The blockage of ponto-geniculo-occipital waves in the cat lateral geniculate nucleus by nicotinic antagonists

Discharge and Role of Acetylcholine Pontomesencephalic Neurons in Cortical Activity and Sleep-Wake States Examined by Optogenetics and Juxtacellular Recording in Mice

Acetylcholine (ACh) neurons in the pontomesencephalic tegmentum (PMT) are thought to play an important role in promoting cortical activation with waking (W) and paradoxical sleep [PS; or rapid eye movement (REM)], but have yet to be proven to do so by selective stimulation and simultaneous recording of identified ACh neurons. Here, we employed optogenetics combined with juxtacellular recording and labeling of neurons in transgenic (TG) mice expressing ChR2 in choline acetyltransferase (ChAT)-synthesizing neurons. We established in vitro then in vivo in anesthetized (A) and unanesthetized (UA), head-fixed mice that photostimulation elicited a spike with short latency in neurons which could be identified by immunohistochemical staining as ACh neurons within the laterodorsal (LDT)/sublaterodorsal (SubLDT) and pedunculopontine tegmental (PPT) nuclei. Continuous light pulse stimulation during sleep evoked tonic spiking by ACh neurons that elicited a shift from irregular slow wave activity to rhythmic θ and enhanced γ activity on the cortex without behavioral arousal. With θ frequency rhythmic light pulse stimulation, ACh neurons discharged in bursts that occurred in synchrony with evoked cortical θ. During natural sleep-wake states, they were virtually silent during slow wave sleep (SWS), discharged in bursts during PS and discharged tonically during W. Yet, their bursting during PS was not rhythmic or synchronized with cortical θ but associated with phasic whisker movements. We conclude that ACh PMT neurons promote θ and γ cortical activity during W and PS by their tonic or phasic discharge through release of ACh onto local neurons within the PMT and/or more distant targets in the hypothalamus and thalamus.

Discharge properties of presumed cholinergic and noncholinergic laterodorsal tegmental neurons related to cortical activation in non-anesthetized mice

We have recorded, for the first time, in non-anesthetized, head-restrained mice, a total of 339 single units in and around the laterodorsal (LDT) and sublaterodorsal (SubLDT) tegmental nuclei, which are located, respectively, in, or beneath, the periaqueductal gray and contain cholinergic neurons. The recordings were made during the complete wake-sleep cycle including wakefulness (W), slow-wave sleep (SWS), and paradoxical (or rapid eye movement) sleep (PS). The tegmental neurons displayed either a biphasic narrow or triphasic broad action potential. Seventy-six LDT or SubLDT neurons characterized by their triphasic long-duration action potentials were judged to be cholinergic and this was verified in anesthetized mice using neurobiotin juxtacellular labeling combined with choline acetyltransferase immunohistochemistry of the recorded cell. The 76 presumed cholinergic neurons discharged tonically at the highest rate during W and PS (W/PS-active neurons) as either single isolated spikes or clusters of two to five spikes, and 26 of them discharged selectively during W and PS, these W/PS-selective neurons being found mainly in the SubLDT. The clustering discharge was particularly prominent during PS, when it was associated with an obvious phasic change in the cortical electroencephalogram (EEG), and during waking periods, when it was accompanied by abrupt body movements. During the transition from sleep to waking, the cholinergic W/PS-selective neurons and the LDT or SubLDT noncholinergic W-selective neurons showed firing before the onset of W, while, at the transition from waking to sleep, they ceased firing before sleep onset. At the transition from SWS to PS, all the cholinergic neurons exhibited a significant increase in discharge rate before the onset of PS. The present study in mice supports the view that cholinergic and noncholinergic LDT and SubLDT neurons play an important role in tonic and phasic processes of arousal and cortical EEG activation occurring during W or PS, as well as in the sleep/waking switch.

Control of sleep and wakefulness

This review summarizes the brain mechanisms controlling sleep and wakefulness. Wakefulness promoting systems cause low-voltage, fast activity in the electroencephalogram (EEG). Multiple interacting neurotransmitter systems in the brain stem, hypothalamus, and basal forebrain converge onto common effector systems in the thalamus and cortex. Sleep results from the inhibition of wake-promoting systems by homeostatic sleep factors such as adenosine and nitric oxide and GABAergic neurons in the preoptic area of the hypothalamus, resulting in large-amplitude, slow EEG oscillations. Local, activity-dependent factors modulate the amplitude and frequency of cortical slow oscillations. Non-rapid-eye-movement (NREM) sleep results in conservation of brain energy and facilitates memory consolidation through the modulation of synaptic weights. Rapid-eye-movement (REM) sleep results from the interaction of brain stem cholinergic, aminergic, and GABAergic neurons which control the activity of glutamatergic reticular formation neurons leading to REM sleep phenomena such as muscle atonia, REMs, dreaming, and cortical activation. Strong activation of limbic regions during REM sleep suggests a role in regulation of emotion. Genetic studies suggest that brain mechanisms controlling waking and NREM sleep are strongly conserved throughout evolution, underscoring their enormous importance for brain function. Sleep disruption interferes with the normal restorative functions of NREM and REM sleep, resulting in disruptions of breathing and cardiovascular function, changes in emotional reactivity, and cognitive impairments in attention, memory, and decision making.

Beta2-containing nicotinic receptors contribute to the organization of sleep and regulate putative micro-arousals in mice

The cholinergic system is involved in arousal and in rapid eye movement sleep (REMS). To evaluate the contribution of nicotinic acetylcholine receptors (nAChRs) to these functions, we studied with polygraphic recordings the regulation of sleep in mice lacking the beta2 subunit gene of the nAChRs, a major component of high-affinity nicotine binding sites in the brain. Nicotine (1-2 mg/kg, i.p.) increased wakefulness in wild-type but not knock-out animals, indicating that beta2-containing nAChRs mediate the arousing properties of nicotine. Under normal conditions, the beta2-/- mice displayed the same amounts of waking, non-REM sleep (NREMS) and REMS as their wild-type counterparts. However, they exhibited longer REMS episodes and a reduced fragmentation of NREMS by events characterized notably by a transient drop in EEG power and frequently associated with EMG activation, tentatively referred to as micro-arousals. Respiration monitoring showed that these events were accompanied with, but not caused by, breathing irregularities. Sleep deprivation of beta2-/- mice resulted in a normal increase in REMS episode duration and NREMS delta power but yielded a reduction of the number of micro-arousals in NREMS. In contrast, in beta2-/- mice, a 1 hr immobilization stress failed to produce the normal rebound in REMS in the following 12 hr and, instead, was associated with increased NREMS fragmentation and sustained corticosterone levels. Our results show that the beta2-containing nAChRs contribute to the organization of sleep by regulating the transient phasic activity in NREMS, the REMS onset and duration, and the REMS-promoting effect of stress.

Modulation of presumed cholinergic mesopontine tegmental neurons by acetylcholine and monoamines applied iontophoretically in unanesthetized cats

The mesopontine tegmentum, which contains both cholinergic and non-cholinergic neurons, plays a crucial role in behavioral state control. Using microiontophoresis in unanesthetized cats, we have examined the effect of cholinergic and monoaminergic drugs on two putative cholinergic neurons located mostly in the laterodorsal tegmental nucleus and X area (or the cholinergic part of the nucleus tegmenti pedunculopontinus, pars compacta): one (type I-S) exhibiting slow tonic discharge during both waking and paradoxical sleep, and the other (PGO-on) displaying single spike activity during waking and burst discharges in association with ponto-geniculo-occipital (PGO) waves during paradoxical sleep. We found that: (i) application of carbachol, a potent cholinergic agonist, inhibited single spike activity in both PGO-on and type I-S neurons, but had no effect on the burst activity of PGO-on neurons during paradoxical sleep; the inhibition was associated with either blockade or increased latency of antidromic responses, suggesting membrane hyperpolarization; (ii) application of glutamate, norepinephrine, epinephrine, or histamine resulted in increased tonic discharge in both PGO-on and type I-S neurons; this was state-independent and resulted in a change in the firing mode of PGO-on neurons from phasic to tonic; (iii) application of serotonin had only a weak state-dependent inhibitory effect on a few type I-S neurons; and (iv) application of dopamine had no effect on either type of neuron. The present findings suggest that cholinergic, glutamatergic and monoaminergic (especially noradrenergic, adrenergic and histaminergic) inputs have the capacity to strongly modulate the cholinergic neurons, altering both their rate and mode of discharge, such as to shape their state specific activity, and thereby contribute greatly to their role in behavioral state control.

Endogenous and exogenous factors on sleep-wake cycle regulation

A number of theories have proposed the involvement of different brain structures and neurotransmitters in order to explain the regulation of the sleep wake cycle. However, there is no clear consensus as to the mechanisms through which the brain structures and their various neurotransmitters interact to produce theses phases. Perhaps the problem is related to the fact sleep is a very fragile state, easily modified or influenced by a variety of substances or experimental manipulations. In this paper, we describe the evidence of two different groups of factors that induce important changes on the sleep wake cycle. The endogenous factors: neurotransmitters; hormone; peptides; and some substances of lipidic nature and exogenous factors: stress, food intake, learning, sleep deprivation, sensorial stimulation, exercise and temperature on the regulation the sleep-wake cycle. Likewise, we propose a hypothesis which attempts to reconcile the fact that endogenous and exogenous factors have similar effects.

Neuronal activity in the lateral geniculate nucleus associated with ponto-geniculo-occipital waves lacks lamina specificity

Ponto-geniculo-occipital (PGO) waves are spontaneously occurring field potentials recorded in the dorsal lateral geniculate nucleus (LGN) just prior to and during rapid eye movement (REM) sleep. Facilitated discharge rates of LGN neurons are associated with PGO waves. In kittens during the critical period of visual system development, both visual experience and PGO waves appear capable of influencing the course of development through activity-dependent mechanisms. Retinal innervation of LGN segregates into eye-specific laminae and is critical to supporting the role of binocular visual experience in development. We sought to determine whether neuronal activity associated with PGO waves also exhibits lamina specificity. PGO wave-related discharges were examined in LGN neurons identified as to lamina location in adult cats administered urethane anesthesia and the reserpine-like compound, RO4-1284. Spontaneous activity of LGN neurons was related to the occurrence of PGO-like waves in all cells studied. No factors could be found that differentiated lamina location and PGO wave-related discharges. We conclude that the PGO wave influence on neuronal activity in the visual system is fundamentally different from that derived from visual experience. The implications of this difference for the role of the two sources of activation in the control of neural activity in development are discussed.

The fasciculus retroflexus controls the integrity of REM sleep by supporting the generation of hippocampal theta rhythm and rapid eye movements in rats

The fasciculus retroflexus (FR) fiber bundle comprises the intense cholinergic projection from the medial division of the habenula nucleus (Hbn) of the epithalamus to the interpeduncular nucleus (IPN) of the limbic midbrain. Due to the widespread connections of the Hbn and IPN, it could be surmised that the FR is integrated in the processings of various subsystems that are known to be involved in the sleep-wake mechanisms; relevant sites include the limbic forebrain and midbrain areas and more caudal pontine structures. Consequently, the present study addressed the significance of the FR in the spontaneous sleep-wake stage-associated variations of the different activity patterns of frontal cortex and hippocampal electroencephalograms (EEGs), the electrooculogram, and body movements, in freely behaving rats that had been subjected to either bilateral electrolytic lesioning of the FR or control operations. The evolution of different state combinations was assessed by the combinatory analysis of different activity stages appearing on the 6-h records. As compared to the control-operated group, the FR lesioning substantially reduced the time spent in rapid eye movement (REM) sleep by 79%, moderately decreased the duration of the intermediate state of sleep by 29%, and quiet waking state by 44%, but had virtually no effects on the durations of different types of non-REM sleep (i.e., drowsiness that which involved quiet sleep or slow-wave sleep containing delta and spindle state components) or on the times of active waking behavior that corresponded to the body movements. Quantitative decomposition analyses revealed marked variations in the frontal cortex and hippocampal activity as well as REM during the course of the extracted sleep-wake stages described and there were also some group differences. Of those individual features that were used to determine different sleep-wake stages, the overall hippocampal theta time (41% decrease) and single REM frequency (71% reduction during the REM sleep) were most affected. In contrast, the various properties of desynchronization/synchronization patterns of frontal cortex EEGs were consistently hardly influenced by the FR lesioning. Therefore, the present data suggest the involvement of the FR in the REM sleep processes by establishing prominent associations with the limbic and REM control mechanisms that involve the hippocampus and plausibly pontine ocular activity networks.

Serotonergic dorsal raphe nucleus projections to the cholinergic and noncholinergic neurons of the pedunculopontine tegmental region: a light and electron microscopic anterograde tracing and immunohistochemical study

The serotonergic dorsal raphe nucleus is considered an important modulator of state-dependent neural activity via projections to cholinergic neurons of the pedunculopontine tegmental nucleus (PPT). Light and electron microscopic analysis of anterogradely transported biotinylated dextran, combined with choline acetyltransferase (ChAT) immunohistochemistry, were employed to describe the synaptic organization of mesopontine projections from the dorsal raphe to the PPT. In a separate set of experiments, we utilized immunohistochemistry for the serotonin transporter (SERT), combined with ChAT immunohistochemistry at the light and electron microscopic levels, to determine whether PPT neurons receive serotonergic innervation. The results of these studies indicate that: (1) anterogradely labeled and SERT-immunoreactive axons and presumptive boutons invest the PPT at the light microscopic level; (2) at the ultrastructural level, dorsal raphe terminals in the PPT pars compacta synapse mainly with dendrites and axosomatic contacts were not observed; (3) approximately 12% of dorsal raphe terminals synapse with ChAT-immunoreactive dendrites; and (4) at least 2-4% of the total synaptic input to ChAT-immunoreactive dendrites is of dorsal raphe and/or serotonergic origin. This serotonergic dorsal raphe innervation may modulate cholinergic PPT neurons during alterations in behavioral state. The role of these projections in the initiation of rapid eye movement (REM) sleep and the ponto-geniculo-occipital waves that precede and accompany REM sleep is discussed.

Transdermal nicotine on sleep and PGO spikes

There is conflicting evidence for the role of nicotine in sleep regulation. This study was undertaken to determine the effects of transdermal nicotine at doses of 17.5, 35 and 52.5 mg on sleep and PGO spike activity. Minor effects were observed on sleep with a general increase in waking. PGO spike activity was abolished by all patches. The results are discussed in terms of the mechanisms involved in the disappearance of PGO spikes as a result of nicotine.

State-dependent phenomena in cat masseter motoneurons

In the present study we explored the mechanisms of carbachol-induced muscle atonia in the alpha-chloralose-anesthetized animal. We compared our findings to those that have been previously obtained in unanesthetized cats during muscle atonia occurring during natural active sleep. Accordingly, in cats anesthetized with alpha-chloralose, intracellular records were obtained from masseter motoneurons before and after carbachol-induced motor atonia. Following the induction of atonia, the membrane potential activity was dominated by high-frequency, discrete, hyperpolarizing potentials. These hyperpolarizing potentials were reversed in polarity by the intracellular injection of chloride ions and abolished by the application of strychnine. These findings indicate that they were inhibitory postsynaptic potentials (IPSPs) mediated by glycine. These IPSPs appeared exclusively during muscle atonia. In addition, masseter motoneurons were significantly hyperpolarized and their rheobase increased. There was a decrease in input resistance and membrane time constant. In the alpha-chloralose-anesthetized preparation, stimulation of the nucleus pontis oralis (NPO) induced IPSPs in masseter motoneurons following, but never prior to, the pontine injection of carbachol. Thus, this is the first demonstration that "reticular response-reversal' may be elicited in an anesthetized preparation. Another state-dependent phenomenon of active sleep, the occurrence of IPSPs in motoneurons that are temporally correlated with ponto-geniculo-occipital (PGO) waves, was also observed in this preparation only after carbachol administration. Based on the data in this report, we conclude that the inhibitory system that mediates atonia during the state of active sleep can be activated in an animal that is anesthetized with alpha-chloralose. Specifically, the neuronal groups that generate spontaneous IPSPs, those that mediate the phenomenon of reticular response-reversal, and those involved in the generation of PGO waves are capable of being activated and remain functional during alpha-chloralose-anesthesia.

Cholinergic receptor subtypes and REM sleep in animals and normal controls

As reviewed here and elsewhere in this symposium, acetylcholine, in conjunction with other neurotransmitter systems, plays a very important role in the regulation of circadian and sleep-wake states. To briefly recapitulate, several current basic concepts about the regulation of sleep-wake states include: (a) REM sleep, or at least its phasic events (eye movements and PGO spikes), are promoted by cholinergic neurons originating within the peribrachial regions [LDT/PPT] (Mitani et al., 1988; Shiromani et al., 1988; Datta et al., 1991; Shouse and Siegel, 1992); (b) REM sleep may be inhibited by noradrenergic and serotonergic neurons in the locus coeruleus and dorsal raphe, respectively (Siegel, 1989; Steriade and McCarley, 1990; Jones, 1991); (c) stages 3 and 4 (Delta) sleep are inhibited by cholinergic terminals from basal forebrain to cortex (Buzsaki et al., 1988) and from LDT/PPT to thalamus (Steriade and McCarley, 1990; Steriade et al., 1991); (d) Delta sleep is modulated by complex serotonergic mechanisms; for example, it is increased by pharmacological antagonists of 5HT2 receptors (Declerck et al., 1987; Dugovic et al., 1989; Benson et al., 1991), although the mechanism and neuroanatomical site at which this effect occurs is unknown. Given the importance of mACHR mediation of components of REM sleep, it is unfortunate that so little is known about the distribution of the various subtypes of mACHRs in brainstem areas which regulate REM sleep. mACHR subtypes have been identified by molecular, biological and pharmacological methods.(ABSTRACT TRUNCATED AT 250 WORDS)

Afferent projections to the cholinergic pedunculopontine tegmental nucleus and adjacent midbrain extrapyramidal area in the albino rat. I. Retrograde tracing studies

The afferent connections of the pedunculopontine tegmental nucleus (PPT) and the adjacent midbrain extrapyramidal area (MEA) were examined by retrograde tracing with wheat germ agglutinin-conjugated horseradish peroxidase (WGA-HRP). Major afferents to the PPT originate in the periaqueductal gray, central tegmental field, lateral hypothalamic area, dorsal raphe nucleus, superior colliculus, and pontine and medullary reticular fields. Other putative inputs originate in the paraventricular and preoptic hypothalamic nuclei, the zona incerta, nucleus of the solitary tract, central superior raphe nucleus, substantia innominata, posterior hypothalamic area, and thalamic parafascicular nucleus. The major afferent to the medially adjacent MEA originates in the lateral habenula, while other putative afferents include the perifornical and lateral hypothalamic area, periaqueductal gray, superior colliculus, pontine reticular formation, and dorsal raphe nucleus. MEA inputs from basal ganglia nuclei include moderate projections from the substantia nigra pars reticulata, entopeduncular nucleus, and a small projection from the globus pallidus, but not the subthalamic nucleus. Dense anterograde labeling was observed in the substantia nigra pars compacta, entopeduncular nucleus, subthalamic nucleus, globus pallidus, and caudate-putamen only following WGA-HRP injections involving the MEA. The results of this study demonstrate that the PPT and MEA share many potential afferents. Remarkable differences were found that support distinguishing between these two nuclei in future studies regarding the functional organization of the midbrain and pons. The results, for example, confirm our previous observations that the largely reciprocal connections between the midbrain and basal ganglia distinguish the MEA from the PPT. Afferents from the lateral habenula and contralateral superior colliculus represent extensions of more traditional basal ganglion circuitry which further delineate the MEA from the PPT. The results are discussed with respect to the important role of the midbrain and pons in behavioral state control and locomotor mechanisms.

Paradoxical sleep and its chemical/structural substrates in the brain

As originally named for the ostensibly contradictory appearance of rapid eye movements and low voltage fast cortical activity during behavioral sleep, paradoxical sleep or rapid eye movement sleep, represents a distinct third state, in addition to waking and slow wave sleep, in mammals and birds. It is an internally generated state of intense tonic and phasic central activation that is contemporaneous with the inhibition of sensory input and motor output. In early studies, it was established that the state of paradoxical sleep was generated within the brainstem, and particularly within the pons. Pharmacological studies indicated an important role for acetylcholine as a neurotransmitter in the generation of this state. Local injections of cholinergic agonists into the pontine tegmentum triggered a state of paradoxical sleep marked by phasic ponto-geniculo-occipital spikes in association with cortical activation and neck muscle atonia. Following the immunohistochemical identification of choline acetyl transferase-containing neurons and their localization to the dorsolateral ponto-mesencephalic tegmentum, neurotoxic lesions of this major cholinergic cell group could be performed to assess its importance in paradoxical sleep. Destruction of the majority of the cholinergic cells, which are concentrated within the laterodorsal tegmental and pedunculopontine tegmental nuclei but extend also into the locus coeruleus and parabrachial nuclei in the cat, resulted in a loss or diminishment of the state of paradoxical sleep, ponto-geniculo-occipital spiking and neck muscle atonia. These deficits were correlated with the loss of choline acetyltransferase-immunoreactive neurons in the region, so as to corroborate results of pharmacological studies and single unit recording studies indicating an active role of these cholinergic cells in the generation of paradoxical sleep and its components. These cells provide a cholinergic innervation to the entire brainstem reticular formation that may be critical in the generation of the state which involves recruitment of massive populations of reticular neurons. Major ascending projections into the thalamus, including the lateral geniculate, may provide the means by which phasic (including ponto-geniculo-occipital spikes) and tonic activation is communicated in part to the cerebral cortex. Descending projections through the caudal dorsolateral pontine tegmentum and into the medial medullary reticular formation may be involved in the initiation of sensorimotor inhibition. Although it appears that the pontomesencephalic cholinergic neurons play an important, active role in the generation of paradoxical sleep, this role may be conditional upon the simultaneous inactivity of noradrenaline and serotonin neurons, evidence for which derives from both pharmacological and recording studies.(ABSTRACT TRUNCATED AT 400 WORDS)

Anatomical interconnections of the pedunculopontine tegmental nucleus and the nucleus prepositus hypoglossi in the cat

The Pedunculopontine tegmental nucleus (PPT) is a mesopontine structure containing predominantly cholinergic neurons, and physiological data indicate its neurons transfer eye-movement gated ponto-geniculo-occipital (PGO) waves to thalamus during the rapid eye movement phase of sleep. The present study, using anterograde and retrograde tracing of wheat germ agglutinin-conjugated horseradish peroxidase, found that the medullary nucleus Prepositus hypoglossi (PH), whose neurons are known to have eye-movement-related information, projects densely to PPT, and PPT has reciprocal projections to PH. The PH-PPT projection has some topographic organization, with rostral PH to rostral PPT and caudal PH to caudal PPT projections dominating. The PH-PPT projection may furnish the anatomical substrate for input of eye movement-related information into the rostral PGO wave system.

Pontine cholinergic neurons simultaneously innervate two thalamic targets

Cholinergic neurons located in the lateral dorsal tegmental (LDT) and pedunculopontine tegmental (PPT) nuclei have been shown to principally innervate the thalamus. In order to determine whether some of these neurons might simultaneously project to two thalamic targets we made microinjections of rhodamine-conjugated microbeads into the central-lateral nucleus of the thalamus and fluorescein isothiocyanate (FITC)-conjugated microbeads into the dorso-lateral geniculate nucleus. We then determined whether both tracers were found in immunohistochemically identified cholinergic somata in the LDT and PPT nuclei. Results showed that some cholinergic and non-cholinergic neurons in the LDT and PPT nuclei projected to both thalamic sites. This finding extends our understanding of the projections of the LDT-PPT cholinergic neurons and further supports the role of these neurons in complex behaviors.

Inhibition by carbachol microinjections of presumptive cholinergic PGO-on neurons in freely moving cats

The effects of microinjections of a cholinergic agonist, carbachol (0.2 micrograms/0.2 microliters), were examined on a population of presumptive cholinergic mesopontine PGO-on neurons that presents a tonic pattern of discharge during waking and exhibits short spike bursts preceding the onset of dorsal lateral geniculate PGO waves during paradoxical sleep and slow wave sleep just prior to it. PGO-on neurons were activated antidromically by the stimulation of the dorsal lateral geniculate, pulvinar and/or medial and intralaminar thalamic nuclei. They were all characterized by a long spike duration and a slow conduction velocity. Microinjections of carbachol near unit recording sites in freely moving cats induced a complete suppression of the spontaneous tonic activity during waking, but did not suppress the spontaneous phasic burst activity during sleep. Carbachol microinjections also resulted in a marked reduction in responsiveness of PGO-on neurons to orthodromic stimulation. These spike depressant effects lasted for approximately 90-120 min and were reversed completely by a local or systemic administration of atropine sulfate. These findings point to a direct inhibition of central cholinergic PGO-on neurons via a muscarinic autoreceptor and a difference in the mechanisms underlying the generation of tonic and phasic burst activity of PGO-on neurons occurring during waking and sleep.

Brainstem genesis of reserpine-induced ponto-geniculo-occipital waves: an electrophysiological and morphological investigation

Several experimental results indicate that the peribrachial (PB) cholinergic area of the pedunculopontine nucleus is the final relay for the transfer of brainstem-generated pontogeniculo-occipital (PGO) waves to the thalamus. However, the mechanisms underlying the PGO-related activity of PB neurons remain unknown. In order to study these mechanisms, single unit recordings in the PB area were performed in reserpinized cats. Because PGO waves are closely related to rapid eye movements, our microelectrode explorations were also aimed to some structures of the preoculomotor network, namely, the superior colliculus (SC) and parts of the central tegmental field (FTC). We have found several classes of PGO-on cells in the PB area, most of them descharging 80 ms or less before the peak of PGO waves. These cell-classes comprised high-frequency bursting cells, slow-frequency bursting cells, and neurons discharging single spikes or doublets. Intracellular recordings showed that PGO-on single spikes arise from conventional excitatory postsynaptic potentials. Among PGO-related cells in structures outside the PB limits, it was found that most SC cells discharge during or after the PGO, whereas FTC cells increase their discharge rate several hundreds of ms before PGO waves, thus indicating that PGO waves are elaborated long before the activation of PB neurons. Massive retrograde labeling was found in FTC following horseradish peroxidase injections into the PB area. We suggest that long-lead FTC neurons provide an excitatory input to PGO-on PB neurons.

Microinjections of nicotine in the medial pontine reticular formation elicits REM sleep

Microinfusion of non-specific cholinergic muscarinic-nicotinic agonists, such as carbachol, into the medial pontine reticular formation readily elicits REM sleep. It has generally been assumed that muscarinic receptors mediate the action of cholinergic agonists in triggering rapid eye movement (REM) sleep. Very little is known, however, about the role of nicotinic mechanisms in REM sleep generation. In this study, we administered nicotine and Ringer's solution into the medial pontine reticular formation of freely moving cats. Compared to control Ringer's injections, nicotine increased REM sleep and decreased wake and slow wave sleep (SWS) I percentage. Nicotine also shortened the time to REM sleep onset. These findings suggest a role of nicotinic mechanisms in REM sleep generation.

6-Hydroxydopamine treatment blocks the effects of chronic monocular paralysis in the cat's lateral geniculate nucleus

The abnormal patterns of binocular stimulation produced by unilateral eye immobilization (monocular paralysis) alter the physiology of the lateral geniculate nucleus (LGN), shifting the LGN X/Y ratio in such a way that X cells are encountered far less frequently than Y cells. These changes are not observed in cats treated with intraventricular injections of the neurotoxin, 6-hydroxydopamine (6-OHDA) during the period of chronic monocular paralysis. Additional experiments indicated that the blockade was not due to any non-specific effects associated with the injection procedures, nor to any direct effects the drug itself may have had on LGN cell recording. These results suggest that the neuronal mechanism mediating the shift in the X/Y ratio produced by monocular paralysis contains elements that are sensitive to 6-OHDA.

The cellular mechanism of thalamic ponto-geniculo-occipital waves

The cellular mechanisms underlying the genesis of thalamic ponto-geniculo-occipital waves were studied in reserpinized cats under urethane anaesthesia. Simultaneous field potential and intracellular recordings were performed in the lateral geniculate nucleus after acute lesions of retinal and visual cortical inputs. In most relay cells, reserpine-induced ponto-geniculo-occipital waves were associated with a transient depolarization that was often interrupted by a unitary inhibitory postsynaptic potential. The depolarization grew in size with membrane hyperpolarization and was accompanied by an increase in membrane conductance. The inhibitory postsynaptic potential is likely to have resulted from the activation of intrageniculate interneurons since perigeniculate cells were always inhibited during the occurrence of ponto-geniculo-occipital waves. Under reserpine, thalamic ponto-geniculo-occipital waves could also be triggered by peribrachial or auditory stimulation. These evoked ponto-geniculo-occipital waves were associated with intracellular events identical to those occurring spontaneously after reserpine administration. In addition, thalamic spindle oscillations were readily blocked by the occurrence of spontaneous or evoked ponto-geniculo-occipital waves. On the basis of the present results and those already published in the literature, the conclusion is reached that lateral geniculate ponto-geniculo-occipital waves result from a nicotinic activation of relay cells and from a parallel muscarinic inhibition of perigeniculate cells by peribrachial afferents. The functional significance of the ponto-geniculo-occipital activity is discussed on the basis of the antagonistic action of these signals on thalamic oscillations. It is proposed that these signals are the central correlates of orienting reactions elicited by sensory stimuli during waking (the so-called eye movement potentials) and by internally generated drives during paradoxical sleep.

The effects of brainstem peribrachial stimulation on neurons of the lateral geniculate nucleus

The intracellular effects of brainstem peribrachial stimulation on lateral geniculate neurons were investigated in the cat. Experiments were performed in cats under barbiturate or urethane anaesthesia and in non-anaesthetized deafferented animals. Most animals were pretreated with reserpine and were acutely deprived of their retinal and visual cortical inputs. Short trains of stimuli triggered a transient depolarization in most relay neurons (latency: 20-30 ms; duration: 200-300 ms). This depolarization could be interrupted by a short-duration unitary inhibitory postsynaptic potential. The depolarization increased with membrane hyperpolarization and was associated with an increase in membrane conductance. The inhibitory postsynaptic potential had an intrathalamic origin and likely resulted from parallel activation of intrageniculate interneurons. The above responses were largely enhanced in reserpinized cats and were completely abolished by small doses of barbiturates. Iontophoretic applications of the nicotinic blocker, hexamethonium, eliminated peribrachial-evoked discharges in these cells, while similar applications of the muscarinic antagonist, scopolamine, were devoid of any effect. The conclusion is reached that the depolarization of lateral geniculate relay neurons by peribrachial afferents represents a direct postsynaptic effect and does not result from a global disinhibitory mechanism involving inhibition of perigeniculate cells and intrageniculate interneurons. This peribrachial-evoked transient excitation of relay neurons results from a nicotinic mechanism.