and Jantos, 1992; Quattrochiet al., 1993; Tissier et al., 1993; Driver et al., 1995). Thesereceptors are located on both somas and dendrites of serotonergicneurons in raphe nuclei (somatodendritic autoreceptors) (Vergéet al., 1986; Sotelo et al., 1990) and target neurons receivingserotonergic projections (postsynaptic receptors) (Kia et al.,1996; Riad et al., 2000). The PS inhibition induced by 5-HT_1Areceptor agonists would result from activation of postsynapticreceptors (Tissier et al., 1993), notably those at pontine level(Sanford et al., 1994; Horner et al., 1997; Thakkar et al., 1998).In contrast, activation of somatodendritic 5-HT_1A autoreceptorsin anterior raphe nuclei would induce a PS enhancement (Portaset al., 1996; Bjorvatn et al., 1997).

However, the specific involvement of 5-HT_1A receptors in sleep-wakefulness regulations remains questionable because none ofthe ligands used so far is really selective of 5-HT_1A receptors.Indeed, even 8-OH-DPAT, which is classically considered as a selective5-HT_1A agonist (Hoyer et al., 1994), acts at 5-HT₇ receptors atrelatively low doses (Wood et al., 2000). An alternative strategyto assess the potential role of 5-HT_1A receptors in sleep-wakefulnessregulation under baseline conditions, as well as after variousbehavioral challenges (Sallanon et al., 1983; Houdouin et al.,1991a; Cespuglio et al., 1995; Gonzalez et al., 1996; Gonzalezand Valatx, 1998), is now possible thanks to the availabilityof knock-out mice that do not express this receptor type (Heisleret al., 1998; Parks et al., 1998; Ramboz et al., 1998). Phenotypicalcharacterization of these mutants showed that they exhibit markedbehavioral alterations, in particular increased responses in anxiety-relevanttests, in sharp contrast with the apparent decrease in anxiety-likebehaviors in mutant mice that do not express 5-HT_1B receptors(Zhuang et al., 1999). Interestingly, the latter 5-HT_1B $-$ / $-$ mutantsshow increased amounts of PS under baseline conditions but norebound of this sleep stage after its selective deprivation (Boutrelet al., 1999). Whether 5-HT_1A $-$ / $-$ mutants also exhibit alterationsin PS regulation, possibly opposite to those observed in 5-HT_1B $-$ / $-$ mutants, was an interesting question to be addressed with regardto the well established relationships between stress-anxiety-drivenbehaviors and sleep-wakefulness (Cespuglio et al., 1995; Marinescoet al., 1999; Vazquez-Palacios and Velazquez-Moctezuma, 2000).

All of these considerations led us to investigate the characteristics of sleep-wakefulness regulations in 5-HT_1A $-$ / $-$ mice comparedwith wild-type counterparts, first, under baseline conditionsand in response to the administration of 5-HT_1A and 5-HT_1B receptorligands, and second, after selective PS deprivation or immobilizationstress.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

All of the procedures involving animals and their care were conducted in conformity with the institutional guidelines thatare in compliance with national and international laws and policies(Council directive 87-848, October 19, 1987, Ministère de l'Agricultureet de la Forêt, Service vétérinaire de la santé et de la protectionanimale, permissions 75-116 to M.H. and 0315 to J.A.).

All mice used for these studies were of the 129/Sv strain. Those used for spontaneous sleep-wakefulness analysis, PS deprivation,and immobilization stress were produced by heterozygous breeding,and their genotype was determined according to the method of Rambozet al. (1998). Other groups of mice, produced from homozygousbreeding of knock-out and wild-type strains, were used for pharmacologicalexperiments.

Surgery
Male wild-type (5-HT_1A+/+) and mutant (5-HT_1A $-$ / $-$ ) mice were used at 2-3 months of age (body weight, 22-26 gm). Animals wereimplanted under sodium pentobarbital anesthesia (70-75 mg/kg,i.p.) with the classical set of electrodes (made of enameled nichromewire, 150 µm in diameter) for polygraphic sleep monitoring asdescribed previously (Boutrel et al., 1999). In brief, EEG electrodeswere inserted through the skull onto the dura over the right cortex(2 mm lateral and 4 mm posterior to the bregma) and over the cerebellum(at midline, 2 mm posterior to lambda), electrooculography electrodeswere positioned subcutaneously on each side of the orbit, andEMG electrodes were inserted into the neck muscles. All electrodeswere anchored to the skull with Superbond (Limoge-Lendais et al.,1994) and acrylic cement and soldered to a miniconnector alsoembedded in cement. After completion of surgery, animals werehoused in individual cages (20 × 20 × 30 cm) and maintained understandard laboratory conditions: 12 hr light/dark cycle (lighton at 7:00 A.M.), 24 ± 1°C ambient temperature, and food and wateravailable ad libitum. The animals were allowed 7-10 d to recoverand habituate to the recordingconditions.

Pharmacological treatments
Drugs were dissolved in 0.1 ml of saline, except for the 5-HT_1B agonist 3-(1,2,5,6-tetrahydro-4-pyridyl)-5-propoxypyrrolo[3,2-b]pyridine(CP 94253),which was dissolved in 0.1 ml of warm distilled water.All injections were performed between 9:30 and 10:00 A.M.; CP94253 and the 5-HT_1A antagonist N-[2-[4-(2-methoxyphenyl)-1-piperazinyl]ethyl]-N-(2-pyridinyl) cyclohexane carboxamide (WAY 100635) wereinjected intraperitoneally, whereas 8-OH-DPAT was injected subcutaneously.For baseline data, mice were injected intraperitoneally or subcutaneouslywith the vehicle only, as appropriate. A washout period of atleast 2 d for CP 94253 and WAY 100635 and 7 d for 8-OH-DPAT wasallowed between two consecutivetreatments.

PS deprivation
Mice were placed for 9 hr, starting at 10:00 A.M., on platforms (control conditions, 7.5 cm in diameter, 3 cm high; deprivationconditions, 3.5 cm in diameter, 4 cm high) surrounded by water(2 cm deep) (Boutrel et al., 1999) at an ambient temperature of24°C, with access to food and water ad libitum. At the end ofthis period, they were returned to their home cage and allowedto recover for 12 hr (from 7:00 P.M. to 7:00 A.M. the next morning).Each mouse underwent the paired control and deprivation procedures(separated by at least 1week).

Immobilization stress
At least 10 d after completion of the deprivation procedure, mice were immobilized for 90 min, from 6:30 to 8:00 P.M., bywrapping them inside a plastic grid. At the end of this period,they were returned to their home cage for sleep-wakefulness monitoring.Each mouse underwent, first, the control procedure (the animalremained free in its home cage and was connected a few minutesbefore being recorded) and, second (2-3 d later), the immobilizationprocedure.

Polygraphic recordings
For the study of spontaneous sleep-wakefulness cycles, each animal was recorded for 48 hr, beginning at 7:00 P.M., i.e., atthe onset of the dark period. For pharmacological studies, sleep-wakefulnessparameters were recorded for 8 hr after injections, i.e., from10:00 A.M. to 6:00 P.M.. For PS deprivation experiments, recordingswere performed from the beginning of the deprivation period (at10:00 A.M.) and continued until 12 hr after the end of deprivation,and, for the stress procedure, recordings were performed for 12hr after the end of immobilizationchallenge.

Data analysis and statistics
Polygraphic recordings were scored manually every 15 sec epoch using Somnologica software (Flaga, Reykjavik, Iceland), andthe amounts of each state of vigilance [wakefulness (W), slow-wavesleep (SWS), and PS] were calculated perhour.
Spontaneous sleep-waking cycles. For each animal, the amounts of vigilance states for every hour throughout 48 hr were averagedfor the light and the dark phases. The mean values (expressedas minutes ± SEM) for each strain of mice were used for calculatingthe ANOVA for the genotype. In case of significance (p < 0.05),the F test was followed by the Student's t test for meancomparisons.
Pharmacological experiments. The effects of each dose of a given compound on each state of vigilance were analyzed for every2 hr period after injection and are expressed as minutes ± SEM.For a given treatment, each animal was referred to its own baseline,represented by the data obtained after injection of vehicle. Statisticalanalyses were performed using ANOVA for factors treatment andstrain, and, in case of significance (p < 0.05), the F test wasfollowed by the post hoc Fisher's test for assessing the effectof each dose ofcompounds.
PS deprivation and immobilization stress. For each animal, the PS amounts during the small platform condition and the following12 hr recovery period and those during the 12 hr post-stress periodwere compared with their respective control values (i.e., PS amountsduring the large platform condition and the corresponding controlrecovery period and those during the same period with no stress,respectively). Paired t tests were performed to assess statisticalsignificance of thedata.

Chemicals
The following drugs were used: WAY 100635 (0.5 mg/kg, i.p.; Wyeth Research, Princeton, NJ), 8-OH-DPAT (0.25-1.0 mg/kg, s.c.; Research Biochemicals, Natick, MA), and CP 94253 (1-3 mg/kgi.p.; Pfizer, Groton,CT).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Spontaneous sleep-wakefulness cycles

All mice exhibited a clear-cut circadian sleep-wakefulness rhythm, with larger amounts of sleep during the light period thanduring the dark one (Fig. 1). However, 5-HT_1A $-$ / $-$ mutants differedsignificantly (p < 0.05) from wild-type mice by a greater amountof PS, during both the light (approximately +39%) and the dark(approximately +45%) phase (Table 1). This enhancement was accountedfor by an increase in the mean duration of PS episodes duringthe light phase (1.25 ± 0.04 vs 1.08 ± 0.02 min; mean ± SEM; n= 8 in each group; p < 0.05) and by an increase in the numberof PS episodes during the dark phase (35.6 ± 2.5 vs 26.8 ± 2.5;p < 0.05).

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Figure 1. Circadian variations of W, SWS, and PS in 5-HT_1A+/+ (dotted line) and 5-HT_1A $-$ / $-$ (solid line) mice. Data (mean ± SEM of 9 and 8 animals, respectively) are expressed as minutes per hour during two consecutive light/dark cycles (lights on from 7:00 A.M. to 7:00 P.M.). *p < 0.05, significant difference between groups; Student's t test.


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Table 1. Amounts of W, SWS, and PS in 5-HT_1A+/+ and 5-HT_1A $-$ / $-$ mice under normal conditions

In contrast, the amounts of W and SWS were identical in both groups throughout the entire circadian period (Fig. 1, Table1).

Pharmacological data

Activation or blockade of 5-HT_1A receptors
In wild-type mice, 8-OH-DPAT (0.25-1 mg/kg, s.c.) induced, during the first 2 hr period after injection, a dose-related inhibitionof PS (ANOVA; F_(3,15) = 20.4; p < 0.0001) (Fig. 2) and SWS (ANOVA;F_(3,15) = 15.9; p < 0.0001; data not shown), as well as a concomitantincrease in W (ANOVA; F_(3,15) = 21.0; p < 0.0001; data not shown).These initial modifications of sleep-wakefulness states were significantfor all doses of 8-OH-DPAT tested (p < 0.001; post hoc Fisher'stest). They were followed by a rebound of PS observed between6 and 8 hr after the injection, which was significant (p < 0.05;Fisher's test) for the doses of 0.25 and 0.5 mg/kg 8-OH-DPAT (Fig.2). In contrast, 8-OH-DPAT had no effect on sleep or wakefulnessamounts in 5-HT_1A $-$ / $-$ mice, except for a nonsignificant PS enhancement(125.3 ± 18.6% of baseline; n = 6; p = 0.17) during the first2 hr after injection at the dose of 1 mg/kg (Fig. 2). On the whole,the difference between strains during this period was highly significantfor the three states of vigilance (ANOVA; F_(1,36) = 43.1, 21.5,and 32.0; p < 0.001 for PS, SWS, and W, respectively).

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Figure 2. Effects of the 5-HT_1A agonist 8-OH-DPAT on paradoxical sleep in 5-HT_1A+/+ (top) and 5-HT_1A $-$ / $-$ (bottom) mice during four successive 2 hr periods after injection. Data (mean ± SEM of 5 and 6 animals, respectively) are expressed as minutes per 2 hr after subcutaneous injection of saline (open bars) or 8-OH-DPAT at various doses (filled bars). *p < 0.05, significantly different from saline; post hoc Fisher's test.

Blockade of 5-HT_1A receptors by WAY 100635 (0.5 mg/kg, i.p.) induced in 5-HT_1A+/+ mice, but not in 5-HT_1A $-$ / $-$ mutants, a significantincrease in PS amounts (p = 0.001; paired Student's t test) duringthe first 4 hr after the injection (Fig. 3) and no modificationsin W and SWS in any strain (data not shown).

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Figure 3. Effects of blockade of 5-HT_1A receptors on paradoxical sleep in 5-HT_1A+/+ (top) and 5-HT_1A $-$ / $-$ (bottom) mice during four successive 2 hr periods after treatment. Data (mean ± SEM of 6 and 4 animals, respectively) are expressed as minutes per 2 hr after injection of saline (white bars) or the 5-HT_1A antagonist WAY 100635 at the dose of 0.5 mg/kg intraperitoneally (gray bars). *p < 0.05, significantly different from saline; paired Student's t test.

Activation of 5-HT_1B receptors
5-HT_1B receptor activation by CP 94253 (1-3 mg/kg, i.p.) induced, during the first 4 hr after injection, a significant reductionin PS amounts in wild-type mice (ANOVA; F_(3,23) =3.6; p = 0.028),as well as in mutants (ANOVA; F_(3.23) = 9.6; p < 0.001). Thisreduction reached significance for the doses of 2 and 3 mg/kgin wild-type (p = 0.023 and 0.007, respectively; post hoc Fisher'stest) and mutant (p < 0.001 for both doses) mice and was morepronounced in 5-HT_1A $-$ / $-$ animals (ANOVA; F_(1,46) = 9.63; p = 0.003)(Fig. 4). In contrast, neither W nor SWS were significantly affectedby CP 94253 in both groups of mice (data not shown).

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Figure 4. Effects of the 5-HT_1B agonist CP 94253 at various doses on paradoxical sleep in 5-HT_1A+/+ (dotted line) and 5-HT_1A $-$ / $-$ (solid line) mice during the first 4 hr period after injection. Data (mean ± SEM of 7 animals in each group) are expressed as percentages of PS amounts in saline-treated mice (0 on abscissa). *p < 0.05, significant difference between groups; Fisher's test.

Paradoxical sleep deprivation

During PS deprivation (small platform), mice of both groups exhibited nearly the same amounts of SWS (data not shown) butonly ~20% of PS compared with those observed under control conditions(large platform) (Fig. 5). During the recovery period, PS amountswere significantly enhanced in 5-HT_1A+/+ mice compared with thoseunder control conditions (Fig. 5, Table 2), notably during thefirst 6 hr (+76.4 ± 22.3%; n = 6; p < 0.05; paired Student's ttest). This increase was accounted for by an increase in the numberof PS episodes (Table 2) with no modification of their mean duration(1.21 ± 0.11 vs 1.11 ± 0.10 min; NS; paired Student's t test).In contrast, in 5-HT_1A $-$ / $-$ mice, only a slight but not significantincrease in PS amounts was observed after PS deprivation comparedwith those under control conditions (Fig. 5, Table 2) (+20.6± 16.9% during the first 6 hr of the recovery period; n = 6; NS;paired Student's t test), and neither the number (Table 2) northe mean duration (1.22 ± 0.10 vs 1.16 ± 0.05 sec; NS; pairedStudent's t test) of PS episodes were altered during the recoveryperiod in PS-deprived compared with nondeprived mutants. In addition,no modifications in W and SWS amounts were observed after PS deprivationin wild-type and 5-HT_1A $-$ / $-$ mice (data not shown).

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Figure 5. Paradoxical sleep amounts observed during 9 hr of PS deprivation and 12 hr thereafter, in 5-HT_1A+/+ (white bars) and 5-HT_1A $-$ / $-$ (gray bars) mice. Data (mean ± SEM of 6 animals in each group) are expressed as percentage of paired values obtained under control conditions (large platform). *p < 0.05, significant difference between groups; Student's t test.


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Table 2. Characteristics of paradoxical sleep in 5-HT_1A+/+ and 5-HT_1A $-$ / $-$ mice during 12 hr after a 9 hr PS deprivation or a 90 min immobilization stress

Immobilization stress

After 90 min of immobilization, wild-type mice, but not 5-HT_1A $-$ / $-$ mutants, exhibited a significant increase in PS amountsduring the 12 hr recovery period compared with the control conditions[respectively, +27.5 ± 10.6% (n = 9; p < 0.05) and $-$ 0.2 ± 7.0%(n = 7; NS); paired Student's t test]. This PS rebound in wild-typemice was mainly observed during the second half of the night (Table2), especially for the last 3 hr (Fig. 6), and was accountedfor by an increase in the number of PS episodes (Table 2), withno change of their mean duration (1.20 ± 0.05 vs 1.06 ± 0.07 min;NS; paired Student's t test). In contrast, no significant modificationsin the amounts of W and SWS after the immobilization procedurewere observed in wild-type and 5-HT_1A $-$ / $-$ mice (data not shown).

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Figure 6. Paradoxical sleep amounts observed during 12 hr after 90 min of immobilization in 5-HT_1A+/+ (top) and 5-HT_1A $-$ / $-$ (bottom) mice. Data (mean ± SEM of 9 and 7 animals, respectively) are expressed as minutes per 3 hr under control conditions (white and gray solid bars) and after immobilization stress (hatched bars). *p < 0.05, significantly different from respective control value; paired Student's t test.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Regulation of sleep-wakefulness cycles under baseline conditions

In the present work, we found that knock-out mice, which do not express the 5-HT_1A receptor, and their wild-type counterpartsexhibit similar circadian sleep-wakefulness cycles with predominanceof wakefulness during the dark period and sleep during the lightone. These data are comparable with those generally obtained inmice (Tobler et al., 1997) and notably in the 129/Sv strain (Boutrelet al., 1999), which shares the same genetic background as thepresent ones. However, 5-HT_1A $-$ / $-$ mutants differed from 5-HT_1A+/+wild-type mice by higher amounts of PS during the entire circadianperiod, whereas wakefulness and SWS amounts were similar in bothgroups. Because we used in this part of the study only mice derivedfrom heterozygous breeding, it is most probable that the differencein PS amounts is accounted for by the 5-HT_1A gene disruption ratherthan by some heterogeneity in the genetic background between bothgroups of mice (Gerlai, 1996). This is further supported by thefact that pharmacological blockade of 5-HT_1A receptors with WAY100635 induced in wild-type mice an increase in PS amounts, therebymimicking the change that occurred spontaneously in mutants lacking5-HT_1A receptors. Accordingly, both the larger amounts of spontaneousPS in 5-HT_1A $-$ / $-$ mutants and the PS enhancement after 5-HT_1A receptorblockade in wild-type mice indicate that these receptors mediatea tonic inhibitory influence on PS in thisspecies.

The lack of significant effect of 8-OH-DPAT on sleep-wakefulness cycle in 5-HT_1A $-$ / $-$ mutants would suggest that 5-HT₇ receptorsat which this ligand acts as a partial agonist (Wood et al., 2000)are not involved in the regulation of vigilance states, at leastin the mouse. This conclusion is in line with previous resultsshowing that the effects of 8-OH-DPAT on sleep and wakefulnessin the mouse were completely prevented by the selective 5-HT_1Areceptor antagonist WAY 100635 (Boutrel et al., 1999). In anycase, additional investigations are needed to assess the possibleimplication of 5-HT₇ receptors in sleep-wakefulness regulationbecause Hagan et al. (2000) reported recently a decrease in PSafter administration of a 5-HT₇ receptor antagonist in rats. Indeed,we did find a tendency to an increase in PS amounts in 5-HT_1A $-$ / $-$ mice treated with 8-OH-DPAT (Fig. 2), which would fit with theidea of 5-HT₇ receptor stimulation exerting a facilitatory influenceon PS expression inrodents.

According to the reciprocal interaction model for PS regulation (McCarley and Massaquoi, 1992), 5-HT exerts an inhibitoryinfluence on mesopontine cholinergic "PS-on" neurons (Honda andSemba, 1994), notably through postsynaptic 5-HT_1A receptors (Sanfordet al., 1994; Horner et al., 1997). On the contrary, 5-HT mighthave a facilitatory influence on PS (Portas et al., 1996; Bjorvatnet al., 1997) or SWS (Sakai and Crochet, 2001) through the activationof somatodendritic 5-HT_1A autoreceptors in anterior raphe nuclei.In the present work, the increase of PS amounts observed afterboth pharmacological and genetic inactivation of 5-HT_1A receptors,together with the unchanged levels of SWS, support the view thatmainly postsynaptic 5-HT_1A receptors are involved in the physiologicalregulation of PS (Tissier et al., 1993).

Compensation at 5-HT_1B receptors in 5-HT_1A $-$ / $-$ mutants

Interestingly, we found that 5-HT_1B receptor activation by CP 94253 caused a more pronounced reduction of PS amounts in 5-HT_1A $-$ / $-$ mutants than in wild-type mice, thereby suggesting that 5-HT_1Breceptors are supersensitive in these mutants. A similar adaptationof 5-HT_1A receptors was apparent in 5-HT_1B knock-out mice in which8-OH-DPAT was found to be more potent than in paired wild-typemice to inhibit PS expression (Boutrel et al., 1999). Becauseboth 5-HT_1A and 5-HT_1B receptors appear to be involved in a 5-HT-mediatedinhibitory control of PS in mice (Boutrel et al., 1999; presentstudy), these data would support the idea that a compensatoryincrease in the functioning of one receptor occurs after inactivationof the other. Such compensatory changes in 5-HT_1A $-$ / $-$ and 5-HT_1B $-$ / $-$ mice have been reported previously but with variations from onebrain area to another (Bouwknecht et al., 2001; Knobelman et al.,2001), illustrating the complexity of adaptive processes affectingthese receptors. With regard to sleep-wakefulness mechanisms,whether 5-HT_1B receptors in pontine nuclei possibly controllingPS expression (Boutrel et al., 1999) are supersensitive or upregulatedin 5-HT_1A $-$ / $-$ mutants is an important question to be addressedin futureinvestigations.

PS rebound after selective PS deprivation or immobilization stress

In agreement with previous reports, wild-type mice were presently found to exhibit a PS rebound after either selective PSdeprivation (Sallanon et al., 1983; Adrien and Dugovic, 1984;Gonzalez et al., 1996; Boutrel et al., 1999) or immobilizationstress (Cespuglio et al., 1995; Gonzalez et al., 1995; Gonzalezand Valatx, 1998; Meerlo et al., 2001). Interestingly, the reboundafter deprivation started immediately at the beginning of therecovery period, whereas that after immobilization stress wasdelayed by 3-6 hr. Such differences in the time courses of reboundin the two experimental procedures, which have also been observedin rats (Adrien and Dugovic, 1984; Houdouin et al., 1991a), probablyreflect two different mechanisms. Indeed, PS deprivation (smallplatform), in contrast to immobilization stress, does not enhanceplasma corticosterone levels (compared with paired control conditions,large platform) (Porkka-Heiskanen et al., 1995). Accordingly,immediate PS rebound would not be attributable to the stress inherentto the platform technique but would rather reflect sleep homeostaticproperties (Barbato and Wehr, 1998). On the other hand, the delayin PS rebound after immobilization stress may be accounted forby increased levels of corticosterone just after the stress, becausethis hormone exerts inhibitory influence on PS (Bradbury et al.,1998; Marinesco et al., 1999). Indeed, under our conditions, preliminarydata showed that plasma corticosterone levels increased markedlyjust after immobilization and returned to baseline only 4-6 hrlater (our unpublished observations), i.e., at the time of PSreboundonset.

In contrast to wild-type animals, 5-HT_1A $-$ / $-$ mutants did not exhibit any PS rebound after PS deprivation or immobilizationstress. This has been found previously with 5-HT_1B $-$ / $-$ mice afterselective PS deprivation (Boutrel et al., 1999) and immobilizationstress (our unpublished data). Accordingly, it can be inferredthat both 5-HT_1A and 5-HT_1B receptors play key roles in the homeostaticregulation of PS and in the PS adaptive response to acute stress.Interestingly, previous studies also showed an absence of sleeprebound when 5-HT neurotransmission had been impaired (Sallanonet al., 1983; Houdouin et al., 1991a,b). Altogether, these datasupport the idea that the serotonergic system, in addition tothe corticotropin-releasing hormone- noradrenergic one (Gonzalezet al., 1995, 1996; Gonzalez and Valatx, 1998), underlie the PSrebound in response to both conditions. Such a lack of PS reboundafter acute stress in 5-HT_1A $-$ / $-$ mice might be linked to a prolactindeficit (Meerlo et al., 2001) and/or increased corticosteronelevels. Indeed, in 5-HT_1A (and 5-HT_1B) knock-out mice, but notin their wild-type counterparts, plasma corticosterone levelshad not returned to baseline, even 6 hr after the end of immobilization(our unpublished observations), thereby accounting for a sustainedprevention of PS rebound in thesemutants.

Because PS amounts for the recovery period after deprivation or immobilization stress in wild-type mice were similar to thosepreviously observed at baseline in 5-HT_1A $-$ / $-$ mutants, it can alsobe proposed that the latter have reached a maximum level of PSproduction as a result of the absence of 5-HT-mediated inhibitorycontrol. In this scheme, the 5-HT system, notably through 5-HT_1Aand 5-HT_1B (Boutrel et al., 1999) receptors, would play a predominantrole in all adaptive mechanisms involving PS. In any case, theabsence of PS rebound after PS deprivation, as well as after immobilizationstress, raises the question of the existence of common mechanismsunderlying the homeostatic regulations of PS and the PS-mediatedadaptations to stress, notably those involving 5-HT_1A and 5-HT_1Breceptors.

It is interesting to note that both 5-HT_1A $-$ / $-$ and 5-HT_1B $-$ / $-$ (Boutrel et al., 1999) mutants exhibit, on the one hand, a spontaneousincrease in PS amounts and a lack of PS adaptation to PS deprivationor a stressful condition, and, on the other hand, abnormal behaviors(anxiety-like for the 5-HT_1A $-$ / $-$ and aggressiveness for the 5-HT_1B $-$ / $-$ mice). The present results indicate that these abnormal behaviorsare associated with sleep alterations, a situation that is alsooften described in humans suffering from mood disorders (Gillin,1998; Van Praag, 1998) and that an altered 5-HT neurotransmissioncould be, at least, a common factor in these disorders. In thisrespect, it has to be emphasized that depression is associatedwith both an increased pressure of paradoxical sleep (Kupfer,1976; Gillin, 1998) and a general decrease in postsynaptic 5-HT_1Areceptor density in various brain regions (Drevets et al., 2000;Sargent et al., 2000) in humans. The increased expression of PSobserved herein in 5-HT_1A $-$ / $-$ mice would suggest that such a sleepanomaly in depressed patients is underlain, at least in part,by the reported downregulation of 5-HT_1A receptors in thesepatients.

  FOOTNOTES

Received Dec. 18, 2002; revised March 5, 2002; accepted March 8, 2002.

This research was supported by grants from Institut National de la Santé et de la Recherche Médicale and the Bristol-MyersSquibb Foundation (unrestricted biomedical research grant program).We are grateful to pharmaceutical companies (Wyeth Research andPfizer) for generous gifts of drugs. During performance of thesestudies, B.B. was supported by a Ministére de l'Education Nationalede la Recherche et de la Technologie fellowship and a grant fromLa Fondation pour la Recherche Médicale.

Correspondence should be addressed to Benjamin Boutrel, Institut National de la Santé et de la Recherche Médicale U288,91 Boulevard de l'Hôpital, 75634 Paris Cedex 13, France. E-mail:boutrel{at}hotmail.com.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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