Interleukin-13 and transforming growth factor-beta 1 inhibit spontaneous sleep in rabbits

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Interleukin-13 and transforming growth factor- $beta$ 1 inhibit spontaneous sleep in rabbits

Takeshi Kubota, Jidong Fang, Tetsuya Kushikata, and James M. Krueger

Washington State University, College of Veterinary Medicine, Department of Veterinary and Comparative Anatomy, Pharmacology and Physiology, Pullman, Washington 99164

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Proinflammatory cytokines, including interleukin-1 $beta$ and tumor necrosis factor- $alpha$ are involved in physiological sleep regulation.Interleukin (IL)-13 and transforming growth factor (TGF)- $beta$ 1 areanti-inflammatory cytokines that inhibit proinflammatory cytokinesby several mechanisms. Therefore, we hypothesized that IL-13 andTGF- $beta$ 1 could attenuate sleep in rabbits. Three doses of IL-13(8, 40, and 200 ng) and TGF- $beta$ 1 (40, 100, and 200 ng) were injectedintracerebroventricularly 3 h after the beginning of the lightperiod. In addition, one dose of IL-13 (200 ng) and one dose ofTGF- $beta$ 1 (200 ng) were injected at dark onset. The two higher dosesof IL-13 and the highest dose of TGF- $beta$ 1 significantly inhibitedspontanenous non-rapid eye movement sleep (NREMS) when they weregiven in the light period. IL-13 also inhibited NREMS after darkonset administration; however, the inhibitory effect was lesspotent than that observed after light period administration. The40-ng dose of IL-13 inhibited REMS duration during the dark period.TGF- $beta$ 1 administered at dark onset had no effect on sleep. Thesedata provide additional evidence for the hypothesis that a braincytokine network is involved in regulation of physiologicalsleep.

non-rapid eye movement sleep; electroencephalogram; cytokine; brain

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

SLEEP IS REGULATED, in part, by humoral mechanisms. The proinflammatory cytokines such as interleukin (IL)-1 $beta$ and tumor necrosisfactor (TNF)- $alpha$ are involved in physiological sleep regulation(reviewed in Ref. 23). Administration of IL-1 $beta$ (13, 35,46) or TNF- $alpha$ (14, 19, 46) increases non-rapid eye movementsleep (NREMS), and inhibition of IL-1 $beta$ (18, 38, 39, 51)or TNF- $alpha$ (50, 52-54, 56) inhibits NREMS in a variety of species.IL-4, IL-10, IL-13, and transforming growth factor (TGF)- $beta$ 1 areclassified as anti-inflammatory cytokines (reviewed in Refs. 21and 22). Previously, we showed that IL-4 (27) and IL-10 (26)inhibit NREMS in rabbits after intracerebroventricular administration.Moreover, IL-10 inhibits NREMS in rats (40). However, the effectsof IL-13 and TGF- $beta$ 1 on sleep have not yet beenreported.

IL-13 is considered to be an important macrophage-deactivating factor. IL-13 shares many of its biological functions withIL-4. They have a 20-25% homology in their amino acid structure.Moreover, IL-13 and IL-4 receptors involve a common component,IL-4R $alpha$ (reviewed in 3). IL-13 suppresses IL-1 $beta$ and TNF- $alpha$ productionin vitro (5, 9, 61). Some in vivo studies also demonstratethat IL-13 inhibits LPS-induced TNF- $alpha$ and IL-1 $beta$ production inmice (10, 34). Moreover, IL-13 promotes the production ofadditional anti-inflammatory substances including the IL-1 receptorantagonist (9, 33, 59, 61) and the IL-1 type II receptor(4).

TGF- $beta$ 1 is an important regulator of immune and inflammatory processes in the central nervous system (CNS) (reviewed in Ref.30). TGF- $beta$ 1 is part of a complex network that forms a negative-feedbacksystem for IL-1 and TNF- $alpha$ production (43). IL-1 stimulates TGF- $beta$ 1expression in glial cells (7). Conversely, TGF- $beta$ 1 suppressesmicroglial activation, proliferation, and IL-1 $beta$ and TNF- $alpha$ production(47). TGF- $beta$ 1 also inhibits IL-1 $beta$ -induced cellular inflammationin the retina (6). Furthermore, TGF- $beta$ receptor mRNAs and proteinsare present in the CNS (60).

These findings suggest that IL-13 and TGF- $beta$ 1 could modulate endogenous sleep regulatory substances and, thereby, affect sleep.We report here that IL-13 and TGF- $beta$ 1 inhibit rabbit NREMS withoutaffecting brain temperature (Tbr) and electroencephalographic(EEG) slow-wave activity(SWA).

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Agents. Recombinant human IL-13 and TGF- $beta$ 1 were purchased from R&D Systems (Minneapolis, MN). IL-13 was dissolved in pyrogen-freeisotonic NaCl (PFS; Abbott Laboratories, North Chicago, IL) atthe concentrations of 8, 40, and 200 ng in volumes of 25 µl. TGF- $beta$ 1was dissolved in 25 µl PFS at the doses of 40, 100, and 200 ng.They were stored under sterile conditions at $-$ 80°C until theexperiment.

Animals. Male New Zealand White Pasteurella-free rabbits weighing 3.5-4.5 kg were surgically implanted with EEG electrodes, a brainthermistor, and a lateral intracerebroventricular cannula underketamine-xylazine anesthesia as previously described (26, 27).Briefly, the guide cannula was placed in the left lateral ventriclefor intracerebroventricular injection. A calibrated 30-k $Omega$ thermistor(model 44008; Omega Engineering, Stamford, CT) was implanted onthe dura mater over the parietal cortex to measure Tbr. The leadsfrom the electrodes and the thermistor were routed to a Teflonpedestal. The pedestal, guide cannula, and leads were attachedto the skull with dental acrylic (Duz-All; Coralite Dental Products,Skokie, IL). After at least 2 wk of recovery, the animals wereplaced in experimental chambers (Hot Pack 352600, Philadelphia,PA). The animals were kept on a 12:12-h light-dark cycle (0600light on) at 21 ± 1°C ambient temperature. Water and food weread libitum throughout theexperiment.

Recording and analysis. A flexible tether connecting the EEG electrodes and the thermistor was led to an electronic swivel (SL6C, Plastics One, Roanoke,VA). Body movements were detected by ultrasonic detectors (BiochemicalInstrumentation, University of Tennessee). The leads from theswivel and movement detectors were routed to Grass model 7D polygraphsin an adjacent room. The EEG was filtered below 0.1 Hz and above35 Hz. The amplified signals were digitized at the frequency of128 Hz for the EEG and at 2 Hz for Tbr and motor activity. Tbrdata were saved on a computer in 10-s intervals. The vigilancestates of wakefulness, NREMS and rapid eye movement sleep (REMS)were visually determined offline in 10-s epochs by using criteriapreviously reported (26, 27). In brief, wakefulness was characterizedby fast low-amplitude EEG waves, gradually increasing Tbr, anda high incidence of gross body movements. NREMS was associatedwith slow high-amplitude EEG waves, slowly decreasing Tbr, andlack of body movements. In contrast, REMS was characterized byfast low-amplitude EEG waves, appearance of theta activity inthe EEG, rapidly increasing Tbr at REMS onset, and a lack of bodymovement. Online Fourier analysis of the EEG was performed. Theaverage of EEG power density in the delta frequency band (0.5-4.0Hz) during NREMS, also called EEG SWA, was calculated. The averagepower of EEG SWA throughout the entire 23-h control recordingperiod was normalized to 100% for each animal. Then all EEG SWAdata were expressed as a percentage of that control value. Theaverage amount of time spent in each vigilance state, EEG SWA,and Tbr were calculated for 2-h intervals for purposes of graphicdisplay (Figs. 1 and 2). In addition, the number of NREMS andREMS episodes, the mean episode length, and mean length of sleepcycles (R-R interval: time between the onset of a REMS episodeand the onset of the next REMS episode) were determined usinga computer program with the criterion that each REMS episode lastedat least 30 s.

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Fig. 1. Effects of intracerebroventricular injection of interleukin-13 (IL-13) on the time spent in non-rapid eye movement sleep (NREMS) and rapid eye movement sleep (REMS), electroencephalograph (EEG) slow-wave activity (SWA) and brain temperature (Tbr). $open circle$ , Vehicle treatment group;

, IL-13 treatment group. Horizontal shaded bars denote dark phase. IL-13 (200 ng) was injected either during the light phase (A) or at dark onset (B). IL-13 significantly inhibited NREMS. All data shown are averages obtained from 2-h intervals and expressed as means ± SE.

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Fig. 2. Effects of intracerebroventricular injection of transforming growth factor- $beta$ 1 (TGF- $beta$ 1) on time spent in NREMS, REMS, EEG SWA, and Tbr. $open circle$ , vehicle treatment group;

, TGF- $beta$ 1 treatment group. TGF- $beta$ 1 (200 ng) was injected either during light phase (A) or at dark onset (B). TGF- $beta$ 1 significantly inhibited NREMS when given during light phase; however, it failed to affect NREMS if injected at dark onset. All data shown are averages obtained from 2-h time blocks ± SE.

Experimental protocols. Each rabbit was injected with 25 µl PFS intracerebroventricularly on a separate control day. If a rabbit was used more thanonce, at least 7 days separated the injections, and a separatecontrol day recording was obtained. In experiment 1, 12 rabbitswere used. Rabbits received one to three doses of IL-13 duringthe light period: 8 (n = 7), 40 (n = 8), and 200 ng (n = 8). Injectionstook place between 0845 and 0915. Eight rabbits received 200 ngof IL-13 at dark onset (1800). In experiment 2, a different setof 12 rabbits was used. Rabbits were injected with one to threedoses of TGF- $beta$ 1 during light period (0845-0915): 40 (n = 8), 100(n = 7), and 200 ng (n = 8) on the experimental day. Nine rabbitsreceived 200 ng of TGF- $beta$ 1 at dark onset (1800). After injections,EEG, Tbr, and motor activity were recorded for the next 23h.

Statistical analysis. Two-way ANOVA for repeated measures followed by a Student-Newman-Keuls test was used to analyze data concerning time spentat each vigilance state, EEG SWA, and Tbr; 3-h time blocks wereused for these analyses. For the sleep-episode data, one-way ANOVAfor repeated measures was used for the entire 23-h period, the9-h light period between the time of injection and the dark period,and the 12-h dark period. A significance level of P < 0.05 wasaccepted.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Experiment 1: effects of IL-13 on spontaneous sleep in rabbits. The lowest dose of IL-13, 8 ng, failed to affect any of the sleep parameters measured (Table 1). In contrast, the two higherdoses of IL-13 administered during the light period significantlyinhibited NREMS [ANOVA treatment effects for the entire 23-h postinjectionperiod: 40 ng, F(1,7) = 15.79, P = 0.0054; 200 ng, F(1,7) = 7.04,P = 0.0325; ANOVA treatment effects for the 12-h dark period:40 ng, F(1,7) = 11.61, P = 0.0113; 200 ng, F(1,7) = 7.28, P =0.0307; Table 1 and Fig. 1]. The NREMS inhibitory effect duringthe dark period was due to a decrease in the number of NREMS episodes[ANOVA for the 12-h dark period: 200 ng, F(1,7) = 9.70, P = 0.0170;Table 2]. The decreases in NREMS during the initial 9-h lightperiod did not reach significance after any dose. The 200-ng dosegiven at dark onset also inhibited NREMS; however, it was lesseffective than the same dose given during the light period [ANOVAtreatment effects for the 23-h postinjection period: F(1,7) =17.36, P = 0.0042; Table 1 and Fig. 1]. This effect was alsodue to a decrease in the number of NREMS episodes [ANOVA for 23h: F(1,7) = 6.35, P = 0.0398; Table 2]. REMS was inhibited duringthe dark period after the 40-ng dose of IL-13 [ANOVA for the 12-hdark period: F(1,7) = 9.94, P = 0.0161], and it was due to a decreasein the number of REMS episodes [ANOVA for 12 h: F(1,7) = 13.5,P = 0.0080]. As a result, a significant increase in the sleep-cyclelength (R-R interval) was observed [ANOVA for 23 h: F(1,7) = 5.80,P = 0.0469; Tables 1 and 3]. Although a significant decreasein the total amount of time in REMS was not found after 200 ngof IL-13 administration at dark onset, the number of REMS episodesduring the dark period was significantly inhibited [ANOVA forthe 12-h dark period: F(1,7) = 9.21, P = 0.0188; Table 3]. EEGSWA and Tbr were not affected by any of the IL-13 doses tested.Furthermore, IL-13 did not induce gross abnormal behavior; animalsappeared normal when handled, and no motor abnormalities wereevident.

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Table 1. Effects of interleukin-13 and transforming growth factor- $beta$ 1 on spontaneous sleep in rabbits

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Table 2. Effects of IL-13 and TGF- $beta$ 1 on NREMS cycles

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Table 3. Effects of IL-13 and TGF- $beta$ 1 on REMS cycles

Experiment 2: effects of TGF- $beta$ 1 on spontaneous sleep in rabbits. The lowest dose of TGF- $beta$ 1 did not affect any of the sleep parameters measured. The middle dose of TGF- $beta$ 1 decreased the amountof time spent in NREMS, but this effect did not reach significance[ANOVA treatment effect for the 23-h postinjection period: F(1,6)= 4.84, P = 0.0701]. The highest dose of TGF- $beta$ 1 significantlydecreased time spent in NREMS [ANOVA treatment effect for 23 h:F(1,7) = 15.58, P = 0.0056; for the initial 9 h: F(1,7) = 9.84,P = 0.0164], and it was due to a decrease in the duration of NREMSepisodes [ANOVA for 23 h: F(1,7) = 11.20, P = 0.0122; for theinitial 9 h: F(1,7) = 10.50, P = 0.0141; Tables 1 and 2]. The200-ng dose given at dark onset inhibited NREMS in the light period;however, this effect did not reach significance [ANOVA treatmenteffect for the 11-h light period: F(1,8) = 4.20, P = 0.0744; Table1]. REMS, EEG SWA, and Tbr were not affected by any of the TGF- $beta$ 1doses given. Furthermore, abnormal behavior was not observed afterany dose of TGF- $beta$ 1.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The major finding in the present study is that both IL-13 and TGF- $beta$ 1 inhibit NREMS. These effects are similar to those wepreviously reported for IL-4 and IL-10 (26, 27). These inhibitoryactions are likely due to inhibition of production of endogenoussleep regulatory substances such as IL-1 $beta$ , TNF- $alpha$ , and nitric oxide(NO). IL-13 (5, 9, 10, 34, 61) and TGF- $beta$ 1 (47) suppressIL-1 $beta$ and TNF- $alpha$ production. They inhibit the expression of theinducible NO synthase, a rate-limiting enzyme for the productionof NO (1, 31). IL-4 (1, 20, 29, 32) and IL-10 (12,15, 28, 57) also have theseproperties.

The present study also shows that injections of IL-13 and TGF- $beta$ 1 at dark onset are less effective than injections in the lightperiod. We also reported that IL-4 and IL-10 had no inhibitoryeffects after dark-onset administration (26, 27). Normally,IL-1 $beta$ mRNA and TNF- $alpha$ mRNA levels are lowest at dark onset, hencetheir productions at that time are likely low (17, 48). Therefore,it is possible that the inhibitory effects of IL-13 or TGF- $beta$ 1on IL-1 $beta$ and TNF- $alpha$ production may be less potent during the darkperiod. The onset of inhibitory effects on NREMS induced by IL-13and TGF- $beta$ 1 is shorter than that observed in IL-4 and IL-10. Thesleep-inhibitory effects of IL-4 and IL-10 are not manifesteduntil 8-10 h after their administration (26, 27). There areseveral possibilities for this difference. For example, it ispossible that the times for diffusion of these inhibitory cytokinesto effective sites can be different, because the location of thesesites are still obscure. As another possibility, it may due tothe stimulation of production of sleep-inhibitory substances suchas receptor antagonists or soluble receptors for IL-1 $beta$ and TNF- $alpha$ by inhibitory cytokines. Administration of substances that bindIL-1 or TNF rapidly, such as antibodies and soluble receptorsfor IL-1 $beta$ (36, 51) and TNF- $alpha$ (50, 52, 53, 57), inhibitNREMS within the first postinjection hour. Thus, if the abilityof IL-13 or TGF- $beta$ 1 to induce production of these inhibitory substancesis relatively rapid, then the latency for NREMS inhibitory effectscould be shorter. Although the time course for this effect isunclear, IL-13 promotes the production of the IL-1 type II receptor,a decoy receptor (4), as well as the IL-1 receptor antagonist(9, 33, 59, 61). TGF- $beta$ can also antagonize the effectsof IL-1 $beta$ by increasing the expression of the IL-1 receptor antagonist(58) as well as decreasing cell surface expression of IL-1 receptors(11, 44). It is likely that the NREMS inhibitory effects ofIL-13 and TGF- $beta$ 1 result from one or more of thesemechanisms.

Although the present study did not show clear dose-dependent inhibition of REMS, IL-13 slightly inhibited REMS. It is thoughtthat sleep-regulatory mechanisms of REMS are different from thoseof NREMS. In cats, microinjection of NO synthase inhibitors intothe pedunculopontine tegmental area reduces REMS as well as NREMS(8). Therefore, brain stem NO ergic mechanisms could be implicatedin the inhibitory effect of REMS by IL-13. Although we did notshow any inhibitory effect for REMS by TGF- $beta$ 1, it is possiblethat the doses used in this study were insufficient to reveala REMS-inhibitory effect; as mentioned above, TGF- $beta$ 1 also inhibitsNO production. We previously reported that IL-4 and IL-10 inhibitedREMS only in the highest doses used (26, 27). These resultssuggest that the doses of inhibitory cytokines required for REMSinhibition are higher than those needed for NREMSinhibition.

In the present study, neither IL-13 nor TGF- $beta$ 1 affected EEG SWA. Previously, we reported that IL-4 and IL-10 also did notaffect EEG SWA (26, 27). Therefore, we can conclude that thoseanti-inflammatory cytokines tested thus far do not change EEGSWA in the doses that reduce NREMS. EEG SWA reflects the intensityof NREMS under many conditions (41). For example, EEG SWA ismarkedly increased during the deep sleep occurring after sleepdeprivation (42). IL-1 $beta$ and TNF- $alpha$ are involved in this effectbecause sleep deprivation-enhanced EEG SWA is attenuated if animalsare pretreated with inhibitors if IL-1 or TNF (37, 49, 53).The reason why IL-4, IL-10, IL-13, or TGF- $beta$ 1 does not inhibitspontaneous EEG SWA remains unclear. However, the mechanisms responsiblefor EEG SWA are different from those responsible for NREMS, andthus it is reasonable to expect that these parameters can varyindependently in some experimental conditions. For example, neurotrophin1 and 2 promote NREMS but slightly decrease EEG SWA (25, 55).Benzodiazepine hypnotics promote NREMS with decreases in EEG SWA.A benzodiazepine-receptor antagonist antagonizes drug-inducedNREMS but does not antagonize the effect on EEG SWA (reviewedin Ref. 2). The diurnal rhythms of NREMS in rats allowed foodintake only during daylight hour shifts to one characterized bymore NREMS during the dark than during the day; the rhythms ofEEG SWA are not changed by restricted food intake (45). Furthermore,it is also possible that the mechanisms responsible for durationof NREMS and EEG SWA may have different thresholds for the inhibitoryeffects of IL-13 and TGF- $beta$ 1.

IL-13 and TGF- $beta$ 1 failed to affect Tbr. These data are also consistent with those obtained after IL-4 and IL-10 treatment (26,27). Tbr is coupled to sleep states, but there are many conditionsin which they are not tightly linked. For example, antipyreticsantagonize IL-1-induced fever, but not sleep responses. In contrast,inhibitors of NO synthase block IL-1 $beta$ -induced sleep response,but not fevers (reviewed in Ref. 24). The lack of effect ofIL-13 and TGF- $beta$ 1 on Tbr at the doses that inhibit NREMS suggeststhat proinflammatory cytokines may have little effect in the regulationof normal bodytemperature.

The physiological functions of IL-13 in peripheral tissue have been studied; however, the function of IL-13 in the CNS hasnot yet been elucidated. TGF- $beta$ 1 is involved in cell growth, differentiation,adhesion, and proliferation in the CNS; however, it is expressedmainly in pathological conditions during adulthood (reviewed inRef. 16). Therefore, we cannot conclude that these cytokinesare involved in physiological sleep regulation. However, currentdata support the hypothesis that the cytokine network in the brainplays an important role in physiological sleepregulation.

	ACKNOWLEDGEMENTS

We thank Richard A. Brown for expertise in animalcare.

	FOOTNOTES

This work was supported, in part, by grants from the National Institutes of Health (NS-25378, NS-31453, and HD-36520).

Address for reprint requests and other correspondence: J. M. Krueger, P.O. BOX 646520, 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.§1734 solely to indicate thisfact.

Received 2 February 2000; accepted in final form 27 March 2000.

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Interleukin-13 and transforming growth factor-1 inhibit spontaneous sleep in rabbits

Interleukin-13 and transforming growth factor- $beta$ 1 inhibit spontaneous sleep in rabbits