Cholinergic Rapid Eye Movement Research Articles

Urotensin II evokes neurotransmitter release from rat cerebrocortical slices

Urotensin II (UII) has been reported to modulate rapid eye movement (REM) sleep via activation of brainstem cholinergic neurons and REM sleep is regulated by locus coerleus (LC)-cerebrocortical noradrenergic neurons. We hypothesized that UII may activate LC-cerebrocortical noradrenergic neurons. To test this hypothesis, we have examined the effects of UII on norepinephrine release from rat cerebrocortical slices. In addition, the effect of the putative UT receptor antagonist [Pen(5), DTrp(7), Dab(8)]UII(4-11) (UFP-803) was assessed. We have compared this with other wakefulness-promoting neurotransmitters such as dopamine, glutamate, serotonin and histamine. We also studied the effects of UII and UFP-803 on intracellular Ca(2+) ([Ca(2+)]i) in HEK293 cells stably expressing rat UT receptor (HEK293-rUT cells). UII produced a time- (peaking at approximately 10 min following stimulation with 10nM) and concentration-dependent increase in norepinephrine release with pEC(50) and E(max) (% of basal) values of 8.78+/-0.17 (1.65 nM) and 138+/-2%, respectively. UII also evoked dopamine, serotonin and histamine release with similar pEC(50) values. UII increased glutamate release but only at high concentrations (<100 nM) and this failed to saturate. UII markedly increased [Ca(2+)](i) in HEK293-rUT cells in a concentration-dependent manner with pEC(50) of 8.26+/-0.24. The UT antagonist UFP-803 reversed both UII-increased norepinephrine release from the cerebrocortical slices (pK(B)=8.98) and [Ca(2+)](i) (pK(B)=8.87) in HEK293-rUT cells. Collectively these data suggest that UII evokes the release of norepinephrine via UT receptor activation and produces similar effects on other wakefulness-promoting neurotransmitters: these neurochemical actions of UII may be important for the control of the sleep-wake cycle.

Sleep and the cholinergic rapid eye movement sleep induction test in patients with primary alcohol dependence

Background: The present study investigated polysomnographically assessed sleep parameters in alcohol-dependent patients after withdrawal and in healthy control subjects during baseline and after a cholinergic stimulation paradigm. The aim of the study was to test whether sleep parameters, especially rapid eye movement (REM) sleep variables, may serve as predictors for relapse in alcohol-dependent patients. Methods: Forty patients diagnosed with alcohol dependence were admitted to a specialized ward for alcohol withdrawal and were investigated by polysomnography at three time points: 2–3 weeks after withdrawal (T0) and at follow-up investigations 6 (T1) and 12 (T2) months after discharge from the hospital. A subgroup of patients ( n = 17) was studied at T0 after challenge with galanthamine, a reversible cholinesterase inhibitor (cholinergic REM induction test, CRIT). Patients were compared with two control groups: a) 30 healthy control subjects (matched for age- and gender-distribution) for comparison at baseline conditions; and b) 17 age- and gender-matched control subjects for comparison with the CRIT. Results: At baseline the patients showed significant disturbances of sleep continuity and sleep architecture (decreased slow-wave sleep, SWS) and exhibited an increase of “REM sleep pressure” (a combined index of REM latency, REM density, and REM sleep percent). Galanthamine provoked significant alterations of sleep continuity, sleep architecture (reduced SWS), and increased most of the components of REM pressure, taking patients and control subjects together. Apart from SWS %SPT (sleep period time) no significant drug-group interactions occurred. Patients who remained abstinent ( n = 11) for at least 6 months at follow-up exhibited significantly less abnormalities of REM sleep at T0 compared to the group of patients that relapsed at 6 months follow-up. Conclusions: It is concluded that increased REM sleep pressure after alcohol withdrawal is a robust predictor of vulnerability to relapse. Thus, a subgroup of alcoholic patients appears to exhibit distinct neurobiological abnormalities assessable by polysomnography that are related to an increased vulnerability for alcoholism and early relapse.

CAMP and protein kinase A modulate cholinergic rapid eye movement sleep generation.

Cholinergic neurotransmission in the medial pontine reticular formation (mPRF) modulates rapid eye movement (REM) sleep generation. Microinjection of cholinergic agonists and acetylcholinesterase inhibitors into the mPRF induces a REM sleep-like state, and microdialysis data reveal increased mPRF levels of acetylcholine during REM sleep. Muscarinic cholinergic receptors (mAChRs) participate in REM sleep generation, and data suggest that mAChRs of a non-M1 subtype modulate REM sleep generation. The signal transduction pathway activated by m2 and m4 mAChRs involves a pertussis toxin-sensitive G protein, adenylate cyclase (AC), adenosine 3',5'-cyclic monophosphate (cAMP), and protein kinase A (PKA). Therefore, the present study tested the hypothesis that cAMP and PKA within the mPRF modulate the carbachol-induced REM sleep-like state. To test this hypothesis, the mPRF was microinjected with compounds known to facilitate the effects of cAMP (dibutyryl cAMP and 8-bromo-cAMP), stimulate PKA (Sp-cAMP[S]), and inhibit PKA (Rp-cAMP[S]). The results showed that compounds that fostered the intracellular effects of cAMP significantly decreased cholinergic REM sleep, while having no effect on spontaneously occurring REM sleep. These data are consistent with the recent finding that within the mPRF, AC and a pertussis toxin-sensitive G protein modulate cholinergic REM sleep generation. These new data suggest a modulatory role for pontine cAMP and PKA in cholinergic REM sleep regulation.

Cholinergic REM induction test with arecoline in depressed children

Children with major depressive disorder often fail to exhibit electroencephalographic (EEG) sleep abnormalities similar to those reported in depressed adults. It was hypothesized that a cholinergic rapid eye movement (REM) induction test would contribute to the identification of EEG sleep abnormalities in depressed children. To test this hypothesis, prepubertal children meeting research diagnostic criteria for major depressive disorder ( n = 33) and carefully screened healthy control children ( n = 15) were enrolled in a4-day psychobiologic protocol that included 1 night with infusion of arecoline (0.5 mg) during the first non-REM sleep period. Although there had been no significant group differences in baseline sleep measures, results on the arecoline night revealed significantly shorter REM latency in the group of depressed children compared with the control children (mean ± SD = 105 ± 51 minutes vs. 140 46 ± minutes). The design of the protocol (with an interval break immediately preceding the arecoline night) prevented a direct estimation of arecoline effects within subjects; however, these data provide promising preliminary results regarding cholinergic REM induction tests in childhood depression.

Sleep in depression: the influence of age, gender and diagnostic subtype on baseline sleep and the cholinergic REM induction test with RS 86.

One hundred and eight healthy controls and 178 patients with a major depressive disorder according to DSM-III were investigated in the sleep laboratory after a 7-day drug wash-out period. Subsamples of 36 healthy controls and 56 patients additionally took part in the cholinergic rapid eye movement (REM) sleep induction test with RS 86. Data analysis revealed that age exerted powerful influences on sleep in control subjects and depressed patients. Sleep efficiency and amount of slow wave sleep (SWS) decreased with age, whereas the number of awakenings, early morning awakening, and amounts of wake time and stage 1 increased with age. REM latency was negatively correlated with age only in the group of patients with a major depression. Statistical analysis revealed group differences for almost all parameters of sleep continuity with disturbed indices in the depressed group. Differences in SWS were not detected. REM latency and REM density were altered in depression compared to healthy subjects. Sex differences existed for the amounts of stage 1 and SWS. The cholinergic REM induction test resulted in a significantly more pronounced induction of REM sleep in depressed patients compared with healthy controls, provoking sleep onset REM periods as well in those depressed patients showing baseline REM latencies in the normal range. Depressed patients with or without melancholia (according to DSM-III) did not differ from each other, either concerning baseline sleep or with respect to the results of the cholinergic REM induction test. The results stress the importance of age when comparing sleep patterns of healthy controls with those of depressed patients. Furthermore they underline the usefulness of the cholinergic REM induction test for differentiating depressed patients from healthy controls and support the reciprocal interaction model of nonREM-REM regulation and the cholinergic-aminergic imbalance hypothesis of affective disorders.

The Cholinergic Rapid Eye Movement Induction Test With Arecoline in Depression

The cholinergic rapid eye movement (REM) induction test using arecoline hydrobromide, a cholinergic muscarinic receptor agonist, was studied in patients with affective disorder and in normal controls to determine whether or not depression is associated with enhanced induction of REM sleep by muscarinic agonists. Arecoline induced REM sleep in a dose-dependent fashion in both patients and controls compared with placebo infusions. Compared with normal controls, patients entered REM sleep significantly more rapidly following intravenous administration of 1.0 mg of arecoline hydrobromide than they did following administration of 0.5 mg of arecoline hydrobromide or placebo. These results, as well as those of previous studies, support the hypothesis that patients with affective disorder show a functional supersensitive induction of REM sleep in response to muscarinic receptor agonists and may be consistent with the hypothesis that functional muscarinic receptor "up regulation" is associated with depression.

EEG sleep and the cholinergic REM induction test in anorexic and bulimic patients

The electroencephalographic (EEG) sleep of 20 anorexic patients, 10 bulimic patients, and 10 age-matched healthy controls was studied. In addition, six anorexic patients and six bulimic patients had a cholinergic rapid eye movement (REM) sleep induction test (RIT) performed with the cholinergic agent RS 86. The three samples showed no major differences in sleep patterns. The same held true when attention was focused on patients who additionally met DSM-III criteria for major depression. The RIT results were similar in the patients with eating disorders and in controls, but differed from those reported in depressives. Therefore, the present study found no hints of depression-like sleep patterns in patients with eating disorders.