Cataplexy is the pathognomonic symptom of narcolepsy, and is the sudden uncontrollable onset of skeletal muscle paralysis or weakness during wakefulness. Cataplexy is incapacitating because it leaves the individual awake but temporarily either fully or partially paralyzed. Occurring spontaneously, cataplexy is typically triggered by strong positive emotions such as laughter and is often underdiagnosed owing to a variable disease course in terms of age of onset, presenting symptoms, triggers, frequency and intensity of attacks. This disorder occurs almost exclusively in patients with depletion of hypothalamic orexin neurons. One pathogenetic mechanism that has been hypothesized for cataplexy is the activation, during wakefulness, of brainstem circuitry that normally induces muscle tone suppression in rapid eye movement sleep. Muscle weakness during cataplexy is caused by decreased excitation of noradrenergic neurons and increased inhibition of skeletal motor neurons by γ-aminobutyric acid-releasing or glycinergic neurons. The amygdala and medial prefrontal cortex contain neural pathways through which positive emotions probably trigger cataplectic attacks. Despite major advances in understanding disease mechanisms in cataplexy, therapeutic management is largely symptomatic, with antidepressants and γ-hydroxybutyrate being the most effective treatments. This Review describes the clinical and pathophysiological aspects of cataplexy, and outlines optimal therapeutic management strategies.
Rapid eye movement (REM) sleep is generated and maintained by the interaction of a variety of neurotransmitter systems in the brainstem, forebrain, and hypothalamus. Within these circuits lies a core region that is active during REM sleep, known as the subcoeruleus nucleus (SubC) or sublaterodorsal nucleus. It is hypothesized that glutamatergic SubC neurons regulate REM sleep and its defining features such as muscle paralysis and cortical activation. REM sleep paralysis is initiated when glutamatergic SubC cells activate neurons in the ventral medial medulla, which causes release of GABA and glycine onto skeletal motoneurons. REM sleep timing is controlled by activity of GABAergic neurons in the ventrolateral periaqueductal gray and dorsal paragigantocellular reticular nucleus as well as melanin-concentrating hormone neurons in the hypothalamus and cholinergic cells in the laterodorsal and pedunculo-pontine tegmentum in the brainstem. Determining how these circuits interact with the SubC is important because breakdown in their communication is hypothesized to underlie narcolepsy/cataplexy and REM sleep behavior disorder (RBD). This review synthesizes our current understanding of mechanisms generating healthy REM sleep and how dysfunction of these circuits contributes to common REM sleep disorders such as cataplexy/narcolepsy and RBD.
Reduced tongue muscle tone precipitates obstructive sleep apnea (OSA), and activation of the tongue musculature can lessen OSA. The hypoglossal motor nucleus (HMN) innervates the tongue muscles but there is no pharmacological agent currently able to selectively manipulate a channel (e.g., Kir2.4) that is highly restricted in its expression to cranial motor pools such as the HMN. To model the effect of manipulating such a restricted target, we introduced a “designer” receptor into the HMN and selectively modulated it with a “designer” drug. We used cre-dependent viral vectors (AAV8-hSyn-DIO-hM3Dq-mCherry) to transduce hypoglossal motoneurons of ChAT-Cre+ mice with hM3Dq (activating) receptors. We measured sleep and breathing in three conditions: (i) sham, (ii) after systemic administration of clozapine-N-oxide (CNO; 1 mg/kg) or (iii) vehicle. CNO activates hM3Dq receptors but is otherwise biologically inert. Systemic administration of CNO caused significant and sustained increases in tongue muscle activity in non-REM (261 ± 33% for 10 hrs) and REM sleep (217 ± 21% for 8 hrs), both P < 0.01 versus controls. Responses were specific and selective for the tongue with no effects on diaphragm or postural muscle activities, or sleep-wake states. These results support targeting a selective and restricted “druggable” target at the HMN (e.g., Kir2.4) to activate tongue motor activity during sleep.
Highlights d Muscle tone and arousal state are decoupled by manipulation of the SLD d SLD activation promotes cataplexy, whereas SLD silencing prevents cataplexy d SLD activation triggers cataplexy in wild-type mice d The SLD couples arousal state and motor activity during REM sleep and wakefulness
REM sleep, also known as dreaming sleep, is marked by intense cortical activation and absence of skeletal muscle tone, so-called REM sleep paralysis (atonia). It is commonly believed that REM sleep paralysis functions to prevent movement during vivid dreams. Indeed, REM sleep behaviour disorder -a neurological condition marked by violent dream enactment -results from loss of REM sleep paralysis. For the last 50 years, biologists have focused on the identification of brain mechanisms responsible for REM sleep. A majority of evidence suggests that a brainstem region known as the sublaterodorsal nucleus (SLD), also called the subcoeruleus, is important for REM sleep generation (Jouvet 1962). However, there is uncertainty concerning the chemical mechanisms by which the SLD triggers REM sleep phenomena. For example, some data suggest that cholinergic modulation of SLD cells underlies REM sleep generation, whereas, other data suggest that GABAergic disinhibition and glutamatergic excitation of SLD cells are critical for REM sleep control (Boissard et al. 2002;Lu et al. 2006). The recent study by Weng et al. (2014) provides a potentially new framework for understanding REM sleep control by showing that both cholinergic and glutamatergic processes operating within the SLD could be important for triggering REM sleep paralysis. The SLD contains cells that are crucial for generating REM sleep paralysis. Pharmacological and electrical activation of SLD neurons produces a REM-like Z.A. Torontali and K.P. Grace contributed equally to this manuscript sleep state that is characterized by muscle paralysis and cortical activation. In contrast, SLD lesions produce REM sleep without atonia in animals, and neurodegeneration of the SLD region is associated with REM sleep behaviour disorder in humans. REM sleep-active SLD neurons are glutamatergic and are thought to induce REM paralysis by activating GABA and glycine-containing neurons in the ventromedial medulla and spinal cord, which in turn trigger motor atonia by inhibiting skeletal motoneurons (Boissard et al. 2002). During REM sleep, acetylcholine is thought to participate in the activation of these descending atonia pathways. For example, application of cholinergic agonists into the SLD can induce long-lasting periods of cortical activation and muscle paralysis (Steriade & McCarley, 2005). Nevertheless, not all experimental interventions produce this same effect. In fact, cholinergic stimulation of the SLD can also induce prolonged bouts of wakefulness (George et al. 1964). Taking these contradictions to heart, Weng and co-workers set out to understand better how cholinergic mechanisms regulate REM sleep paralysis at the level of the SLD.Because the SLD contains a heterogeneous pool of neurons that mediate a range of behaviours, Weng and co-workers developed a new approach for studying how cholinergic mechanisms affect the function of spinally projecting SLD neurons specifically. They did this by retrogradely labelling SLD neurons from the spinal cord and then used in vitro ele...
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