An ether stressor increases REM sleep in rats: possible role of prolactin

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An ether stressor increases REM sleep in rats: possible role of prolactin

B. Bodosi¹, F. Obál Jr.¹, J. Gardi², J. Komlódi¹, J. Fang², and J. M. Krueger²

¹ Department of Physiology, Albert Szent-Györgyi Medical University, 6720 Szeged, Hungary; and ² Department of Veterinary and Comparative Anatomy, Pharmacology and Physiology, Washington State University, Pullman, Washington 99164-6520

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Sleep alterations after a 1-min exposure to ether vapor were studied in rats to determine if this stressor increases rapideye-movement (REM) sleep as does an immobilization stressor. Etherexposure before light onset or dark onset was followed by significantincreases in REM sleep starting ~3-4 h later and lasting for severalhours. Non-REM (NREM) sleep and electroencephalographic slow-waveactivity during NREM sleep were not altered. Exposure to ethervapor elicited prolactin (Prl) secretion. REM sleep was not promotedafter ether exposure in hypophysectomized rats. If the hypophysectomywas partial and the rats secreted Prl after ether exposure, thenincreases in REM sleep were observed. Intracerebroventricularadministration of an antiserum to Prl decreased spontaneous REMsleep and inhibited ether exposure-induced REM sleep. The resultsindicate that a brief exposure to ether vapor is followed by increasesin REM sleep if the Prl response associated with stress is unimpaired.This suggests that Prl, which is a previously documented REM sleep-promotinghormone, may contribute to the stimulation of REM sleep afteretherexposure.

hypophysectomy; immunoneutralization; pituitary

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

AN ACUTE 1- TO 2-H IMMOBILIZATION is followed by large increases in rapid eye-movement (REM) sleep in the rat (4, 30).The response to immobilization is often limited to increases inREM sleep (13, 30), but sometimes clear increases in non-REM(NREM) sleep could also be observed (4, 6, 12). The interindividualdifferences in the sleep alterations after stress might be relatedto the stressor responsiveness of the rats (6) and the durationof the stressor (19). The rats are awake most of the time duringimmobilization (4, 30), and therefore this procedure mightalso involve some degree of sleep deprivation. To avoid majorsleep loss, the immobilization is timed to the beginning of thedark period when rats normally sleep relatively little. Our aimwas to use a stress model, which is brief and thus suitable foruse at the beginning of the light period, the physiological restperiod for the rat, without the risk of significant sleep deprivation.In addition, it is not clear whether stimulation of REM sleepis specific for immobilization stress or if it occurs in anotherstress model. For example, the intensity of NREM sleep is enhancedwithout changes in REM sleep after exposure to a 1-h stressorassociated with social defeat in the rat (20). The stress modelconsisting of a brief exposure to ether vapor was used in ourexperiments.

Another aim of our experiments was to study the role of prolactin (Prl) in the mediation of the sleep alterations elicitedby brief exposure to ether. In addition to the activation of thehypothalamo-pituitary-adrenocortical axis, both immobilizationand ether exposure elicit Prl secretion (1, 11, 17, 23).Administration of exogenous Prl (27, 33, 43), stimulationof the release of endogenous Prl (28), and chronic hyperprolactinemia(26) are associated with increases in REM sleep in rats. Administrationof the recently described prolactin-releasing peptide (PrPR) promotesREM sleep in doses that also stimulate Prl secretion (44). Nevertheless,suppression of pituitary Prl secretion has relatively minor effectson REM sleep (25). It was suggested that it is the intraneuronalPrl in the brain that is important for the regulation of REM sleep;and systemic Prl, which is transported into the brain (38),stimulates REM sleep significantly only when circulating Prl concentrationsare high (31). Hypophysectomized rats (HYPOX) and rats injectedintracerebroventricularly with an antiserum to Prl (Prl-AS) wereused to determine whether the sleep alteration after ether exposuresurvives the suppression of Prlsecretion.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Animals and surgery. Male Sprague-Dawley rats (300-550 g) were used. The surgeries were carried out under ketamine-xylazine (87 and 13 mg/kg, respectively)anesthesia. Stainless steel jewelry screws for electroencephalograph(EEG) recording were implanted over the frontal and parietal corticesand over the cerebellum on the right side. A thermistor placedover the left parietal cortex was used to record brain corticaltemperature (Tcrt). The chronic intracerebroventricular cannulawas stereotaxically inserted into the left lateral ventricle [ $-$ 0.80mm from the bregma, 1.4 mm from midline, and $-$ 3.4 mm from thetop of the skull (29)]. The injection cannula protruded by 0.5mm from the guide cannula. The location of the cannula was determinedby the gravity method (sudden drop in pressure) during implantation.The function of the cannula and the drainage of the ventricularsystem were tested by the drinking response to intracerebroventricularlyinjected angiotensin (100 ng) before the recording, and the ratsthat failed to respond were left out of the experiments. Finally,Trypan blue was injected into the cannula, and the ventricleswere examined at the termination of the experiments; data wereused from those rats only in which Trypan blue stained the entireventricular system. For blood sampling, rats previously used insleep experiments were chronically implanted with a Silastic catheterin the right atrium. The catheter was introduced via the rightexternal jugular vein, and the distal end was exteriorized onthe back of the neck. The catheters were flushed daily with heparinizedphysiological saline (200-300 IU/day in 0.2-0.3 ml). Hypophysectomywas performed via the transauricular route (40) in rats previouslyimplanted with EEG electrodes and thermistors. The pituitary wassucked out by means of an 18-gauge needle attached to a syringefilled with physiological saline. The presence of the pituitaryin the suction fluid indicated the effectiveness of the hypophysectomy.In addition, the Prl response to ether exposure was also determinedin these rats, and the sella turcica was examined at the terminationof the experiments to determine whether the hypophysectomy wascomplete. The rats received 10 mg/kg hydrocortisone acetate intramuscularlyimmediately after hypophysectomy. HYPOX rats are prone to hypoglycemia,and their capacity for metabolic heat production is seriouslycompromised. As suggested (37, 40), the HYPOX rats thereforewere provided with drinking water containing 5% glucose, and theambient temperature was set to 29-30°C starting from the timeof the surgery and throughout the subsequent recovery and experimentalperiods.

Ether stress. The rats were moved individually into a jar (10 l) containing ether vapor for 1 min and then returned to their recording cage.A cotton cloth soaked with ether was placed in the bottom of thejar, and it was separated from the rat with a plastic plate withholes. The lid of the jar was closed. Near the end of ether exposure,the rats displayed motor uncoordination, but they were still standingor rearing; anesthesia did not occur. The rats were normal afterremoval from the jar. As a control treatment, the rats were placedin a jar that did not contain ether vapor but was otherwise identicalwith the one used for etherexposure.

Experimental schedule and groups. The experiments were done with the use of three sets of rats, including intact, HYPOX, and Prl-AS-treated animals. Withineach set, several groups of rats were used. The rats were exposedto ether 30-45 min before recording. The ether exposure was performedeither before light onset (light-onset group, n = 14) or beforedark onset (dark-onset group, n = 11), and the recording startedat light or dark onset. These two groups of intact rats were recordedfor the 23 h per day on 4 consecutive days as follows: day 1 (baseline):the rats were undisturbed; day 2 (control): the rats were exposedto the empty jar; day 3: ether exposure; and day 4: the rats wereundisturbed. Because changes in sleep occurred only in the first12 h of the recording period, only sleep in the light and darkperiod is reported herein for the light-onset group and the dark-onsetgroup,respectively.

Ten HYPOX rats were used. Prl measurements and examination of the sella turcica after the experiments indicated that the hypophysectomywas complete in seven rats (HYPOX group) and incomplete in threerats (partially HYPOX rats). Ether exposure occurred before lightonset, and sleep-wake activity was recorded during the 12-h lightcycle. The rats were exposed to the empty jar on day 1 (control)and to ether vapor on day 2. Because maintenance of HYPOX ratsrequired relatively high ambient temperature and glucose supplement,the effects of ether exposure on REM sleep were also tested ina group of intact rats (n = 4) that were kept at 29-30°C and receiveddrinking water containing 5%glucose.

Rabbit "polyclonal antiserum for rat Prl immunochemistry" (anti-rPrl-IC-5, lyophilized after 1:10 dilution in phosphate buffer)was obtained from the National Institute of Diabetes, Digestive,and Kidney Diseases (NIDDK) and used for in vivo immunoneutralizaton.The Prl-AS is provided without preservative and is devoid of antibodiesto pituitary hormones other than Prl. The 1:10 dilution of thePrl-AS was reconstituted, and three injections of 4 µl of thesolution were intracerebroventricularly injected 30, 20, and 10min before ether exposure in six rats. On the control day, therats were placed in the empty jar, and they received intracerebroventricularinjections of pyrogen-free physiological saline at the same timepoints as the injections of Prl-AS on the experimental day. Inanother group of rats (n = 5), instead of Prl-AS, normal rabbitserum in the same dilution and volume as the Prl-AS was intracerebroventricularlyinjected. These rats were also recorded for 2 days; a controlday with intracerebroventricular injection of physiological saline+ exposure to the empty jar and an experimental day with intracerebroventricularadministration of normal rabbit serum + ether stress. In all theexperiments with Prl-AS or normal rabbit serum, the ether exposureoccurred before light onset, and the rats were recorded from duringthe 12-h lightperiod.

Finally, the effects of Prl-AS were tested on spontaneous sleep without ether exposure in one group of rats (n = 11). Therats received intracerebroventricular physiological saline onthe control day and Prl-AS on the experimental day; the volume,dose, and timing of the injections were the same as those usedin the group with ether stress, but these rats were not exposedto an empty jar or ether vapor. Sleep-wake activity was recordedduring the 12-h lightperiod.

The timing of various treatments were as follows. Each rat was allowed 7 to 10 days of recovery after the implantation ofthe EEG electrodes, the thermistor, and the intracerebroventricularcannula. During this period, the rats were connected to the recordingtether and habituated to the experimental conditions. In addition,the rats prepared for intracerebroventricular injections weretested with angiotensin 2 to 3 days after implantation, and theyreceived intracerebroventricular injections of physiological saline(4 µl) daily for 4 days before the onset of recording. The ratswith an intracerebroventricular cannula were intracerebroventricularlyinjected with Trypan blue and killed immediately after the experimentto check the staining of the ventricular system. A group of ratsthat was used in sleep recording without intracerebroventricularcannula was implanted with the cardiac catheter 3 to 5 days afterthe termination of recording. These rats were used to determinethe effects of ether exposure on plasma Prl for blood sampling4 to 5 days postimplantation. Rats implanted with EEG electrodesand thermistors were HYPOX 7 to 10 days after surgery. Sleep inthese rats was studied 7 to 8 days after hypophysectomy. Bloodcollection for Prl measurements occurred 3 to 4 days after sleeprecording in HYPOXrats.

Recording. The rats were housed in individual Plexiglas cages. The cages were placed in recording rooms with a 12:12-h light-dark cycleand with an ambient temperature regulated at 26°C (29-30°C forthe HYPOX rats). The rooms were sound attenuated. Food and waterwere continuously available. The rats were kept in conditionsidentical to those in the recording rooms for at least 1 mo beforetheoperation.

The tethers were attached to commutators. The motor activity of the rats was assessed by recording potentials generated inelectromagnetic transducers attached to the tethers. Cables fromthe commutators and electromagnetic transducers were connectedto amplifiers (filtering below 0.1 and above 30 Hz) in an adjacentroom. The signals were digitized (64-Hz sampling rate) and collectedby a computer and stored on compact discs. For scoring, the EEG,Tcrt, and motor activity signals were restored on the computerscreen. In addition, power density values were calculated by fast-Fouriertransformation for consecutive 8-s epochs in the frequency rangebetween 0.25 and 20.0 Hz for 0.25-Hz bands and integrated for0.5-Hz bins; the spectral resolution was 0.125 Hz. The power densityspectra were also displayed on the computer screen. The statesof vigilance were determined over 8-s epochs by the usual criteriaas NREM sleep (high-amplitude EEG slow waves, lack of body movements,and declining Tcrt on entry), REM sleep (highly regular thetaactivity in the EEG, general lack of body movements with occasionaltwitches, and a rapid rise in Tcrt at onset), and wakefulness(EEG activities similar to, but often less regular, with loweramplitude than those in REM sleep, frequent body movements, anda gradual increase in Tcrt after arousal). The percentage of thetime spent in each state of vigilance of 1-h periods was determined.The 8-s Tcrt values were averaged for 1-h periods. Mean powerdensity spectra were calculated for 8-s uninterrupted periodsof artifact-free NREM sleep in each hour. The power density valuesfor the 0.25- to 4-Hz (delta) frequency range were integratedand used as an index of EEG slow-wave activity (SWA) during NREMsleep to characterize sleep intensity in each recording hour (SWAwas calculated for 2-h blocks in the dark-onset group to avoidtime blocks without NREM sleep). In the light-onset group, powerdensity values were calculated in the frequency bands between(in Hz) 0.25 and 4.0, 4.5 and 7.0, 7.5 and 12, and 12.5 and 20for both NREM sleep and wakefulness in hour 1 of the recordingof the control day (empty jar) and of the day with ether exposure(day 3) to determine if ether exposure altered EEG activity. Themean number per 12 h (frequency) and the mean duration of REM-sleepepochs were determined in both groups. Brief NREM sleep-wake sequencesmay intrude on REM sleep. When the time interval between two consecutiveREM-sleep periods was <1 min, then these REM-sleep periods werecounted as one epoch. The fragments of REM sleep were summed,but the intervening periods were not included in the calculatedduration of the REM-sleep epochs. The selection of 1-min timewindows for the occurrences of fragmented REM-sleep episodes wason the basis of the assumption that occurrences of REM sleep tendto peak at 8- to 12-min intervals, which are the normal durationof the sleep cycle in the rat, in both the oscillation and homeostaticmodels of REM-sleep regulation (3).

Determination of Prl. The rats (n = 10) fitted with a chronic catheter in the right atrium were exposed to the empty jar on the control day andto ether vapor on the experimental day. Blood samples (0.2 mleach) were withdrawn immediately before moving the rats into thejar and 5, 15, 30, and 60 min after they were returned to theirrecording cage. Silastic tubing was connected to the cardiac catheters,and the tubing was routed out of the cage. Thus the rats couldmove freely, and they were not disturbed by sampling. The dead-spacevolume was 0.15 ml. The lost volume was repleted by means of physiologicalsaline.

HYPOX rats are not anticipated to respond with Prl secretion to ether exposure. Therefore, Prl was determined in a singleblood sample obtained from the trunk by means of decapitationwith guillotine 5 min after a second ether exposure in these rats.In this way, implantation of the chronic catheter could be avoidedin the HYPOXrats.

Prl was determined in a single radioimmunoassay in duplicates. The blood was centrifuged, and the plasma was stored at $-$ 20°Cuntil assayed. The intra-assay coefficient of variation was <7%.The immunoreagents (rat Prl-AS: anti-rPrl-S-9; iodination graderat Prl antigen: rPrl-I-6; and rat Prl reference preparation:rPrl-RP-3) were provided by The National Hormone and PituitaryProgram(NIDDK).

Statistics. The mean values of the states of vigilance, SWA, and Tcrt calculated for 2-h periods were used in the statistics. SWA is presentedas deviation from baseline, but the statistical tests were alsoperformed on the absolute values. The states of vigilance, SWA,and Tcrt during the 12-h recording periods were compared by meansof two-way ANOVA for repeated measures between the recording daysin a group of rats. The treatment effect and the time effect (variationsacross the individual hours) were the two factors of the ANOVA.In general, the F statistics are only provided for the treatmenteffect and for the interactions between the treatment and thetime factors when statistically significant differences are noted,and significant variations in time are not discussed. Baselinevalues of REM sleep and NREM sleep were compared by ANOVA forindependent samples among the various groups recorded in the lightperiod. Differences in the mean duration and frequency of REM-sleepepochs were analyzed by means of one-way ANOVA for repeated measuresamong the 4 days of recording in the light-onset group and thedark-onset group. When several groups or more than 2 days werecompared, the Student-Newman-Keuls test was used for post hocanalysis to identify which group or day differed from other groupsor days. The changes in Prl after ether exposure were analyzedby means of ANOVA for repeated measures with respect to the baselineday. Plasma Prl concentrations 5 min after ether exposure werecompared by means of Student's t-test between the intact ratsand the HYPOX rats. An $alpha$ -level of P < 0.05 was considered to besignificant in alltests.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Changes in sleep after ether exposure in intact rats. The rats groomed vigorously for a few minutes after exposure to ether. Then, their behavior was normal and they were mostlyquiet. The time spent in the various states of vigilance in hour1 of the recording after ether exposure did not differ from thosevalues on any other day. Also, ether exposure did not alter thepower density values in the various frequency bands either inwakefulness or NREM sleep as determined in hour 1 of recordingin the light-onset group on the control day and the day with etherexposure. The changes in power densities during wakefulness afterether stress were as follows: delta band (0.5-4.0 Hz): $-$ 2.0 ±3.2%; theta band (4.5-7.5 Hz): +2.8 ± 3.6%; alpha band (8.0-12.0Hz): $-$ 4.2 ± 1.9%; and power densities from 12.0 to 20.0 Hz: $-$ 2.7± 1.6%. None of these changes were statistically significant,and in fact, the EEG lookednormal.

Figure 1 displays the amounts of the states of vigilance, SWA in NREM sleep, and courses of Tcrt for the light period andthe dark period in the light-onset group and the dark-onset group,respectively. The differences between the groups resulted fromthe normal diurnal variations.

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Fig. 1. Effects of 1-min exposure to ether vapor on intact rats on the duration of the states of sleep [rapid eye-movement sleep (REMS) and non-REM sleep (NREMS)], electroencephalograph slow-wave activity (SWA, power densities in the 0.25- to 4.0-Hz range) during NREMS, and brain cortical temperature (Tcrt). Mean ± SE values calculated for 2-h blocks are presented. Light-onset group (n = 14): ether exposure was done before light onset, and the recordings were taken during the 12-h light period. Dark-onset group (n = 11): ether exposure was done before dark onset, and recordings were taken during the dark period (top: horizontal bar marks the dark period). $triangle$ , day 1: the rats were undisturbed; $open circle$ , day 2: 1-min exposure to a jar without ether;

, day 3: 1-min exposure to ether vapor; and

, day 4: the rats were undisturbed. For SWA, percentage deviations from SWA values on day 1 are depicted.

Thus the time spent in NREM sleep and REM sleep were higher in the light period than in the dark period. REM sleep peakedduring the second portion of the light period. The time spentin NREM sleep declined slowly from the morning towards dark onset.Tcrt was lower during the day than at night. The sleep responseto ether exposure consisted of increases in REM sleep (Fig. 1).The amount of REM sleep varied among the 4 days of recording inboth the light-onset group [F(3,39) = 6.425, P < 0.05] and thedark-onset group [F(11,30) = 18.233, P < 0.05]. Post hoc Student-Newman-Keulstest indicated that it was day 3 (ether exposure) that differedfrom all the other days in both groups of rats, i.e., the amountsof REM sleep on day 1, day 2, and day 4 were alike. Despite thestatistical significance, there was some variability in the REM-sleepresponses among the rats. Compared with the baseline day (day1) and the control day (day 2: empty jar), REM sleep failed toincrease in 3 of 14 rats in the 12-h light period after etherexposure. The amount of REM sleep after ether exposure was lowerthan on the control day (day 2) but higher on the baseline day(day 1) in one rat in the dark-onsetgroup.

Increases in REM sleep began about 3-4 h after ether exposure (Fig. 1). In the light-onset group, maximum values of REM sleepwere observed between hours 6 and 8 of the recording, and REMsleep returned to baseline by the end of the light period. Inthe dark-onset group, the amount of REM sleep after ether exposureapproached values that were normally observed during the lightperiod. The time × treatment interaction was statistically significantfor the dark-onset group [F(15,150) = 1.85, P < 0.05]. Althoughincreases in REM sleep continued until the end of the dark period,REM sleep returned to normal in the first hour of the subsequentlight period (4.0 ± 1.47 and 5.29 ± 1.60% on the control day andon the ether day, respectively), and REM sleep calculated forthe 11-h light period was also normal (9.7 ± 0.82 and 9.3 ± 0.69%).Increases in the time spent in REM sleep resulted from an increasednumber of REM-sleep epochs in both the light-onset group and thedark-onset group [F(3,39) = 3.47, P < 0.05, and F(3,33) = 8.43,P < 0.05, respectively, with the ether-exposure day being differentfrom the other recording days] (Table 1). The mean duration ofindividual REM-sleep epochs tended to be slightly longer afterether exposure than on the other days, but these differences werenot statistically significant.

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Table 1. Mean frequency and duration of REM-sleep epochs during 12 h of recording

There were no significant differences in NREM sleep among the 4 days of recording in that the ether exposure did not significantlyalter NREM sleep in either group of rats (Fig. 1). Nevertheless,NREM sleep tended to decrease on day 4 (the day after ether exposure)in the light-onset group. SWA during NREM sleep differed amongthe 4 days in the light-onset group [F(3,39) = 3.06, P < 0.05]due to significant decreases in SWA on day 4 (Student-Newman-Keulstest). No such differences in SWA were observed in the dark-onsetgroup. Significant differences in Tcrt were not detected amongthe 4days.

Changes in Prl after ether exposure. Exposure to ether significantly stimulated Prl secretion [F(1,8) = 8.99, P < 0.05]; the effect varied with time [F(4,32) =3.91, P < 0.05]. Prl was already increased in the sample taken5 min after ether exposure (Fig. 2). Although Prl started to declinethereafter, it stayed above baseline for 30 to 60 min.

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Fig. 2. Effects of ether exposure on plasma prolactin (Prl) concentrations (mean ± SE) in 10 intact rats. $open circle$ : Exposure to a jar without ether.

: Ether stress. The rats were moved into the jar with or without ether immediately after the first blood withdrawal at time 0.

Response to ether exposure in HYPOX rats. ANOVA was used to compare the time spent in REM sleep among the control days in all groups of rats studied in the light period,including day 2 of the light-onset group reported above. Therewere significant differences among the groups [F(4,35) = 5.82,P < 0.05] with REM sleep being significantly less in the HYPOXrats than in any other groups (Table 2). In contrast, NREM sleepwas normal in the HYPOX rats. Ether exposure failed to alter REMsleep, NREM sleep, or SWA (not shown) in the HYPOX rats (Fig.3, Table 2). The four intact rats maintained at 29-30°C and providedwith 5% glucose in drinking water had an increased amount of REMsleep on the control day (mean ± SE: 13.9 ± 1.0% recording time),but each of them responded with increases in REM sleep to etherexposure producing a group mean of 16.5 ± 1.2% amount of REM sleep.

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Table 2. Mean duration of sleep states (% recording time) during 12-h light period on control day and experimental day

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Fig. 3. REMS in hypophysectomized rats (HYPOX, n = 7; A) and partially HYPOX rats (n = 3; B) after 1-min exposure to an empty jar on the control day ( $open circle$ ) and after exposure to ether vapor (

) on the experimental day. Mean ± SE values are presented.

The plasma Prl concentration was 2.6 ± 0.4 ng/ml in the HYPOX rats 5 min after ether exposure. This value was significantlyless (Student's t-test) than the concentration of Prl after etherexposure (13.7 ± 2.0 ng/ml) or on the control day (7.6 ± 0.8 ng/ml)at the same time point in the intact rats (Fig. 2). Prl concentrationafter ether exposure varied greatly in the three rats in whichpost mortem examination indicated partial hypophysectomy (8.5,11.9, and 63.7 ng/ml), but each value was in or above the rangeof stimulated Prl secretion in the intact rats at the same timepoint. The mean amount of REM sleep and NREM sleep in the partiallyHYPOX rats is shown in Fig. 3 and Table 2, although this groupwas not included in the statistical analysis due to the low samplesize. Baseline REM sleep in the partially HYPOX rats was as lowas in the HYPOX group. Unlike the HYPOX rats, however, each partiallyHYPOX rat responded with increases in REM sleep to etherexposure.

Ether exposure after Prl-AS. Intracerebroventricular injections caused fever irrespective of the nature of the solution; physiological saline, normal rabbitserum, or Prl-AS. Figure 4 depicts Tcrt values in the groups injectedwith normal rabbit serum or Prl-AS with or without ether exposure.REM sleep was suppressed during the hyperthermic period, i.e.,for 4-6 h, on both the control and the experimental days in eachgroup. In contrast, NREM sleep tended to increase in these rats,although the changes did not reach the level of statistical significance(Table 2).

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Fig. 4. Effects of intracerebroventricular injections of normal rabbit serum (normal serum + ether, n = 5; A) and antiserum to Prl (Prl-AS + ether, n = 6; B) on the responses of REMS and Tcrt to ether exposure and changes in spontaneous REMS and Tcrt in rats after intracerebroventricular administration of Prl-AS without ether exposure (Prl-AS-no ether, n = 6; C). The rats stressed with ether on the experimental day (

) received intracerebroventricular injections of pyrogen-free physiological saline and were exposed to an empty jar on the control day ( $open circle$ ). The rats injected with Prl-AS without ether exposure on the experimental day (

) also received intracerebroventricular physiological saline on the control day ( $open circle$ ). Values are means ± SE.

Exposure to ether promoted REM in the rats injected with normal rabbit serum [F(1,4) = 9.327, P < 0.05] (Fig. 4, Table 2).In contrast, ether exposure failed to stimulate REM sleep in thegroup injected with Prl-AS (Fig. 4, Table 2). In fact, decreasesin REM sleep were observed in five of six rats, although thesechanges analyzed by ANOVA did not reach the level of statisticalsignificance [F(1,5) = 2.936, P = 0.1]. REM sleep also decreasedin the rats that received Prl-AS without ether exposure (Fig.4, Table 2). The changes in REM sleep after Prl-AS with or withoutether exposure were of similar magnitude, but the reduction inREM sleep in the later group was statistically significant [F(1,8)= 7.83, P < 0.05].

With respect to saline baseline, NREM sleep and SWA (not shown) were not altered after normal rabbit serum or Prl-AS withor without ether exposure (Table 2).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

A brief ether exposure promotes REM sleep. This finding is consistent with reports on the effects of another stressor, acuteimmobilization, on REM sleep in rats in that the increases inREM sleep result from an increase of the frequency of REM-sleepepochs (4, 6, 13), and the changes in REM sleep occurmostly within 12 h after exposure to the stressor (6). Furthermore,like in the experiments with immobilization (6, 30), a fewrats failed to respond with increases in REM sleep to ether vaporin our studies. In the current experiments, ether exposure selectivelystimulated REM sleep; NREM sleep was not altered. Similar findingsare often observed after immobilization (13, 30). Nevertheless,possible long-term changes in NREM sleep cannot be excluded asindicated by the decreases in NREM-sleep intensity 1 day afterthe exposure to ether. The explanation and the biological significanceof this finding is currently not clear. Finally, current findingsindicate that ether exposure could also be used to stimulate REMsleep when applied just before the light period without significantsleep loss during the exposure to the stressor. It is noted thatmanipulation of rats before light onset also means that the ratswere exposed to a brief light exposure when they were moved intothe jar or when intracerebroventricular injections were administered.These treatments, however, did not differ between the controland the experimental days, and therefore the changes in REM sleepafter ether exposure were not due to a phase advance of the diurnalrhythm of REMsleep.

Our idea that Prl might be involved in the mediation of the stressor-induced enhancements in REM sleep is on the basis ofseveral observations as follows. Increases in REM sleep afterether exposure develop slowly, over a period of several hours,and culminate long after the acute stressor is over. This timecourse suggests an action that involves several metabolic stepsrather than a direct neurotransmitter-mediated effect. A similartime course is observed for the increases in REM sleep inducedby systemic administration of Prl (27, 33). Further in ourexperiments, Prl secretion in response to ether exposure was verified(11, 17, 23). Prl is transported into the cerebrospinalfluid by a receptor-mediated mechanism residing in the choroidplexus (38). The expression of the Prl transporter is stimulatedby Prl itself (18) resulting in enhanced intracerebral Prl concentrationswhen systemic Prl is increased. Stress-associated rises in Prlsecretion, e.g., Prl release induced by a 30-min immobilization,are effective in promoting the expression of the Prl transporterin the rat (10). Hypophysectomy and the administration of Prl-ASwere two approaches used to estimate the possible contributionof Prl to promotion of REM sleep after exposure to ether. Althoughcaution is required in the interpretation of the results of theindividual experiments, collectively, the findings support aninvolvement of Prl in the REM-sleepalterations.

Spontaneous REM sleep was significantly reduced, whereas NREM sleep was normal in the HYPOX rats. The literature on sleepalterations in HYPOX rats varies. In a previous experiment inour laboratories, HYPOX rats exhibited decreased NREM sleep andnormal REM sleep; the hypophysectomy was verified by means ofundetectable growth hormone (GH) in systemic blood (24). HYPOXrats, however, were also reported to have decreased or normalREM sleep and decreased, normal, or increased NREM sleep (37,41, 42). The time elapsed between hypophysectomy and recordingmight contribute to the divergent findings. The rats studied inour previous experiments (24) were HYPOX 1 to 2 mo before thesleep recording. Some metabolic alterations might be compensated,whereas others might result in chronic deficiency during sucha long period. Valatx et al. (37) demonstrate that the amountof REM sleep is practically normalized 30 days after surgery inHYPOX rats if these rats are recorded at 30°C instead of normalroom temperature. Our rats were recorded in a relatively earlystage after the removal of the pituitary because the low baselinePrl-like activity in the acutely HYPOX rats rises up to 50% ofnormal levels after several weeks (22). Small nests of Prl-producingcells are believed to be the source of this Prl; these cells remainin the sella turcica after any method of hypophysectomy (40).Low concentrations of Prl were, in fact, detected in our HYPOXrats after ether exposure, but these Prl levels were only one-thirdof the baseline Prl measured in intact rats without ether stress.Exposure to ether vapor did not promote REM sleep in the HYPOXrats. The absence of REM-sleep responses in the HYPOX rats wasnot due to the glucose supplement and relatively high ambienttemperature for both the partially HYPOX rats and the group ofintact rats maintained at the same conditions as the HYPOX ratsexhibited increases in REM sleep after ether exposure. Stimulationof REM sleep occurred in the intact rats despite an already enhancedREM sleep on the control day at 29-30°C, the ambient temperatureat which REM sleep normally peaks in rats (36). Our findingindicates that the presence of the pituitary is important forthe effects on REM sleep, but it does not necessarily imply thatPrl is involved. The bulk of the pituitary was also removed inthe partially HYPOX rats. The low-baseline amount of REM sleepindicated that these rats had the same fundamental deficienciesas the HYPOX rats. Nevertheless, the capacity of the remainingcells to release Prl on stress was obviously enough to producehigh plasma Prl concentrations in the partially HYPOX rats. Adecreased activation of the ACTH-corticosterone axis may promotePrl secretion in the partially HYPOX rats for corticosterone attenuatesPrl release in intact rats (11). Not only Prl secretion, butalso REM sleep was enhanced in response to ether exposure in thepartially HYPOX rats. These findings suggest that a rise in plasmaPrl might be necessary for the stimulation of REM sleep afterexposure toether.

The immunoneutralizaton of Prl inhibited the increases in REM sleep after ether exposure. There are, however, two complicatingfactors that have to be considered in the interpretation of theresults. First, Prl-AS decreased spontaneous REM sleep in theabsence of exposure to ether vapor. Thus low-REM sleep after etherexposure might result from an inhibition of spontaneous REM sleep.Second, the intracerebroventricular injections of a serum mayalter REM sleep independently of Prl, e.g., viafever.

The decreases in spontaneous REM sleep after Prl-AS in rats without ether exposure correspond to previous observations afterintrahypothalamic injection of Prl-AS (34), and they may resultfrom the removal of the REM sleep-promoting activity of intraneuronalPrl (31). The major aim of Prl-AS injections in the currentexperiment was the inhibition of Prl entering the brain from thesystemic circulation but, of course, immunoneutralization of intraneuronalPrl could not be avoided. A very high dose of Prl-AS was thereforeinjected; in fact, the dose of Prl-AS in our studies was largeenough to suppress systemic Prl after leakage into the pituitarycirculation (21). The decreases in REM sleep were of the samemagnitude in the rats injected with Prl-AS with and without exposureto ether vapor. Thus inhibition of ether stress-associated promotionof REM sleep is not attributed to the low spontaneous REM sleepin the rats injected with Prl-AS.

The intracerebroventricular injections caused fever, NREM sleep tended to increase, and REM sleep tended to decrease in theserats. The large dose of Prl-AS required large volumes of intracerebroventricularinjections that can induce sleep alterations in the rat (5).In addition, because the injection cannula was 0.5 mm longer thanthe implanted guide cannula, microlesions by the tip of the cannulamight also cause fever. Increases in NREM sleep and suppressionof REM sleep are characteristic responses to cytokine release(16). Fever was also observed after physiological saline administrationon the baseline days, and it did not interfere with the promotionof REM sleep after ether exposure in the rats injected with normalrabbit serum. Thus the inhibition of promotion of REM sleep afterether exposure is attributed to the neutralization of Prl-likeimmunoreactivity and not to some nonspecific actions of the Prl-AS.

The similarities in the sleep responses to ether exposure and acute immobilization and the fact that immobilization stressis associated with Prl releases (e.g., Ref. 1) open up thepossibility that Prl may also contribute to REM-sleep promotionafter immobilization in the rat. Currently, different substancesare implicated in the mechanism of stimulation of REM sleep byimmobilization. Corticotropin-like intermediate lobe peptide (CLIP)injected into the dorsal raphe nuclei promotes REM sleep (9).Bonnet et al. (4) report that CLIP-like activity increasesin the dorsal raphe nuclei in rats subjected to immobilization.The authors suggest that CLIPergic neurons projecting from thearcuate nucleus to the raphe are activated during stress and maymediate the increases in REM sleep. González and Valatx (13)showed that corticotropin-releasing hormone (CRH) has a key rolein the immobilization-induced enhancements in REM sleep becauseintracerebroventricular administration of a CRH antagonist blocksthe sleep response. These authors proposed that CRH acts on REMsleep via the locus ceruleus. The importance of the various REMsleep-promoting mechanisms may vary with the type of stressor,and it is possible that these mechanisms are related. For example,CRH is involved in stress-associated Prl secretion because inhibitionof CRH suppresses the Prl response to stessors (1).

Perspectives

It is not known how Prl stimulates REM sleep. Our speculation is that the site of the action is in the brain stem becausePrl continues to enhance REM sleep-like activity in cats withmesencephalic transection (15). Expression of Prl receptorsis well-documented in the forebrain (e.g., Refs. 2, 32),but Prl receptors are also reported in pons and medulla (35)and the ventral tegmental area of the mesencephalon (32). Thelong latency of the REM-sleep response to Prl suggests that thesleep effects are mediated by some metabolic actions. Stimulationof pyruvate dehydrogenase by Prl in cholinergic neurons is a likelycandidate. Increased pyruvate dehydrogenase activity may resultin enhancements in REM sleep (14) due to the increased availabilityof acetylcholine in the brain stem neurons involved in the genesisof REM sleep. Prl, in fact, stimulates pyruvate dehydrogenasein some peripheral tissues (8, 39), and preliminary findingsin our laboratory indicate that it may also do so in the brainstem. Regardless of these possibilities, current results are consistentwith the hypothesis that increases in REM sleep after ether exposureare mediated in part by Prl. The mechanism outlined above is apermissive action by Prl on REM sleep, and in that case CLIP couldprovide the trigger that eventually results in increases in REMsleep after astressor.

	ACKNOWLEDGEMENTS

The authors thank Dr. G. B. Makara (Institute of Experimental Medicine, Budapest, Hungary) for the help in hypophysectomyand S. Tóth for the technicalassistance.

	FOOTNOTES

This work was supported by ETT-627/1996-04 and OTKA-T0-30456 to F. Obál Jr. and by the National Institutes of Health GrantNS-27250 to J. M.Krueger.

Permanent address of J. Gardi: Endocrine Unit, Albert Szent-Györgyi Medical University, 6720 Szeged,Hungary.

Address for reprint requests and other correspondence: J. M. Krueger, 205 Wegner Hall, Dept. of Veterinary and ComparativeAnatomy, Pharmacology and Physiology, Washington State Univ.,Pullman, WA 99164-6520 (E-mail: krueger{at}vetmed.wsu.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 8 March 2000; accepted in final form 3 July 2000.

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