Yoshimasa Koyama

Input of Orexin/Hypocretin Neurons Revealed by a Genetically Encoded Tracer in Mice

The finding of orexin/hypocretin deficiency in narcolepsy patients suggests that this hypothalamic neuropeptide plays a crucial role in regulating sleep/wakefulness states. However, very little is known about the synaptic input of orexin/hypocretin-producing neurons (orexin neurons). We applied a transgenic method to map upstream neuronal populations that have synaptic connections to orexin neurons and revealed that orexin neurons receive input from several brain areas. These include the amygdala, basal forebrain cholinergic neurons, GABAergic neurons in the preoptic area, and serotonergic neurons in the median/paramedian raphe nuclei. Monoamine-containing groups that are innervated by orexin neurons do not receive reciprocal connections, while cholinergic neurons in the basal forebrain have reciprocal connections, which might be important for consolidating wakefulness. Electrophysiological study showed that carbachol excites almost one-third of orexin neurons and inhibits a small population of orexin neurons. These neuroanatomical findings provide important insights into the neural pathways that regulate sleep/wakefulness states.

Are there cholinergic and non-cholinergic paradoxical sleep-on neurones in the pons?

Using microiontophoresis on unanesthetized head-restrained cats, we have found two distinct groups of neurones exhibiting tonic discharge specific to paradoxical sleep (PS) (PS-on neurones) in the mesopontine tegmentum, which contains both cholinergic and non-cholinergic neurones. One group is characterized by a broad action potential, slow conduction velocity and an inhibitory response to a potent cholinergic agonist, carbachol, applied iontophoretically during PS. The other is characterized by a short action potential, fast conduction velocity and an excitatory response to applied carbachol. All PS-on neurones were excited by glutamate. The present findings demonstrate the existence of two types of PS-on neurones and suggest their cholinergic and noncholinergic neurochemical properties.

Orexinergic projections to the cat midbrain mediate alternation of emotional behavioural states from locomotion to cataplexy.

Orexinergic neurones in the perifornical lateral hypothalamus project to structures of the midbrain, including the substantia nigra and the mesopontine tegmentum. These areas contain the mesencephalic locomotor region (MLR), and the pedunculopontine and laterodorsal tegmental nuclei (PPN/LDT), which regulate atonia during rapid eye movement (REM) sleep. Deficiencies of the orexinergic system result in narcolepsy, suggesting that these projections are concerned with switching between locomotor movements and muscular atonia. The present study characterizes the role of these orexinergic projections to the midbrain. In decerebrate cats, injecting orexin‐A (60 μm to 1.0 mm, 0.20–0.25 μl) into the MLR reduced the intensity of the electrical stimulation required to induce locomotion on a treadmill (4 cats) or even elicit locomotor movements without electrical stimulation (2 cats). On the other hand, when orexin was injected into either the PPN (8 cats) or the substantia nigra pars reticulata (SNr, 4 cats), an increased stimulus intensity at the PPN was required to induce muscle atonia. The effects of orexin on the PPN and the SNr were reversed by subsequently injecting bicuculline (5 mm, 0.20–0.25 μl), a GABAA receptor antagonist, into the PPN. These findings indicate that excitatory orexinergic drive could maintain a higher level of locomotor activity by increasing the excitability of neurones in the MLR, while enhancing GABAergic effects on presumably cholinergic PPN neurones, to suppress muscle atonia. We conclude that orexinergic projections from the hypothalamus to the midbrain play an important role in regulating motor behaviour and controlling postural muscle tone and locomotor movements when awake and during sleep. Furthermore, as the excitability is attenuated in the absence of orexin, signals to the midbrain may induce locomotor behaviour when the orexinergic system functions normally but elicit atonia or narcolepsy when the orexinergic function is disturbed.

Mutual interactions among cholinergic, noradrenergic and serotonergic neurons studied by ionophoresis of these transmitters in rat brainstem nuclei

In urethane-anesthetized rats, single neuronal activity was recorded in or around the central gray of the caudal mesencephalon to rostral pons with multibarrel microelectrodes for ionophoretic application of acetylcholine, noradrenaline and serotonin. Neurons were classified by spike shape into broad-spike and brief-spike neurons. In the laterodorsal tegmental nucleus, locus coeruleus or dorsal raphe, broad-spike neurons, marked by Pontamine Sky Blue and discriminated in sections processed for histochemistry of reduced nicotinamide adenine dinucleotide phosphate diaphorase or Nissl staining, were presumed to be cholinergic, noradrenergic or serotonergic, respectively. The majority of these neurons were inhibited through autoreceptors, except some laterodorsal tegmental neurons which might not be furnished by autoreceptors. Noradrenaline and serotonin inhibited more than two-thirds of the laterodorsal tegmental neurons tested, while a few neurons were excited by noradrenaline. Though effects of noradrenaline on dorsal raphe neurons and those of serotonin on locus coeruleus neurons were not clear in many neurons tested, neurons affected in these examinations (30%) were all inhibited clearly and no excitatory effect was observed. Acetylcholine exerted inhibition on about one-half of dorsal raphe neurons, while effects of acetylcholine on locus coeruleus neurons were the only case in the present study in which excitation was the major effect, though more than a half of locus coeruleus neurons were not sensitive to this drug. Thus, in this study some new data on the pharmacological properties of the cholinergic laterodorsal tegmental neurons were obtained. In addition, mutual interactions between brainstem cholinergic, noradrenergic and serotonergic neurons were assayed by comparing the pharmacological properties of these neurons tested with a uniform procedure. The interactions between these diffuse projection neurons may be involved in neural mechanisms controlling vigilance, wakefulness and/or sleep.

State-dependent activity of neurons in the perifornical hypothalamic area during sleep and waking

Neurons containing orexins are located in the perifornical hypothalamic area and are considered to have a role in sleep-wake regulation. To examine how this area is involved in the regulation of sleep and wakefulness, we recorded neuronal activity in undrugged, head-restrained rats across sleep-waking cycles. Recordings were made in the perifornical hypothalamic area where orexin-immunoreactive neurons are distributed (PFH), and in the area dorsal to the PFH, including the zona incerta and subincertal nucleus (collectively referred to as ZI). The 40 neurons recorded from in the PFH were divided into five groups: (1) neurons most active during paradoxical sleep (PS, n=14, 35%), (2) neurons active during both waking (W) and PS (n=12, 30%), (3) neurons most active during W (n=7, 18%), (4) neurons most active during slow-wave sleep (SWS, n=3, 7.5%), and (5) neurons whose activity had no correlation with sleep-waking states (n=4, 10%). Of 30 neurons recorded from in the ZI, the corresponding numbers were 13 (43%), seven (23%), six (20%), three (10%), and one (3.3%). In both areas, neuronal activity fluctuated more during PS than during W. Waking-specific neurons (group 3) in the PFH generated action potentials with longer durations than those produced by other types of neurons. About half of the neurons in the PFH that were classified in groups 1, 2, and 3 increased their firing rate after the transition from one state to another, while higher percentages of neurons of groups 1 and 2 in the ZI than those in the PFH increased their firing rate prior to the state shift from SWS to PS. In these ZI neurons, however, the firing rate varied considerably at the state shift. These results suggest that the PFH and ZI are involved in the regulation of PS or W, especially the regulation of phasic events during PS or the maintenance of W. The ZI appears to be more closely involved than the PFH in the induction of PS or some phasic phenomena associated with PS.

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.

Brainstem Neural Mechanisms of Sleep and Wakefulness

The three diffuse projection systems arising in the brainstem, that is, noradrenergic projection originating in the locus coeruleus, serotonergic projection from the dorsal raphe nucleus, and cholinergic projection from neurons gathering in the laterodorsal tegmental nucleus and scattering in the pedunculopontine tegmental nucleus, may function as controllers of sleep and wakefulness. We have investigated the functional roles of these projections by recording neuronal activity in these brainstem nuclei and by stimulating the brainstem nuclei. It is suggested that the projection from the locus coeruleus is an arousal system; the function of the serotonergic projection is still mysterious, since these neurons are active specifically during waking; activation of the noradrenergic projection excites the upper brain sites whereas activation of the serotonergic projection depressed them. It is clear that a group of cholinergic neurons constitute a system to induce and maintain paradoxical sleep. The cholinergic projection may also have the role to induce a rapid, transient elevation of the vigilance level by its phasic response to novel, unfamiliar stimuli.

Control of sleep and wakefulness by brainstem monoaminergic and cholinergic neurons.

Noradrenergic projection originating in the locus coeruleus, serotonergic projection from the dorsal raphe nucleus, and cholinergic projection from neurons gathering in the laterodorsal tegmental nucleus and scattering in the pedunculopontine tegmental nucleus constitute three diffuse projection systems arising from the brainstem and innervating wide areas of the brain. They may function as controllers of sleep and wakefulness. We have investigated functional roles of the projections by recording neuronal activity in these brainstem nuclei, and by observing effects of stimulation of the brainstem nuclei. The projection from the locus coeruleus is an arousal system, since the noradrenergic neurons are active specifically during waking, and activation of the noradrenergic projection excites upper brain structures. Functions of the serotonergic projection are still mysterious, since its action on upper brain is inhibitory in spite of waking-specific activity of the neurons. A group of cholinergic neurons constitute a system to induce and maintain paradoxical sleep. The cholinergic projection may have another role, i.e. to induce a rapid, transient elevation of vigilance level by their phasic response to novel, unfamiliar stimuli.

State-dependent effects of orexins on the serotonergic dorsal raphe neurons in the rat

The serotonergic dorsal raphe (DR) neurons play an important role in sleep-wakefulness regulation. Orexinergic neurons in the lateral hypothalamus densely project to the brainstem sites including the DR. To test the effects of orexins on the serotonergic DR neurons, we applied orexin A (0.1 mM) by pressure to these neurons in unanesthetized and urethane anesthetized rats. Orexin A caused excitation in 10 of 15 neurons under unanesthetized condition. The excitation was characterized by slow onset (0-18 s), long lasting duration (15-150 s) and state-dependency. Orexin A applied during REM sleep or slow wave sleep induced significant excitation while during wakefulness, the similar amount of orexin A did not increase the firing rate any more. In the anesthetized animals, orexin A induced excitation in four of eight neurons. The excitation had slow onset and was long lasting. These results suggest that orexinergic neurons exert excitatory influence on the serotonergic DR neurons to maintain tonic activity of them, thereby participating in regulation of sleep-wakefulness cycles and other functions.

The orexinergic synaptic innervation of serotonin- and orexin 1-receptor-containing neurons in the dorsal raphe nucleus.

Orexin/hypocretin has been well demonstrated to excite the serotonergic neurons in the dorsal raphe nucleus (DRN). We studied the morphological relationships between orexin-containing axon terminals and serotonin- as well as orexin-receptor-containing neurons in the dorsal raphe nucleus. Using immunohistochemical techniques at the light microscopic level, orexin A (OXA)-like immunoreactive neuronal fibers in the DRN were found to make close contact with serotonergic neurons, while some of the serotonergic neurons also expressed the orexin 1 receptor (OX1R). At the electron microscopic level, double-immunostaining experiments showed that the orexin A-like immunoreactive fibers were present mostly as axon terminals that made synapses on the serotonin- and orexin 1-receptor-containing neurons. While only axodendritic synapses between orexin A-containing axon terminals and serotonergic neurons were detected, the synapses made by orexin A-containing axon terminals on the orexin 1-receptor-containing neurons were both axodendritic and axosomatic. The present study suggests that excitation effect of orexin A on dorsal raphe serotonergic neurons is via synaptic communication through orexin 1 receptor.