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The Journal of Neuroscience, July 1, 2002, 22(13):5282-5286
BRIEF COMMUNICATION
Release of Hypocretin (Orexin) during Waking and Sleep States
Lyudmila I.
Kiyashchenko1, 2, 3, *,
Boris Y.
Mileykovskiy1, 2, 3, *,
Nigel
Maidment1,
Hoa A.
Lam1,
Ming-Fung
Wu1, 2,
Joshi
John1, 2,
John
Peever1, 2, and
Jerome M.
Siegel1, 2
1 Department of Psychiatry and Biobehavioral Sciences
and Brain Research Institute, University of California Los Angeles
School of Medicine, and 2 Veterans Administration of
Greater Los Angeles Healthcare System-Sepulveda, North Hills,
California 91343, and 3 Institute of Evolutionary
Physiology and Biochemistry, Russian Academy of Science, St.
Petersburg, 194223, Russia
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ABSTRACT |
Hypocretin (Hcrt or orexin) somas are located in the hypothalamus
and project widely to forebrain and brainstem regions, densely innervating monoaminergic and cholinergic cells. Loss of Hcrt function
results in the sleep disorder narcolepsy. However, the normal pattern
of Hcrt release across the sleep-wake cycle is unknown. We monitored
Hcrt-1 release in the basal forebrain, perifornical hypothalamus, and
locus ceruleus (LC) across the sleep-wake cycle using microdialysis in
freely moving cats and a sensitive solid phase radioimmunoassay. We
found that the peptide concentration in dialysates from the
hypothalamus was significantly higher during active waking (AW) than
during slow-wave sleep (SWS). Moreover, Hcrt-1 release was
significantly higher during rapid eye movement (REM) sleep than during
SWS in the hypothalamus and basal forebrain. We did not detect a
significant difference in release across sleep-waking states in the
LC, perhaps because recovered levels of the peptide were lower at this
site. Because there was a trend toward higher levels of Hcrt-1 release
during AW compared with quiet waking (QW) in our 10 min dialysis
samples, we compared Hcrt-1 levels in CSF in 2 hr AW and QW
periods. Hcrt-1 release into CSF was 67% higher during AW than during
QW. Elevated levels of Hcrt during REM sleep and AW are consistent with
a role for Hcrt in the central programming of motor activity.
Key words:
hypocretin; orexin; microdialysis; sleep-waking cycle; motor activity; cataplexy
| |
INTRODUCTION |
Hypocretin (Hcrt) peptides are
synthesized by a small number of neurons in the perifornical and
lateral hypothalamus (De Lecea et al., 1998 ; Sakurai et al., 1998).
These neurons have dense projections to the basal forebrain (BF),
limbic structures, and brainstem regions, in particular those related
to waking and rapid eye movement (REM) sleep regulation (Peyron et al.,
1998; Nambu et al., 1999). Symptoms resembling those seen in human
narcolepsy are seen in prepro-hypocretin null mutant mice, in dogs with
a mutation in one of the two Hcrt receptors, and in rats with targeted destruction of Hcrt receptor-expressing neurons (Chemelli et al., 1999;
Lin et al., 1999; Gerashchenko et al., 2001). Human narcolepsy is
linked to an 85-95% loss of Hcrt neurons (Thannickal et al., 2000)
and undetectable Hcrt levels (Peyron et al., 2000). Narcolepsy has long
been thought to be a disease affecting REM sleep regulation because of
the similarity of cataplexy and sleep paralysis to the muscle-tone
suppression of REM sleep, the narcoleptic's short REM sleep latency,
hypnagogic hallucinations that resemble dreaming (Rechtschaffen and
Dement, 1967), and similarities of locus ceruleus (LC) and medial
medullary unit discharge during cataplexy and REM sleep (Siegel et al.,
1991; Wu et al., 1999).
Two hypotheses have been proposed for the pattern of release of Hcrt
across the sleep-wake cycle. One hypothesis is influenced by the
finding that noradrenergic, serotonergic, and histaminergic neurons
that are strongly innervated by Hcrt neurons have a "REM sleep-off" activity profile (Vanni-Mercier et al., 1984; Jacobs, 1987; Wu et al., 1999) and the finding that Hcrt is excitatory to
aminergic cell groups (Hagan et al., 1999; Ivanov and Aston-Jones, 2000; Brown et al., 2001; Eriksson et al., 2001). This hypothesis postulates maximal Hcrt release during waking, reduced release during
slow-wave sleep (SWS), and minimal release during REM sleep (Hungs and
Mignot, 2001). The other hypothesis, influenced by the finding that
cholinergic cells are also strongly innervated and excited by Hcrt
neurons (Burlet et al., 2002) and by the increased activity in
cholinergic neuronal populations during waking and REM sleep (Steriade
et al., 1990; Sakai and Onoe, 1997) suggests that Hcrt release is
maximal during REM sleep and during waking and is minimal during SWS
(Kilduff and Peyron, 2000).
It has been difficult to determine the pattern of release of Hcrt
because the limited sensitivity of the assays used has required very
long duration microdialysis samples. This has prevented investigators from separating the contributions of REM sleep, SWS, and waking behavior to Hcrt levels. In the current study, we have addressed this
problem by adapting a sensitive solid-phase peptide assay for Hcrt
measurement (Maidment and Evans, 1991) and by using cats, which have
longer-duration sleep periods than rodents, as subjects.
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MATERIALS AND METHODS |
Surgery. All procedures were approved by the Animal
Studies Committee of the Sepulveda Veterans Administration Medical
Center/University of California Los Angeles, in accordance with United
States Public Health Service guidelines. Aseptic stereotaxic
neurosurgery was performed on four young cats (two males and two
females) weighing from 2.5 to 3.5 kg. Animals were intubated, and deep
anesthesia was maintained with 2% isoflurane. Surface and depth
electrodes (n = 8) were implanted to record sleep- and
waking-state physiology, using stereotaxic coordinates from the atlas
of Snider and Neimer (1961). Stainless-steel screws were threaded into
the bone over the left frontal cortex [anterior (A), 4; lateral
(L), 8] to record cortical EEG and also over the orbit in the
frontal sinus to register electrooculograms. Stainless-steel
wires were inserted into the dorsal neck musculature to record splenius
electromyograms. Depth electrodes with 0.5 mm deinsulated tips were
inserted bilaterally to record activity in the lateral geniculate
nucleus [A, 6; L, 10; height (H), +2.3].
For microdialysis, guide cannulas (NG-35; Eicom, Kyoto, Japan)
were bilaterally implanted 5 mm above target sites in the BF, perifornical hypothalamus (HYP), and LC. Coordinates of the sampling sites were as follows: for the BF, A, 14; L, 5; and H,  4.5; for the
HYP, A, 11; L, 2; and H, -3.5; and for the LC, posterior (P), 2.5; L, 2.5; and H, -2.5. A minimum of 2 weeks postoperative recovery was allowed.
Microdialysis sampling. Animals were adapted to the
recording chamber for 24 hr before baseline polygraphic recordings of sleep-wake cycles. Simultaneous sleep recording and collection of
Hcrt-1 microdialysis samples were started at least 12 hr after the
insertion of each microdialysis probe (NDP-35-015; Eicom) (1000 kDa;
membrane length, 1.5 mm; outer diameter, 0.6 mm; recovery rate,
 20%). Dialysates were collected from each probe for 2 d. Dialysis probes were perfused with artificial CSF (Harvard Apparatus, Holliston, MA) in a push-pull manner using a microsyringe pump (ESP-64; Eicom) with samples collected into a 20 µl manual sample injector (model 9725I; Eicom) at 2 µl/min. A 2 hr stabilization period was used before sampling. Dialysates were collected in 10 min
(20 µl) samples during temporally adjacent periods of active waking
(AW), quiet waking (QW), SWS, and REM sleep to control for any
circadian effects or slow changes in recovery from the probe. States
with a duration that was <75% of the 10 min sample period were
excluded from analysis. Hcrt-1 levels in samples that were >75%
complete were extrapolated to a 10 min duration. Data from one BF probe
was excluded because of a >40-fold difference in detected Hcrt levels
between the 2 d. Hcrt-1 levels in all other probes deviated by
less than a factor of 3 between days 1 and 2.
CSF collection and motor activity. CSF (0.5 ml) was drawn
from the cisterna magna in six cats with a 22 gauge spinal needle after
fluothane anesthesia. CSF samples underwent a reversed-phase extraction
procedure before radioimmunoassay (RIA) analysis. All CSF collections
were done at 11:00 A.M. within 3-5 min after 2 hr of alert QW or 2 hr
of AW during which the experimenter encouraged the cat to play and
locomote. Motor activity was measured with Mini-Mitter
actigraphs (Actiwatch; MiniMitter Inc, Sundriver, OR) placed in
a neck collar. The two sets of observations in each subject were
conducted on adjacent days in counter-balanced order.
Radioimmunoassay. Microdialysate samples were analyzed
directly by RIA. Samples were acidified with 1% trifluoroacetic
acid (TFA) and loaded onto a C18 Sep-Column (Waters Corp.,
Milford, MA). The peptide was eluted with 1% TFA/40%
acetonitrile. The eluant was then dried down and resuspended in RIA
buffer before assay. The Hcrt-1, iodinated Hcrt-1, and Hcrt-1 antiserum
were obtained from Phoenix Pharmaceuticals, Inc., #RK-003-30 (Belmont, CA). Hcrt-1 and Hcrt-2 are cleaved from the same precursor peptide and
are generally thought to be found in the same neurons (De Lecea et al.,
1998; Sakurai et al., 1998). Hcrt-2 is much less stable than Hcrt-1 and
was not measured in the current study. The solid-phase assay (Maidment
and Evans, 1991) provided an IC50 of 3.8 ± 0.7 fmol and a limit of detection of ~0.2 fmol.
Histology and data analysis. At the end of the study,
animals were anesthetized with Nembutal (35 mg/kg, i.v.) and perfused intracardially with saline followed with buffered 10% formalin. Brain
tissues were cut into 50-µm-thick sections. Two-way ANOVA, Tukey's
test, and paired t test were used for sample analysis. We
present mean values ± SEM.
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RESULTS |
Microdialysis samples were collected from sites in the HYP (Fig.
1A), an area containing
a high concentration of Hcrt somas; the BF (Fig. 1B),
an area with wake-REM sleep-active cholinergic neurons, sleep-active
neurons, and dense Hcrt innervation (Szymusiak, 1995; Peyron et al.,
1998; Nambu et al., 1999); and the LC (Fig. 1C), a brainstem
noradrenergic nucleus with strong Hcrt innervation (Peyron et al.,
1998). Hcrt-1 release differed significantly in the HYP as a function
of sleep-waking state (p < 0.003;
F = 4.7; df = 3, 254) (Fig. 1D)
and in the BF (p < 0.03; F = 3.2; df = 3, 133) (Fig. 1E). Overall levels of
Hcrt-1 recovered in the LC were lower than those in the HYP and BF, and
the changes across sleep-waking states in the LC were not significant
(p < 0.7; F = 0.46; df = 3, 161) (Fig. 1F). The lower levels of Hcrt-1
recovered from the LC may be attributable to its smaller size and
proximity to the fourth ventricle, making for a poorer seal around the
probe. Levels during REM sleep were significantly elevated relative to SWS levels in the HYP (p < 0.002; Tukey's
test) and BF (p < 0.02; Tukey's test)
regions. Hcrt-1 levels during AW were significantly higher than those
during SWS in the HYP (p < 0.05; Tukey's
test). Hcrt-1 levels during REM sleep did not significantly differ from those during AW in any of the sampled regions. Figure
2 shows an individual hypnogram from the
HYP demonstrating the elevated levels of Hcrt-1 in dialysates taken
after REM sleep or AW periods relative to the levels taken after QW or
SWS periods.
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Figure 1.
Sleep-cycle release of Hcrt. A-C,
Location of the tips of dialysis probes in the HYP, BF, and LC.
CI, Internal capsule; CO, optic chasm;
f, fornix; LH, lateral hypothalamus.
D-F, Hcrt levels across the sleep-waking states in the
HYP, BF, and LC. Sleep-state values differ as a function of state (HYP,
p < 0.003, F = 4.7, df = 3254; BF, p < 0.03, F = 3.2, df = 3133). Tukey's test; *p < 0.05;
**p < 0.02; ***p < 0.002. Hcrt release is maximal during AW and REM sleep and minimal during SWS
and QW in the HYP and BF.
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Figure 2.
Hypnogram (A) and
Hcrt levels (B) in the HYP across the sleep
cycle. Circles indicate points at which dialysate was
taken. Hcrt levels are maximal after long AW and REM sleep periods and
minimal after SWS periods.
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Because we saw a trend toward increased Hcrt-1 levels in our 10 min
microdialysis samples during AW relative to QW (Fig. 1), we
investigated the effect of a more prolonged AW period on overall brain
release of Hcrt-1 into CSF. In an independent group of six cats, we
sampled CSF for Hcrt-1 after 2 hr periods of QW and 2 hr periods of AW.
The Hcrt-1 concentration in CSF was increased during AW relative to QW
(p < 0.02; t = 3.4; df = 5; paired t test) by a mean of 67% (Fig.
3).
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Figure 3.
Concentrations of Hcrt-1 in the CSF during AW and
QW. Left, Actigraph readings reflect greater levels of
head movement during active waking. Right, Hcrt levels
are significantly higher in CSF taken after a 2 hr AW period than after
a 2 hr QW period. **p < 0.02;
t = 3.4; df = 5.
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| |
DISCUSSION |
We find maximal Hcrt-1 release in the HYP and BF during both REM
sleep and AW and minimal release during SWS. Our findings support the
model of Hcrt release put forth by Kilduff and Peyron (2000). It has
been reported recently that approximately one-half of the neurons
located in the perifornical HYP are active during both wakefulness and
REM sleep, whereas another cell population in this region has a REM
sleep-off discharge profile (Alam et al., 2002). The current results
suggest that the REM-waking active population includes Hcrt-containing
cells. The widely ramifying projection pattern of individual Hcrt
neurons (Peyron et al., 1998; Abrahamson and Moore, 1999; Nambu et al.,
1999) suggests that Hcrt release may be similar in all brain regions,
but we cannot exclude the possibility that presynaptic regulation or other mechanisms could produce differing local release.
Torterolo et al. (2001) reported that significant
c-fos expression in Hcrt-containing cells is detected
during both AW and the carbachol induced REM sleep-like state. In
contrast, Estabrooke et al. (2001) reported a negative correlation
between c-fos expression in Hcrt cells and amounts of natural REM and
SWS. However, the c-fos method has insufficient temporal
resolution for studies of short-duration processes such as natural REM
sleep (Cirelli and Tononi, 2000). Higher levels of Hcrt-1 have been
seen during the waking portion of the circadian cycle compared with
radioimmunoassay of long samples that included REM and SWS (Taheri et
al., 2000; Fujiki et al., 2001; Yoshida et al., 2001). Our current
results demonstrate that, although overall levels of Hcrt are lower at times of the day when sleeping and inactivity predominate, levels within sleep are not homogeneous, with REM sleep being correlated with
high levels of release and SWS with low levels of release in the BF and HYP.
We also found significantly higher levels of Hcrt-1 release during AW
compared with QW in our CSF samples (Fig. 3). Thus the level of Hcrt-1
is not simply dependent on the electroencephalographically defined
waking state or circadian time, but may reflect the intensity of motor
system activation. Central motor systems reach discharge levels equal
to or greater than those of active waking during REM sleep and have
minimal discharge during SWS (Evarts, 1964; Siegel and Tomaszewski,
1983; Siegel et al., 1983; Siegel, 2000)
The well known link between motor activity and alertness (Bachmann and
Grill, 1987; Vuori et al., 1988; Offenbacher and Stucki, 2000; Kruk et
al., 2001) may be a factor in the narcolepsy syndrome. Motor activity,
mediated by descending systems, is normally coordinated with excitation
of ascending activating systems in the brain. Our results suggest that
Hcrt neurons play a critical role in this coordination through the
activation of cholinergic and aminergic systems during waking. The
absence of Hcrt peptides could cause the impaired maintenance of waking
that is characteristic of narcolepsy.
The finding of high levels of Hcrt-1 release during REM sleep in the
HYP and BF will have to be integrated into models of REM sleep
regulation. If, as the anatomy suggests might be the case, this pattern
of release holds for noradrenergic, serotonergic, and histaminergic
neurons innervated by Hcrt neurons (Peyron et al., 1998; Nambu et al.,
1999), this release pattern then would appear inconsistent with
the silence of these neurons during REM sleep (Vanni-Mercier et al.,
1984; Jacobs, 1987; Wu et al., 1999). Hcrt is excitatory to these cell
groups (Hagan et al., 1999; Ivanov and Aston-Jones, 2000; Brown et al.,
2001; Eriksson et al., 2001). However, Hcrt excitation of aminergic
neurons during REM sleep could be blocked by simultaneous GABAergic
inhibition or glutamatergic disfacilitation from other sources.
Alternatively, Hcrt peptides, which can produce increases in both GABA
and glutamate release (van den Pol et al., 1998), could produce a
relatively selective potentiation of GABA release during REM sleep, a
time when increased levels of GABA are being released onto these cell
groups (Nitz and Siegel, 1996, 1997a,b).
Narcolepsy is characterized by sudden losses of muscle tone during
waking (cataplexy) and at sleep onset and offset (sleep paralysis).
These symptoms suggest that Hcrt peptides may have a role in the
maintenance of muscle tone. Intracerebroventricular administration of
Hcrt (Hagan et al., 1999) facilitates motor activity in freely moving
rats, and microinjections of this peptide in the vicinity of the LC
during waking and in decerebrate rats increases LC discharge and muscle
tone (Bourgin et al., 2000; Kiyashchenko et al., 2001). The elevated
Hcrt-1 release during AW suggests a role for this peptide in the
further facilitation of motor output.
| |
FOOTNOTES |
Received Feb. 27, 2002; revised April 4, 2002; accepted April 9, 2002.
*
L.I.K. and B.Y.M., contributed equally to this study.
This work was supported by National Institutes of Health Grants MH64109
and NS14610 and by the Medical Research Service of the
Department of Veterans Affairs.
Correspondence should be addressed to Jerome Siegel, Department of
Psychiatry, University of California Los Angeles, Neurobiology Res.
151A3, Veterans Adminstration of Greater Los Angeles Healthcare System, 16111 Plummer Street, North Hills, CA 91343. E-mail:
JSiegel{at}UCLA.edu.
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ABSTRACT
INTRODUCTION
