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Department of Veterinary and Comparative Anatomy, Pharmacology and Physiology, Washington State University, Pullman, Washington 99164
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Various growth factors are involved in sleep regulation. Brain-derived neurotrophic factor (BDNF) belongs to the neurotrophin family; it and its receptors are found in normal brain. Furthermore, cerebral cortical levels of BDNF mRNA have a diurnal variation and increase after sleep deprivation. Therefore, we investigated whether BDNF would promote sleep. Twenty-four male Sprague-Dawley rats (320-380 g) and 25 male New Zealand White rabbits (4.5-5.5 kg) were surgically implanted with electroencephalographic (EEG) electrodes, a brain thermistor, and a lateral intracerebroventricular cannula. The animals were injected intracerebroventricularly with pyrogen-free saline and, on a separate day, one of the following doses of BDNF: 25 or 250 ng in rabbits; 10, 50, or 250 ng in rats. The EEG, brain temperature, and motor activity were recorded for 23 h after the intracerebroventricular injections. BDNF increased time spent in non-rapid eye movement sleep (NREMS) in rats and rabbits and REMS in rabbits. Current results provide further evidence that various growth factors are involved in sleep regulation.
neurotrophin-2; rapid eye movement sleep; growth factor; brain temperature; slow-wave sleep
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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THE HYPOTHESIS that sleep serves a synaptic function began with Moruzzi (26) and has been adopted by many others (5, 6, 17, 20, 22). Related hypotheses of brain organization as it applies to sleep suggest that sleep begins as a local event within small groups of highly interconnected neurons (1, 17, 20, 22) [neuronal groups as defined by Edelman (8)]. The notion that sleep is dependent on prior duration of wakefulness was modified in these theories to posit that sleep is dependent on prior neuronal use. It is thought that sleep, at the neuronal group level, is induced by growth factors that are produced locally in response to neuronal use. Those growth factors, in turn, alter synapses and thus input-output relationships of the neuronal group within which they are produced. Sleep function (growth factor-induced synaptic change) is thus posited to be inseparable from sleep mechanisms (growth factor-induced altered circuit dynamics of neuronal groups) (20, 22). There are of course many other ideas concerning sleep function (reviewed in Ref. 13); however, the notion that growth factors are central to both sleep mechanism and sleep function led to the current experiments.
A variety of growth factors are implicated in sleep regulation; the
list includes endocrines, such as growth hormone (GH), GH-releasing
hormone (GHRH), prolactin (PRL), and insulin, as well as autocrines or
exocrines, such as interleukin-1
(IL-1), tumor necrosis
factor-
(TNF-), acidic fibroblast growth factor (aFGF), and
neurotrophin 1 (NT-1). All of these substances, if injected, have the
capacity to enhance non-rapid eye movement sleep (NREMS) (insulin,
IL-1, TNF-, aFGF), rapid eye movement sleep (REMS) (GH, PRL), or
both (GHRH, NT-1) (27). Inhibition of GH, IL-1, TNF, or
GHRH inhibits spontaneous sleep and, in the case of GHRH, IL-1, and
TNF, sleep rebound after sleep deprivation (reviewed in Ref. 21). These
and many additional data strongly suggest that these growth factors are
involved in physiological sleep regulation (3, 21). Brain-derived
neurotrophic factor (BDNF; also called neurotrophin-2) is another
growth factor whose production by neurons is stimulated by neuronal use
(36) and has the ability to promote the growth and survival of neurons in the central nervous system. BDNF and its receptor, a
specific tyrosine kinase receptor (trkB), are widely distributed in the brain (7); both BDNF mRNA and trkB mRNA have diurnal rhythms in brain
(4). Furthermore, BDNF mRNA levels in the cortex increase after sleep
deprivation (32). We thus thought it likely that BDNF might promote
sleep; we report here that injection of BDNF induces enhanced sleep in
rats and rabbits.
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MATERIALS AND METHODS |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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Recombinant human BDNF was purchased from Sigma (St. Louis, MO). BDNF bioactivity, its ability to support survival and stimulate neurite outgrowth of cultured embryonic chick dorsal root ganglia, was determined by the manufacturer. It contained 250 µg BSA per 5 µg. Substances were dissolved in pyrogen-free isotonic NaCl (PFS; Abott, North Chicago, IL). Injection volumes were 4 µl for rats and 25 µl for rabbits.
Animals. Twenty-four male
Sprague-Dawley rats (320-380 g) and 25 male New Zealand White
rabbits (4.5-5.5 kg) were surgically implanted with
electroencephalographic (EEG) electrodes, a brain thermistor, a lateral
intracerebroventricular cannula, and electromyographic (EMG) electrodes
(only in rats); ketamine-xylazine (35 and 5 mg/kg) anesthesia was used
as previously described (16, 18). In rats, the patency and free
drainage of the guide cannula were verified by injecting
intracerebroventricularly 40 ng of angiotensin II (Sigma) in 4 µl of
PFS. If the cannula placement was correct, angiotensin II elicited a
drinking response (35). Only rats with a positive drinking response
were used. After a 1- to 2-wk recovery period, the animals were placed
in sleep-recording chambers (Hot Pack 352600, Philadelphia, PA). Rats
were habituated to the recording procedure for at least 3 days; during
this period, the rats were connected to recording cables and injected
with PFS daily at the same time that the experimental treatments were
to be done. Rabbits were habituated to the recording chamber for at
least 1 day. The animals were kept on a 12:12-h light-dark cycle
(lights on at 0800 for rats or 0600 for rabbits) at 21 ± 1°C
(for rabbits) and 22 ± 1°C (for rats) ambient temperature. Water
and food were available ad libitum throughout the experiment. A
flexible tether connected the electrode and thermistor leads to an
electronic swivel. The animals were allowed relatively unrestricted movement inside the recording cages. EEG, brain temperature
(Tbr), motor activity (only in
rabbits, detected by an ultrasonic sensor; Biomedical Instrumentation,
Univ. of Tennessee), and EMG (only in rats) were recorded. The EEG was
filtered below 0.1 and above 35 Hz. The amplified signals were
digitized at the frequency of 128 Hz for the EEG and 2 Hz for
Tbr and motor activity.
Tbr data were saved on a computer
in 10-s intervals. Tbr values,
averaged in 3-h intervals, were used for statistical analysis. Online
Fourier analyses of EEG data were performed. The vigilance states were determined offline in 10-s epochs. The vigilance states of wakefulness, NREMS, and REMS were visually identified in 10-s epochs using criteria
previously reported by individuals unaware of the treatment animals
were subjected to (16). The amount of time spent in each vigilance
state was calculated for 2-h intervals and for the entire recording
period (Table 1). The EEG
power density values were summed in the delta (0.5-4.0 Hz) band,
then average delta activity during NREMS, also called slow-wave
activity (SWA), was calculated for 2-h time blocks. Because the EEG
amplitude was subject to the influence of subtle variations of EEG
electrode placement, the average power during NREMS throughout the
entire 23-h control recording period was normalized to 100%. The
relative changes in EEG power density values from the baseline were
then calculated. In addition, the number of NREMS and REMS episodes, mean episode lengths, and mean length of sleep cycle (REMS-REMS interval) were determined using a computer program with the criterion that each episode lasted 
30 s.
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Experimental protocol. A total of 24 rats and 25 rabbits were used in these experiments. In rats, each animal received an injection of 4 µl PFS intracerebroventricularly on a separate day to obtain control values. The same animals were then injected intracerebroventricularly with one of three doses of BDNF: 10 (n = 6), 50 (n = 6), or 250 ng (n = 7). The injections took place at dark onset. In rabbits, each animal received 25 µl PFS intracerebroventricularly as control, in the same manner as rats. On the next day, the animals were injected intracerebroventricularly with one of two doses BDNF: 25 (n = 7) or 250 ng (n = 8). The injections took place between 0845 and 0920. In addition, five rabbits were injected intracerebroventricularly with 250 ng BDNF at dark onset. Furthermore, five rats and five rabbits were injected intracerebroventricularly with 12.5 µg of BSA (Sigma) as an additional control, because high doses of BSA (140 mg) injected intraperitoneally induced increases in sleep and Tbr (28).
All statistical analyses were performed with two-way ANOVA for repeated measures across the entire recording period followed by Student-Newman-Kuels test. A significance level of P < 0.05 was accepted.
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RESULTS |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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In rabbits, control injections of BSA had no statistically significant
effects on any of the parameters measured in this study. The typical
diurnal variations in sleep and
Tbr parameters persisted in BSA-
and physiological saline-injected controls. Intracerebroventricular administration of the lowest dose of BDNF tested (25 ng) also had no
effect on NREMS, REMS, SWA, or Tbr
(Table 1). In contrast, intracerebroventricular administration of BDNF
(250 ng) during the light period (LP) increased the amount of time
spent in NREMS (Table 1, Fig. 1)
[ANOVA treatment effect; F(1,7) = 29.92, P < 0.01] with an
interaction of treatment and time [ANOVA treatment effect;
F(1,7) = 2.32, P < 0.05]. Further
intracerebroventricular administration of BDNF (250 ng) at dark onset
had a greater effect on the amount of time spent in NREMS; after dark
onset injections rabbits spent ~1 h extra in NREMS over the recording
period, whereas after daytime injection there were ~40 min extra in
NREMS [ANOVA treatment effect;
F(1,4) = 21.54, P < 0.01]. REMS was also
increased after intracerebroventricular administration of BDNF (250 ng) during either LP [ANOVA treatment effect;
F(1,7) = 13.15, P < 0.01] or at dark onset
[ANOVA treatment effect; F(1,4) = 22.66, P < 0.01] (Fig. 1,
Table 1). The increases in REMS after dark onset injections resulted
from an increase of the number of REMS episodes [1.7 ± 0.1 control vs. 2.2 ± 0.1 experiment; ANOVA treatment effect; F(1,4) = 49.19, P < 0.01]. Sleep cycle length
(REMS-REMS intervals) decreased [37.0 min ± 2.4 control vs.
27.0 ± 1.3 experiment; ANOVA treatment effect;
F(1,4) = 138.89, P < 0.01] with an interaction of treatment and time [ANOVA treatment effect;
F(1,4) = 2.47, P < 0.05]. EEG SWA decreased
after 250 ng BDNF given at dark onset (Table 1) [ANOVA treatment
effect; F(1,4) = 14.68;
P < 0.05]. BDNF failed to
affect Tbr after any dose (Table
1).
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In rats, BSA and physiological saline also failed to alter the normal
diurnal variations of sleep in this species. The lowest dose of BDNF
tested in rats (10 ng) failed to affect any of the parameters measured
in this study. In contrast, administration of the moderate or highest
dose of BDNF increased the amount of time spent in NREMS [ANOVA
treatment effect; F(1,5) = 8.41, P < 0.05 for 50 ng;
F(1,6) = 40.34, P < 0.01 for 250 ng] (Fig.
2, Table 1). For example, after the 250-ng
dose rats spent ~1.3 h in NREMS over the 23-h recording period. About
one-half of this increase took place in the initial 12-h postinjection
dark period, and the other half took place during the subsequent 12-h
light period. In rats, unlike in rabbits, BDNF failed to significantly affect REMS (Fig. 2, Table 1). In rats, the BDNF-induced increases in
NREMS resulted from small increases in both the number of NREMS episodes and their duration, but neither individual effect reached significance. In rats, BDNF failed to affect sleep cycle length or the
number or duration of REMS episodes.
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Although not systematically quantified, BDNF did not induce abnormal behavior in either rats or rabbits, insofar as animals continued to cycle through sleep-wake episodes, were easily aroused if disturbed, and failed to exhibit any gross abnormal motor behavior.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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The effects of BDNF on sleep were dependent on the species and the time
of administration. BDNF increased NREMS and REMS in rabbits but, in
rats, increased only NREMS. The reasons for this species difference are
unknown. Nevertheless, other sleep-promoting substances have similar
species-specific effects on sleep. For example, prostaglandin
D2 enhances sleep in rats but not
in rabbits (12, 19). Furthermore, in rabbits, the effect of BDNF
administration at dark onset on NREMS seemed to be greater than that
observed after administration of BDNF during LP. Previously,
differences in sleep responses after administration of sleep-promoting
or sleep-inhibiting substances at different times of the day in both rats and rabbits were described. For example, administration of 10.0 ng
IL-1 at dark onset enhances NREMS in rats, whereas the same dose of
IL-1 suppresses NREMS if given during LP (29). These differences
likely resulted from the interaction of the circadian and homeostatic
processes regulating sleep (reviewed in Refs. 2, 3).
BDNF failed to affect Tbr. There
is a rather extensive literature describing the multiple links between
thermoregulation and sleep (reviewed in Ref. 23). For example, there is
a regulated decrease in Tbr during
the entry into NREMS (39), and an acute mild increase in ambient
temperature is a well-characterized somnogen (37). Nevertheless, under
a variety of circumstances, thermoregulation can be separated, in part,
from sleep regulation (23). Some substances enhance both NREMS and
Tbr (e.g., TNF and IL-1), but the pyrogenic actions of IL-1 can be pharmacologically blocked without affecting sleep responses (24); the effect of IL-1 on sleep
and temperature is also differentially affected depending on where in
the brain it is injected (38). Furthermore, the somnogenic actions of
IL-1, but not its pyrogenic actions, are blocked by central
administration of nitric oxide synthase inhibitors (16). Other
substances increase Tbr and
inhibit sleep (e.g., corticotropin-releasing hormone). Collectively,
such considerations clearly indicate separate yet linked mechanisms for
sleep and body temperature.
EEG SWA decreased during NREMS after BDNF administration at dark onset
in rabbits. Although this effect was significant, its biological
importance is questioned because control injections of BSA induced
similar decreases, though these were not significant. In many
circumstances, EEG SWA is thought to be indicative of NREMS intensity.
For example, after sleep deprivation, supranormal EEG slow waves
characterize NREMS (31) and are associated with higher arousal
thresholds (30). Nevertheless, there is an extensive literature
describing the separation of EEG SWA from state regulation. For
example, intraperitoneal injections of IL-1 or TNF- can induce
increases in NREMS and decreases in EEG SWA in rats (11) and mice (9),
whereas intracerebroventricular injections of IL-1 or TNF usually
enhance both (14, 29). Systemic injection of atropine induces EEG
synchronization regardless of state (34). Removal of basal forebrain
cholinergic neurons reduces EEG SWA but has little effect on the amount
of NREMS (15). Regardless of such considerations, it does not appear
that BDNF has a major role in regulation of EEG SWA.
Results presented here clearly indicate that BDNF has the capacity to enhance NREMS in both rats and rabbits. These results, coupled with the previous findings that BDNF mRNA increases in the cortex during sleep deprivation (32), suggest that BDNF may have a role in sleep regulation. Such a role for BDNF is also consistent with theoretical considerations suggesting that growth factors are part of sleep mechanisms and that their actions on synapses are part of sleep function (20, 22). Thus that BDNF is produced by GABAergic neurons in an activity-dependent manner (25) and that BDNF promotes synaptic plasticity (10) and affects cortical reorganization after nerve injury or after cutting or stimulation of facial whiskers (33) are consistent with the notion that sleep serves a synaptic function. Regardless of such consideration, current results provide further evidence that sleep is, in part, regulated by growth factors.
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ACKNOWLEDGEMENTS |
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This work was supported by National Institutes of Health Grants NS-25378, NS-27250, NS-31453, and HD-36520.
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FOOTNOTES |
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The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests and other correspondence: J. M. Krueger, Dept. of VCAPP, Washington State Univ., Pullman, WA 99164-6520 (E-mail: krueger{at}vetmed.wsu.edu).
Received 16 November 1998; accepted in final form 23 January 1999.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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T. Kubota, J. Fang, T. Kushikata, and J. M. Krueger Interleukin-13 and transforming growth factor-beta 1 inhibit spontaneous sleep in rabbits Am J Physiol Regulatory Integrative Comp Physiol, September 1, 2000; 279(3): R786 - R792. [Abstract] [Full Text] [PDF]
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T. Kubota, T. Kushikata, J. Fang, and J. M. Krueger Nuclear factor-kappa B inhibitor peptide inhibits spontaneous and interleukin-1beta -induced sleep Am J Physiol Regulatory Integrative Comp Physiol, August 1, 2000; 279(2): R404 - R413. [Abstract] [Full Text] [PDF]
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) or vehicle treatment (
) on time
spent in non-rapid eye movement sleep (NREMS) and rapid eye movement
sleep (REMS) in rabbits during 23-h postinjection period. Data are
means ± SE. Horizontal dark bars denote dark phase of day. BDNF
injected during light period (A) or
at dark onset (B) increased amount
of time spent in NREMS and REMS; effects were larger after dark onset
injections.
