Sleep-waking patterns and brain biogenic amine levels in cats after administration of 6-hydroxydopamine into the dorsolateral pontine tegmentum

Pharmacology Biochemistry and Behavior, Vol. 1, pp. 557-567. ANKHO International Inc., 1973. Printed in the U.S.A.

Sleep-waking Patterns and Brain Biogenic Amine Levels in Cats after Administration of 6-Hydroxydopamine into the Dorsolateral Pontine Tegmentum A. J. ZOLOVICK 2 , W. C. STERN, J. E. JALOWlEC, J. P A N K S E P P 3 A N D P. J. M O R G A N E

Laboratory o f Neurophysiology, The Worcester Foundation for Experimental Biology, Shrewsbury, Massachusetts 01545

( R e c e i v e d 25 July 1 9 7 3 ) ZOLOVICK, A. J., W. C. STERN, J. E. JALOWIEC, J. PANKSEPP AND P. J. MORGANE. Sleep-wakingpatterns and brain biogenic amine levels in cats after administration of 6-hydroxydopamine into the dorsolateral pontine tegmentum. PHARMAC. BIOCHEM. BEHAV. 1(5) 5 5 7 - 5 6 7 , 1973.-Results from lesion and pharmacological experiments have implicated brainstem monoaminergic systems in the regulation of sleep-waking behavior. The serotonin-rich neurons of the raph~ complex function mainly in the genesis of slow-wave sleep (SWS) while the catecholamine-rich neurons of the dorsolateral pontine tegmentum (locus coeruleus) appear to function in the maintenance of cortical desynchronization of wakefulness and in the expression of various tonic and phasic components of rapid eye movement sleep (REM). 6-Hydroxydopamine, an analogue of dopamine, which rather selectively destroys catecholaminergic neurons, was injected into the catecholamine-rich dorsolateral pontine tegmentum of cats in order to evaluate the role of catecholamines in sleep-waking behavior. Five weeks after injection, the animals were sacrificed and regional brain levels of norepinephrine and serotonin were determined in order to assess the effects of this treatment on monoamine metabolism. The acute affect of the treatment was to increase total waking time at the expense of both SWS and REM sleep indicating an initial release of synapticaUy active norepinephrine. The chronic effect of the treatment was to increase the occurrence of SWS and to decrease REM sleep, an effect consistent with disruption of an ascending cortical activating mechanism of REM sleep or disinhibition of a SWS mechanism. This was accompanied by a selective and highly reliable reduction in cortical and hippocampal levels of norepinephrine. However, coincident decreases in forebrain levels of serotonin and norepinephrine preclude a definitive conclusion regarding the relative contribution of catecholamine and indoleamine mechanisms in the maintenance of sleep-waking patterns after intracerebral 6-hydroxydopamine. 6-Hydroxydopamine Biogenic amines Norepinephrine Serotonin

Sleep-waking behavior

Locus coeruleus

REM

Lesions c o n f i n e d t o t h e s e r o t o n i n - c o n t a i n i n g r a p h 6 nuclei, or t r e a t m e n t w i t h p a r a c h l o r o p h e n y l a l a n i n e (PCPA), a drug w h i c h i n h i b i t s t h e s y n t h e s i s of s e r o t o n i n and decreases its levels in t h e b r a i n , have b e e n s h o w n to r e d u c e SWS, which can be restored by administration of 5 - h y d r o x y t r y p t o p h a n , t h e p r e c u r s o r of s e r o t o n i n . Also, t h r e e - w a y c o r r e l a t i o n s b e t w e e n t h e r e d u c t i o n o f SWS, t h e e x t e n t of d a m a g e to t h e s e r o t o n i n - c o n t a i n i n g cells o f t h e r a p h 6 a n d t h e s u b s e q u e n t r e d u c t i o n o f s e r o t o n i n in t h e basal f o r e b r a i n add a d d i t i o n a l s u p p o r t for a role of serot o n i n in t h e genesis o f SWS. Results f r o m lesion a n d p h a r m a c o l o g i c a l studies i n d i c a t e t h a t c a t e c h o l a m i n e r g i c

B A S E D o n extensive p h a r m a c o l o g i c a l and lesion studies in cats J o u v e t [ 1 4 - 1 9 ] has p o s t u l a t e d t h a t states o f vigilance are regulated largely b y activity in m o n o a m i n e r g i c systems l o c a t e d in t h e b r a i n s t e m . A c c o r d i n g to J o u v e t t h e serot o n e r g i c system, o r i g i n a t i n g m a i n l y in t h e mid-line raph6 c o m p l e x , appears t o regulate t h e q u a l i t y and q u a n t i t y of slow-wave sleep (SWS) a n d t h e triggering o f rapid-eyem o v e m e n t sleep ( R E M ) , while w a k e f u l n e s s , b e h a v i o r a l arousal and phasic a n d t o n i c events o f REM sleep a p p e a r to b e u n d e r t h e c o n t r o l of c a t e c h o l a m i n e r g i c systems located in t h e lateral b r a i n s t e m and in diffusely organized cholinergic systems.

~Supported by Grants MH 10625 and MH 02211, NIMH; we gratefully acknowledge the assistance of R. Miller for analyses of biogenic amines and C. Westfall, Jr. and K. McKnight for technical assistance. 2 Present Address: Department of Psychology, McGill University, Montreal, Canada. 3 Present Address: Department of Psychology, Bowling Green State University, Bowling Green, Ohio. 557

558

ZOLOVICK, STERN, JALOWIEC, PANKSEPP AND MORGANE

mechanisms are primarily involved in the regulation of wakefulness and REM sleep [18]. For example, total bilateral destruction of the dorsolateral pontine tegmentum has been shown to produce a selective and total suppression of REM sleep, while less extensive damage to the nucleus locus coeruleus (LOC) only reduced the amount of REM sleep or suppressed the various phasic or tonic components of this state [18]. Thus, the component nuclei of the dorsolateral pontine tegmentum, LOC, subcoeruleus and parabrachial nuclei, appear to be critical elements in governing the occurrence of the various components of REM sleep. Regarding the role of the catecholamine-containing neurons of the LOC in REM sleep; destruction of the caudal third of the LOC eliminates the tonic muscular atonia associated with this state while destruction of the middle third of the LOC results in a selective suppression of some phasic components of REM sleep, i.e., the pontogeniculo-occipital (PGO) activity. The anterior third of the LOC appears more to function in cortical desynchronization of waking rather than in the regulation of REM sleep per se [181. Pharmacological data regarding the involvement of catecholamine mechanisms in the regulation of wakefulness and REM sleep appear less convincing. Treatment with disulfiram, an inhibitor of norepinephrine (NE) synthesis, leads to a decrease in REM sleep and waking [10], while alpha-methyl-dopa, which leads to synthesis of a false transmitter in NE neurons, suppresses REM sleep [11]. However, unlike PCPA which reduces SWS, administration of a l p h a - m e t h y l - t y r o s i n e , an inhibitor of catecholamine synthesis, fails to inhibit REM sleep in man [42], cat [20,36] and rat [27]. Thus, pharmacological evidence for the role of catecholamines in the genesis or regulation of REM sleep is confusing despite the rather striking effects on REM suggested by lesion experiments. R e c e n t l y , a d m i n i s t r a t i o n of 6-hydroxydopamine (6-OHDA) has been used to induce a relatively specific destruction of neurons in rat brain as evidenced by a longlasting decrease in brain levels of NE without coincident decreases in serotonin [47]. Furthermore, intraventricularly administered 6-OHDA has recently been shown to produce a long-lasting specific reduction in forebrain NE accompanied by a reduction in REM sleep in cats [22,23]. Since the catecholamine-containing cells of the dorsolateral pontine tegmentum (LOC) constitute the primary source of noradrenergic afferents to cortical structures [40], an attempt was made to establish a relationship between the noradrenergic components of this brain region and sleepwaking mechanisms more precisely by injecting 6-OHDA directly into the dorsolateral pons. This approach avoids much of the indiscriminate destruction of fibers of passage and non-catecholaminergic components of this area as well as a disruption of neuron-glial-vascular relationships produced by electrolytic lesions which could conceivably affect sleep.

METHOD Six mongrel, female cats weighing 2 . 5 - 4 . 0 kg were anesthethized with pentobarbital sodium (Diabutal 15 mg/kg), supplemented with ~-chloralose (30 mg/kg), and stereotaxically implanted with electrodes for chronic recording of cortical EEG, neck EMG, and dorsal hippo-

campal, lateral geniculate and eye movement activity. Kopf cannulae were bilaterally implanted into the dorsolateral pontine tegmentum; either at the level of the LOC (Anterior-Posterior = - 3 . 0 : Lateral = 2.8: Vertical = +8.5 mm) or the sub-coeruleus area (AP - 5 . 0 : L 2.0: V +4.5 ram) according to the stereotaxic atlas of ReinosoSufirez [30]. Eight-hour continuous polygraphic recordings were obtained from animals placed in an electrically and acoustically shielded, dimly lit and temperature controlled sleep chamber (130 x 75 x 65 cm) with food and water available ad lib. A flexible cable was attached to a counterweighed 15-lead slip-ring system permitting unrestrained movement. Grass model 5 and 7 polygraphs were run at 3 mm/sec and the resulting records scored in 10 sec epochs according to the criteria of Sterman et al. [34]. Scoring of sleep-waking activity was according to 3 categories: (1) awake; (2) SWS (characterized either by cortical spindles interspersed with brief periods of desynchronization or by continuous cortical synchronization; and (3) REM sleep (characterized by cortical desynchronization, neck atonia, rapid eye movements, PGO waves recorded from the lateral geniculate nucleus and hippocampal theta activity). Baseline values for the three states of vigilance in untreated cats were averaged from 4 - 6 recording sessions taken between 08.30 and 17.00 hr and beginning at least 14 days after surgery. 6-Hydroxydopamine hydrobromide (4.0mg/ml) was prepared in deoxygenated saline (0.9%) containing ascorbic acid (1.0 mg/ml) to reduce oxidation. Animals were placed in a restraining jacket and 20 ~1 of solution was injected slowly into each cannula (15 ul volume) over a period of 20 min. The cannulae were then flushed with 10 ul of vehicle over a period of 10 min. The animal's sleep-waking patterns were recorded on the day of injection and at various intervals during the next 3 - 4 week period. Behavioral observations during the recording sessions supplemented polygraphic indicators of the vigilance states. Five days after the final recording session the subjects were sacrificed and the brains removed for analyses of NE and serotonin. The method of sacrifice and regional brain dissection have been reported previously [35]. Brain regions taken for analyses were: temporal cortex, occipital cortex, anterior pyriform lobe (amygdala), posterior pyriform lobe (hippocampus), basal forebrain area, striatum, lateral and medial hypothalamus, lateral lobe of the cerebellum and the medulla. Tissue levels of NE and serotonin were assayed according to the fluorometric method of Thompson e t al. [37] derived from Maickel e t al. [26]. The mesencephalon and pons were dissected out and placed in 10% buffered Formalin (pH = 7.1). Histological identification of the cannular placements and degree of tissue damage were estimated from serially prepared frozen sections (20 u) stained according to the method of KliiverBarrera [21 ]. The effects of 6-OHDA-induced reductions in brain biogenic amines on vigilance states were assessed using paired t-tests in which the percent of time spent in the three sleep states during the 8-hr recording sessions were compared to the results from the same time period of the untreated baseline conditions. Regression analyses were determined for the three vigilance states from each cat's accumulated sleep records beginning from the day following the injection. The effect of 6-OHDA on regional brain levels of NE and serotonin were compared to corresponding regional amine levels of 17 untreated cats using Student's t-test.

6-HYDROXYDOPAMINE AND SLEEP

559 TABLE 1

EFFECTS OF 6-HYDROXYDOPAMINE DIRECTLY INJECTED INTO THE DORSOLATERAL PONTINE TEGMENTUM ON THE VIGILANCE STATES. VALUES EXPRESSED AS THE MEAN (+ SE) DIFFERENCES BETWEEN THE PERCENT OF TIME SPENT IN A GIVEN SLEEP STATE AFTER DRUG ADMINISTRATION FROM THAT PERCENT WHICH OCCURRED DURING THE PRE-DRUG BASELINE CONDITION. MEAN -+SE BASELINE VALUES AS PERCENT OF RECORDING TIME: AWAKE = 31.2 (2.8);SWS = 51.3 (3.0); REM = 17.5 (1.2)

Vigilance State

Day of Injection

Days 1-5

Days 6-10

Days 11-15

Awake

+38.2 (6.9):~

+0.3 (4.1)

+3.1 (4.9)

-0.6 (4.3)

-10.2 (5.3)

+0.6 (3.4)

SWS

-20.7 (7.1)$

+3.2 (2.9)

+4.5 (2.5)

+7.7 (3.1)*

+12.0 (5.9)*

+7.1 (1.7)*

REM

-17.4 (1.1)§

-3.5 (3.2)

-7.6 (3.6)

-7.2 (2.8)*

- 2.9 (0.1)~

-7.9 (2.9)~t

*p<0.05

tp<0.02

Sp<0.0l

§p<0.001

Days 16-20

Days 21-25

correlated t (2-tail)

RESULTS During the initial 2 - 3 hr following injection of 6-OHDA into the dorsolateral pontine tegmentum, all animals exhibited restlessness accompanied by increased locomotor activity. For the total initial 8-hr postinjection recording period REM sleep was completely absent, SWS was significantly reduced to half of its baseline value (Table I). From 1 - 5 days after injection of 6-OHDA all vigilance states had returned to baseline values except for REM sleep in 2 animals which remained at 45 and 5% of baseline and waking in one animal which was 132% of baseline (Fig. 1). REM sleep progressively decreased in all animals from posttreatment Day 5 throughout the remaining 3 weeks of observation, reaching significantly lower levels from 1 1 - 2 5 days after treatment (Table 1). During the same period SWS progressively increased in 4 cats while SWS in 1 cat initially rose to a peak value at Day 2 after treatment then plateaued at a level greater than baseline for the remaining period of observation (Fig. 1). The mean value for SWS was significantly greater than baseline throughout the 1 1 - 2 5 days posttreatment period. The 6-OHDA treatment produced no consistent effects on percent of waking time throughout the 1 - 2 5 day posttreatment period. Two animals exhibited elevated levels of wakefulness while waking time was slightly depressed in the other 3 animals. Regression analyses of the percent of time spent in each state of vigilance versus posttreatment time revealed a significant downward trend in REM sleep in 3 animals while significant upward trends in SWS were noted in 3 of 5 animals (Table 2). In addition, 2 of the cats exhibited significant downward trends in total waking time throughout the posttreatment period. Other than slight ataxia which occurred during the initial 2 - 4 hr after injection of 6-OHDA into the dorsolateral pontine tegmentum, few behavioral effects were noted in the above 5 animals throughout the 3 week period of observation. Polygraphic indices of sleep states revealed little change in bioelectrical activity except for an increase in the number of PGO spikes discharged during the waking state on the day of injection (mean control value = 1.7 spikes/ min vs. mean treated value = 23 spikes/min; p <0 . 0 5 ; N = 5) and for a loss of the atonicity in the antigravity muscles

which normally occurs during REM sleep. The atonicity slowly disappeared beginning 1 - 2 days after injection in all animals, reaching completion by the 6 - 8 t h day and then returning to normal between 1 6 - 1 8 days after injection. Histological examination of the midbrain-pontine region revealed bilateral destruction of neural elements in the inferior colliculus, LOC, brachium conjunctivum, nucleus parabrachialis, the dorsomedial portion of the nucleus reticularis pontis oralis, the tractus tegmentalis and, occasionally, the ventrolateral segment of the central gray substance (Fig. 2). However, areas of destruction common to all animals were the LOC, the brachium conjunctivum and the nucleus parabrachialis. The rostral extent of the lesion corresponded to the - 1.0 mm plane of the Reinoso-Su~rez atlas while the caudal extent of the affected area corresponded to the - 4 . 0 mm plane. Analyses of regional brain levels of NE one week after the final recording session yielded a highly significant reduction in all areas of the brain with the most pronounced decreases occuring in neocortical areas, basal forebrain area, hippocampus and cerebellum (Table 3). Significant reductions in tissue levels of serotonin were noted in all cortical areas, medulla, striatum, pyriform lobe and the hypothalamus, but not in the basal forebrain area and cerebellum. Except for first day effects, an entirely different spectrum of sleep patterns emerged in one cat given 6-OHDA into the subcoeruleus area and the nucleus reticularis pontis oralis than in the previous 5 animals. During the first week after treatment, SWS increased dramatically, total waking time decreased, and REM sleep remained unchanged from its baseline value (Fig. 3). However, on the tenth day after administration of 6-OHDA, SWS suddenly decreased and then slowly increased again for the remainder of the period of observation. Although, a significant upward trend (r = +0.86, p<0.005) in SWS was evident during the secondary rise, i.e., from Day 1 0 - 3 2 , the overall trend in SWS was not significant nor was the absolute increase when compared to baseline values (Table 2). The daily pattern of wakefulness was essentially a mirror image of the SWS pattern throughout the entire 32 day posttreatment period. The decreasing trend in waking time from 1 0 - 3 2 days was highly signifi-

560

ZOLOVICK, STERN, JALOWIEC, PANKSEPP AND MORGANE

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AWAKE

70 ¸

50 -

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FIG. 1. Sleep-waking patterns of Cats A through E after bilateral injection of 80 pg of 6-hydroxydopamine into the dorsolateral pontine tegmentum. B in lower left corner refers to mean of 3 - 6 baseline sleep state values for the respective cats. Vigilance state values are expressed as percent of recording time.

6-HYDROXYDOPAMINE AND SLEEP

561 TABLE 2

REGRESSION EQUATIONS AND COEFFICIENTS OF VIGILANCE STATES FROM 1-25 DAYS AFTER BILATERAL INJECTION OF 6-HYDROXYDOPAMINE INTO THE DORSOLATERAL PONTINE TEGMENTUM. DATA COMPUTED AS VIGILANCE STATE (PERCENT OF RECORD) VERSUS DAYS AFTER TREATMENT.

Cat

Awake

SWS

REM

A

19.91 +0.43× r = +0.45

55.54 +0.55X, r = +0.941-

23.74 -0.42X, r = -0.81 t

B

39.14 +0.18× r = +0.25

55.34 - 0 . 1 4 x , r = -0.46

9.26 -0.22X, r = 4).83?

C

22.39 -0.02X r = -0.48

56.23 +0.59X, r = +0.81 t

22.82 -0.50X, r = -0.92 t

D

55.22 -0.25X r = - 0 . 9 1 t

42.68 +0.22X, r = +0.11

2.24 -0.05X, r = -0.42

E

27.99 -0.69X r = - 0 . 7 9 t

61.87 +0.39X, r = +0.811-

14.84 -O.03x, r = -0.10

F*

31.37 -0.37X r = -0.51 t

58.10 -0.13X, r = -0.14

10.39 +0.57X, r = +0.815

*data collected for 32 days

tp<0.05

$p<0.005

cant (r = - 0 . 9 1 , p < 0 . 0 0 5 ) as well as its overall t r e n d . REM sleep p e r c e n t a g e s r e m a i n e d u n c h a n g e d t h r o u g h o u t t h e first I0 days a f t e r a d m i n i s t r a t i o n o f 6 - O H D A t h e n progressively increased to a p e a k value at 32 days, a c c o u n t i n g for 30% of t h e r e c o r d i n g at t h a t time. T h e u p w a r d t r e n d in REM sleep f r o m 1 0 - 3 2 days was significant (r = +0.68, p < 0 . 0 2 5 ) as well as its overall t r e n d (Table 2, Cat F). In c o n t r a s t to t h e o t h e r five animals, t h e b e h a v i o r of this cat was d r a m a t i c a l l y a f f e c t e d a f t e r a d m i n i s t r a t i o n of 6-OHDA. In a d d i t i o n , to t h e b e h a v i o r a l e x c i t e m e n t w h i c h o c c u r e d o n t h e d a y o f i n j e c t i o n , Cat F e x h i b i t e d episodes of h a l l u c i n o g e n i c - l i k e b e h a v i o r , p o o r l y d i r e c t e d s h a m rage and u n i l a t e r a l l o c o m o t o r activity (circling) b e g i n n i n g o n the day o f i n j e c t i o n and t e r m i n a t i n g o n Day 11 a f t e r t r e a t m e n t . T h e h a l l u c i n o g e n i c - l i k e episodes o c c u r r e d i n t h e a w a k e s t a t e s h o r t l y a f t e r a REM period. P o l y g r a p h i c e x a m i n a t i o n at the m o m e n t p r e c e d i n g t h e o n s e t o f t h e h a l l u c i n o g e n i c like e p i s o d e s revealed seizure activity t h r o u g h o u t t h e c e r e b r u m . T h e d u r a t i o n o f t h e seizure activity was f r o m 5 0 - 1 3 5 sec and first a p p e a r e d s i m u l t a n e o u s l y in t h e h i p p o c a m p a l a n d LGN leads. Similar to t h e p r e v i o u s 5 cats, b o t h the release of P G O activity i n t o t h e a w a k e s t a t e o n t h e d a y of i n j e c t i o n o f 6 - O H D A as well as t h e o n s e t a n d d u r a t i o n of t h e loss of a t o n i c i t y in p o s t u r a l muscles d u r i n g REM sleep o c c u r r e d in this animal. Histological e x a m i n a t i o n o f t h e p o n s in Cat F revealed e x t e n s i v e bilateral d a m a g e t o t h e s u b c o e r u l e u s area, n u c l e u s reticularis p o n t i s oralis, a n d v e n t r a l p o r t i o n o f t h e c e n t r a l gray s u b s t a n c e (Fig. 4a). A l t h o u g h a considerable loss of n e u r a l e l e m e n t s was e v i d e n t w i t h i n t h e i n j e c t e d area m a n y n e u r o n s escaped t h e c y t o l y t i c effects o f 6 - O H D A (Fig. 4b). Regional levels of NE in Cat F were r e d u c e d in all areas of t h e b r a i n e x c e p t in t h e s t r i a t u m and m e d u l l a w i t h t h e greatest r e d u c t i o n o c c u r r i n g in t h e basal f o r e b r a i n area (80%) and in all n e o c o r t i c a l areas ( 6 - 5 1 % ) . Levels o f NE were r e d u c e d b y 30 and 32% in t h e h y p o t h a l a m u s and a n t e r i o r p y r i f o r m lobe, respectively. Regional levels of s e r o t o n i n were r e d u c e d b y 70% in the m e d i a l h y p o t h a l a m u s and p o s t e r i o r p y r i f o r m l o b e while s e r o t o n i n r e m a i n e d u n c h a n g e d in t h e basal f o r e b r a i n area, occipital

one-tail t-test

c o r t e x a n d s t r i a t u m . S e r o t o n i n levels in the r e m a i n i n g areas of t h e b r a i n were r e d u c e d b y 2 8 - 4 1 % . DISCUSSION Results f r o m t h e p r e s e n t s t u d y s h o w t h a t i n j e c t i o n of 6 - O H D A i n t o t h e LOC and a d j a c e n t tissue p r o d u c e s a long t e r m r e d u c t i o n in REM sleep and an increase in SWS. These results are c o n s i s t e n t w i t h results f r o m previous studies w h i c h also s h o w a m a r k e d r e d u c t i o n in R E M sleep [5, 8, 31, 32] a n d an increase in SWS [5] a f t e r e l e c t r o l y t i c d e s t r u c t i o n of t h e d o r s o l a t e r a l p o n t i n e t e g m e n t u m sparing the m i d l i n e r a p h 6 nuclei. However, the l o c a t i o n o f the pacem a k e r for genesis o f REM sleep in t h e p o n s is less clearly defined. J o u v e t [ 15,18] places t h e REM sleep g e n e r a t o r in a diffuse area of the p o n t i n e t e g m e n t u m c o n t a i n i n g t h e m i d d l e a n d caudal region of t h e LOC along w i t h t h e dorsocaudal area of t h e n u c l e u s reticularis p o n t i s oralis ( N P O ) a n d the rostral area o f t h e n u c l e u s reticularis p o n t i s caudalis. However, Carli and Z a n c h e t t i , favor a m e d i o l a t e r a l p o s i t i o n in t h e m i d d l e a n d caudal t h i r d o f t h e NPO [7, 8, 4 3 ] . The p r e s e n t s t u d y suggests an i m p o r t a n t role for t h e catecholamine-containing n e u r o n s o f t h e LOC a n d i m m e d i a t e l y s u r r o u n d i n g tissue in t h e i n d u c t i o n o f REM sleep r a t h e r t h a n t h e NPO, since extensive d a m a g e to t h e NPO (Cat F ) failed t o reduce REM episodes and, in fact, caused an increase in R E M sleep, while d e s t r u c t i o n o f t h e LOC r e d u c e d REM sleep in all subjects. The results of Carli e t al. [ 8 , 4 3 ] can be e x p l a i n e d , in p a r t , b y an i n t e r r u p t i o n of a s c e n d i n g p r o j e c t i o n s f r o m the c a t e c h o l a m i n e - c o n t a i n i n g n e u r o n s of t h e LOC and a d j a c e n t area w h i c h course diffusely t h r o u g h t h e dorsal NPO at t h e level t h e y m a d e t h e i r lesions [ 2 5 , 3 3 ] . T h e r e d u c t i o n in f o r e b r a i n NE ( p a r t i c u l a r y in cortical and h i p p o c a m p a l tissue) in Cat F a f t e r p l a c e m e n t of 6 - O H D A i n t o t h e d o r s o r o s t r a l p o r t i o n of t h e NPO lends s u p p o r t to t h e above i n t e r p r e t a t i o n . Similarly, t h e increase in SWS m i g h t t h e n be a c c o u n t e d for b y a d i s r u p t i o n of a s c e n d i n g activating i n f l u e n c e s o r i g i n a t i n g from t h e LOC [18, 28, 2 9 ] , i.e., r e m o v a l o f a s y s t e m w h i c h p r o b a b l y exerts an i n h i b i t o r y effect o n a SWS m e c h a n i s m [ 3 , 2 4 ] .

ZOLOVICK, STERN, JALOWIEC, PANKSEPP AND MORGANE 562

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-1.0

.'L M,"

FIG. 2. Diagrammatic reconstruction of mesencephalic-pontine region of cat brain illustrating extent of 6-hydroxydopamine-induced lesions in Cats A thru E. Arrows indicate line-cat code of lesion. Numbers on right of figure refers to corresponding anterior-posterior planes (in ram) from the Reinoso-Suarez cat atlas. A = cerebral aqueduct, BP = brachium pontis, CG = central gray substance, IC = inferior colliculus, LM = lemniscus medialis, MLF = medial longitudal fasciculus, NCS = nucleus centralis superior of Bechterew, NPO = nucleus reticularis pontis oralis, P = pons.

6-HYDROXYDOPAMINE

AND SLEEP

563

TABLE 3 EFFECTS OF 6-HYDROXYDOPAMINE INJECTED INTO THE DORSOLATERAL PONTINE TEGMENTUM ON REGIONAL BRAIN LEVELS OF NOREPINEPHRINE AND SEROTONIN. TISSUE VALUES EXPRESSED AS ng OF amine/g OF TISSUE (MEAN -+ SE). CATS WERE SACRIFICED 5 - 6 WEEKS AFTER INTRACEREBRAL INJECTION OF 6-HYDROXYDOPAMINE.

Brain Region

Norepinephrine Normal N=17

Serotonin

Treated N=5

Normal N=17

Treated N=5

Temporal Cortex

298 -+ 11

144 +- 30:~

473 _+ 15

Anterior Pyriform Lobe (Amygdala)

356 -+ 13

220 -+ 42:~

1529 _+ 62

1097 +- 226 t

Posterior Pyriform Lobe (Hippocampus)

237 -+ 12

130 -+ 16~t

1486 _+ 107

795 ± 154"

1183 -+ 70

449 -+ 58:~

1673 _+ 71

135"+

13:~

1 1 4 0 -+ 76

810 + _ 149"

4:~

412 -+ 22

245 _+ 26*

Basal ForebrainArea

358_+ 13~:

1674 -+ 128

Striatum

300"+ 12

Occipital Cortex

297 +- 14

Lateral Hypothalamus

906 -+ 52

392 -+ 47~

1769 -+ 81

1116 ± 118:~

Medial Hypothalamus

1998 +- 90

1085 -+ t07:~

1785 "+ 92

1140 +_ 110"

Cerebellum (Lateral Lobe)

285 ± 10

140 -+ 15:~

371 -+ 21

300 ± 50

Medulla

320-+ 16

200-+

*p<0.01

tp<0.02

:~p<0.001

82 -+

22*

1119"+

58

623 ± 525

Student's t-test (2-tailed)

c¢ 80

== so

=

sls

N,-

40

awak a. 20

0

/

0

_

5

1'0

1'5 Days

_

2'0

_

215

_

3'0

FIG. 3. Sleep-waking patterns of Cat F after bilateral injection of 80 ~g of 6-hydroxydopamine into the dorsomedial pontine tegmentum. B in lower left corner refers to mean of 6 baseline values for the respective vigilance state. Vigilance state values expressed as percent of recording time.

564

ZOLOVICK, STERN, JALOWIEC, PANKSEPP AND MORGANE

a

J

e.\Q;

L2

e;

.

FIG. 4a. Histological section illustrating lesion in pontine tegmentum of cat F sacrificed 35 days after receiving bilateral injections of 80 ug of 6-hydroxydopamine. Arrow indicates point-of-entry of cannyla. Magnification is 5.7X. Kluver-Barrera stain• The p r e s e n t s t u d y also c o n f i r m s t h e original o b s e r v a t i o n b y J o u v e t a n d co-workers [ 2 2 , 2 3 ] , t h a t 6 - O H D A p r o d u c e s t w o d i s t i n c t t i m e - d e p e n d e n t effects o n sleep-waking b e h a v ior. T h e initial arousal w h i c h occurs i m m e d i a t e l y a f t e r i n j e c t i o n o f 6 - O H D A i n t o t h e p o n t i n e t e g m e n t u m or ventricles m a y be d u e to an a c u t e l i b e r a t i o n of s y n a p t i c a l l y active NE [ 2 , 1 2 ] , while the c h r o n i c sleep effects of the t r e a t m e n t m a y b e due to p e r m a n e n t d e g e n e r a t i o n of an a s c e n d i n g n o r a d r e n e r g i c s y s t e m r e s u l t i n g in an i m b a l a n c e in c a t e c h o l a m i n e r g i c - s e r o t o n e r g i c t o n e [ 18 ]. H o w e v e r , c e r t a i n d i f f e r e n c e s b e t w e e n these studies can b e n o t e d . In o u r s t u d y , t h e initial b e h a v i o r a l e x c i t a t i o n t e r m i n a t e d 2 - 3 h r a f t e r a d m i n i s t r a t i o n of 6 - O H D A , whereas the b e h a v i o r a l e x c i t a t i o n was m o r e p r o n o u n c e d , o f a longer d u r a t i o n and

a c c o m p a n i e d b y a severe d i s r u p t i o n in a u t o n o m i c f u n c t i o n o f t e n leading to d e a t h w h e n the LOC was d e s t r o y e d via i n t r a v e n t r i c u l a r i n j e c t i o n s of 6-OHDA [ 9 , 2 2 ] . This l a t t e r result suggests a m o r e widespread effect of the drug w h e n given via the i n t r a v e n t r i c u l a r route. The acute a u t o n o m i c r e s p o n s e appears to result from a l i b e r a t i o n of b o t h NE and s e r o t o n i n , since the e x c i t a t i o n can be p r e v e n t e d b y prior i n h i b i t i o n of c a t e c h o l a m i n e synthesis, while t h e h y p o t h e r m i a and initial release o f PGO spikes can b e p r e v e n t e d b y p r e t r e a t m e n t w i t h c h l o r i m i p r a m i n e , a drug t h a t p r e v e n t s t h e n o n s e p c i f i c u p t a k e of 6-OHDA i n t o s e r o t o n i n n e u r o n s [ 2 3 ] . The initial release of PGO activity t h a t o c c u r r e d in 5 of 6 cats in this s t u d y c o m b i n e d w i t h the long term reduction in b r a i n levels of s e r o t o n i n suggest a 6 - O H D A - i n d u c e d

6-HYDROXYDOPAMINE AND SLEEP

565

FIG. 4b. High-power photomicrograph of area on right side of lesion (see Fig. 4a) illustrating 6-hydroxydopamine-induced cytological damage. Magnification is 202X. disruption of serotonergic mechanisms. Secondly, the time course and duration of the abolition of atonicity in antigravity muscles during REM sleep after injection of 6-OHDA into the pontine tegmentum is similar to that

produced following electrocoagulation of the LOC [ 18]. However, this effect was not produced after intraventricular administration of 6-OHDA [23]. Since decrements in NE were of a similar magnitude in this study and the latter

566

ZOLOVICK, STERN, JALOWIEC, PANKSEPP AND MORGANE

study, it can be concluded that either 6-OHDA was unable to diffuse into the critical elements subserving this function via the intraventricular route or the inhibitory influence on antigravity muscles should not be attributed solely to descending catecholaminergic influences as originally envisioned by Jouvet [16]. In the latter regard George e t al. [ 13] and Baxter [ 1 ] have emphasized the importance of a descending cholinergic pathways originating in the pontomesencephalic reticular formation in the induction of some tonic phenomena associated with REM sleep. Since we did not assess damage to the cholinergic system originating in the dorsal pons produced by our 6-OHDA injections, it is possible that the decrease in REM sleep or the effects on components of REM sleep were due to interference with a cholinergic sleep mechanism. Finally, neither injection of 6-OHDA into the coeruleus complex or into the ventricle elicits hallucinogenic-like behavior which has been reported following bilateral coagulation of the LOC [16]. Although, we have been able to confirm the occurrence of this abnormal behavior in one animal which received 6-OHDA primarily into the NPO, it appears doubtful that such behavior can be attributed to disruption of the catecholamine mechanisms of the coeruleus complex. E x c l u d i n g the acute effects of administration of 6-OHDA, sleep parameters were not significantly different from baseline conditions until after postinjection Day 10. At that time, SWS increased and REM sleep decresed and remained so for the duration of the experiment. The time lag required to achieve this effect combined with the significant correlation of the sleep parameters with time (Table 2) is consistent with a slow degeneration of, or a progressive dysfunction of sleep mechanisms within the coeruleus complex. Histological verification of the affected area, biochemical analysis of regional levels of NE and behavioral effects on sleep in Cats A - E (Figs. I and 2) indicate extensive but not total or permanent dysfunction of the LOC after injection of 6-OHDA. The recovery of the neck muscle atonia of REM sleep between 1 6 - 1 8 days after the injection combined with only a 38% increase in medullary NE suggest that the descending limb originating from the caudal LOC [18] is either resistant to the chemolytic effects of 6-OHDA [39] or that this tonic event of REM sleep is not solely dependent upon the catecholaminergic

components of the LOC. Failure to detect cytological changes in the caudal LOC suggests that this structure was not sufficiently perfused by the injection of 6-OHDA or that a partial reestablishment of functional connections had taken place in the intervening time period. Since complete destruction of the caudal 2/3 of the LOC may be necessary to achieve total suppression of REM sleep [18], failure to completely destroy this structure in any of the cats in the present study precluded a complete loss of REM sleep. However, a permanent 95% reduction in REM sleep was noted in one animal (Cat D) which sustained the greatest degree of damage to the LOC. It would appear from the present data that the ascending projections from the anterior LOC, which may subserve cortical desynchronization during wakefulness, were not sufficiently affected by our treatment as evidenced by a failure to observe a significant decrease in waking time [18]. Histology revealed that the cannular placements were not sufficiently rostral to completely destroy the diffuse rostral and lateral catechol a m i n e - c o n t a i n i n g neurons which contribute to the ascending cortical system [ 16]. Regarding the lesion itself, in s i t u injection of 6-OHDA by no means results in the global tissue destruction produced by electrocoagulation. Although a large number of neurons were destroyed (Fig. 4a, b) many neurons appeared to escape the cytolytic effects of 6-OHDA. Thus, it may be assumed that at least a portion of the affected area can remain functionally active. The latter assumption may in fact account for the disparity between results from electrolytic lesion studies and results from the present study. The significant reduction in NE throughout the forebrain after injection of 6-OHDA into the dorsolateral pontine tegmentum confirms previous reports of the catecholaminolytic effect of the drug in brain tissue [4,39]. However, coincident reductions in brain levels of serotonin following this treatment indicates that the drug lacks the degree of specificity that has been reported for the rat [4, 38, 41]. Since depressed levels of serotonin generally lead to a reduction in SWS [18], it appears unlikely that the lowered levels of serotonin played a significant role in the changes seen in sleep-waking behavior in the present study in view of the reliable increase in SWS that occurred between Days 10 25 after treatment.

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