Neuronal ensembles sufficient for recovery sleep and the sedative actions of α2 adrenergic agonists

Zhang, Zhe; Ferretti, Valentina; Güntan, İlke; Moro, Alessandro; Steinberg, Eleonora A; Z, Ye; Zecharia, Anna; Yu, Xiao; Vyssotski, Alexei L.; Brickley, Stephen G.; Yustos, Raquel; Pillidge, Zoe E; Harding, Edward C.; Wisden, William; Franks, Nicholas P.

doi:10.1038/nn.3957

Cited by 228 publications

(325 citation statements)

References 48 publications

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“…We have previously suggested that sedatives produce sleep by interacting with the NREM sleep-inducing circuitry, changing activity in the hypothalamic and brainstem circuits that globally govern arousal (Nelson et al, 2002;Lu et al, 2008;Zhang et al, 2015). We show here that this seems to be the case for zolpidem, too.…”

Section: Discussionsupporting

confidence: 68%

“…Natural NREM sleep is hypothesized to start when GABA neurons in the preoptic hypothalamus increase their activity onto, among other targets, the wake-promoting histaminergic neurons in the tuberomammillary nucleus (TMN) of the posterior hypothalamus (Nitz and Siegel, 1996;Sherin et al, 1996Sherin et al, , 1998Zhang et al, 2015). Infusing the GABA A agonist muscimol into this area induces sleep (Lin et al, 1989;Nitz and Siegel, 1996); conversely, injecting GABA A receptor antagonists there decreases the potency of GABAergic anesthetics (Nelson et al, 2002).…”

Section: Introductionmentioning

confidence: 99%

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Bottom-Up versus Top-Down Induction of Sleep by Zolpidem Acting on Histaminergic and Neocortex Neurons

Uygun¹,

Z²,

Zecharia³

et al. 2016

J. Neurosci.

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Zolpidem, a GABA A receptor-positive modulator, is the gold-standard drug for treating insomnia. Zolpidem prolongs IPSCs to decrease sleep latency and increase sleep time, effects that depend on ␣2 and/or ␣3 subunit-containing receptors. Compared with natural NREM sleep, zolpidem also decreases the EEG power, an effect that depends on ␣1 subunit-containing receptors, and which may make zolpideminduced sleep less optimal. In this paper, we investigate whether zolpidem needs to potentiate only particular GABAergic pathways to induce sleep without reducing EEG power. Mice with a knock-in F77I mutation in the GABA A receptor ␥2 subunit gene are zolpideminsensitive. Using these mice, GABA A receptors in the frontal motor neocortex and hypothalamic (tuberomammillary nucleus) histaminergic-neurons of ␥2I77 mice were made selectively sensitive to zolpidem by genetically swapping the ␥2I77 subunits with ␥2F77 subunits. When histamine neurons were made selectively zolpidem-sensitive, systemic administration of zolpidem shortened sleep latency and increased sleep time. But in contrast to the effect of zolpidem on wild-type mice, the power in the EEG spectra of NREM sleep was not decreased, suggesting that these EEG power-reducing effects of zolpidem do not depend on reduced histamine release. Selective potentiation of GABA A receptors in the frontal cortex by systemic zolpidem administration also reduced sleep latency, but less so than for histamine neurons. These results could help with the design of new sedatives that induce a more natural sleep.

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Section: Discussionsupporting

confidence: 68%

Section: Introductionmentioning

confidence: 99%

Bottom-Up versus Top-Down Induction of Sleep by Zolpidem Acting on Histaminergic and Neocortex Neurons

Uygun¹,

Z²,

Zecharia³

et al. 2016

J. Neurosci.

Self Cite

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“…9 In another study in vivo, acute knockdown of α 2A -AR expression in the locus coeruleus failed to affect DEX induced sedation. 46 These findings suggest that α 2A -ARs on non-adrenergic neurons mediate their sedative effects. Furthermore, dopamine-β-hydroxylase knockout mice that have no synaptic norepinephrine release show enhanced sensitivity to and delayed emergence from DEX-induced hypnosis compared to wild-type mice.…”

Section: Discussionmentioning

confidence: 95%

“…45 However, more recent studies have implicated effects of α 2 -AR agonists on non-adrenergic neurons in these actions. 9,46,47 Genetically engineered mice that express α 2A -ARs only in noradrenergic terminals show minimal neurological effects of the α 2 -AR agonist medetomidine, including loss of righting reflex and anesthetic-sparing, in contrast to a strong hypnotic effect in wild-type littermates. 9 In another study in vivo, acute knockdown of α 2A -AR expression in the locus coeruleus failed to affect DEX induced sedation.…”

Section: Discussionmentioning

confidence: 99%

“…45,48 While indirect neurophysiological studies in vivo continue to invoke this mechanism, 49 genetic studies provide strong evidence that non-adrenergic, not noradrenergic, α 2A -ARs mediate the sedative, hypnotic and anesthetic-sparing actions of α 2 -AR agonists. 9,10,46,47 Plausible targets for the hypnotic and anesthetic-sparing effects of α 2 -AR agonists include direct suppression of synaptic transmission in cortico-cortical 3 and thalamo-cortical networks. 48,49 A recent study in vivo using the TetTag-hM 3 D q system to record and reactivate neuronal groups activated by DEX implicates the preoptic hypothalamus and neighboring dorsal structures in DEX-induced sedation.…”

Section: Discussionmentioning

confidence: 99%

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α2-Adrenergic Receptor and Isoflurane Modulation of Presynaptic Ca2+ Influx and Exocytosis in Hippocampal Neurons

2016

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Background Evidence indicates that the anesthetic-sparing effects of α2-adrenergic receptor (AR) agonists involve α2A-AR heteroreceptors on nonadrenergic neurons. Since volatile anesthetics inhibit neurotransmitter release by reducing synaptic vesicle (SV) exocytosis, the authors hypothesized that α2-AR agonists inhibit nonadrenergic SV exocytosis and thereby potentiate presynaptic inhibition of exocytosis by isoflurane. Methods Quantitative imaging of fluorescent biosensors of action potential–evoked SV exocytosis (synaptophysin-pHluorin) and Ca2+ influx (GCaMP6) were used to characterize presynaptic actions of the clinically used α2-AR agonists dexmedetomidine and clonidine, and their interaction with isoflurane, in cultured rat hippocampal neurons. Results Dexmedetomidine (0.1 μM, n = 10) or clonidine (0.5 μM, n = 8) inhibited action potential–evoked exocytosis (54 ± 5% and 59 ± 8% of control, respectively; P < 0.001). Effects on exocytosis were blocked by the subtype-nonselective α2-AR antagonist atipamezole or the α2A-AR–selective antagonist BRL 44408 but not by the α2C-AR–selective antagonist JP 1302. Dexmedetomidine inhibited exocytosis and presynaptic Ca2+ influx without affecting Ca2+ coupling to exocytosis, consistent with an effect upstream of Ca2+–exocytosis coupling. Exocytosis coupled to both N-type and P/Q-type Ca2+ channels was inhibited by dexmedetomidine or clonidine. Dexmedetomidine potentiated inhibition of exocytosis by 0.7 mM isoflurane (to 42 ± 5%, compared to 63 ± 8% for isoflurane alone; P < 0.05). Conclusions Hippocampal SV exocytosis is inhibited by α2A-AR activation in proportion to reduced Ca2+ entry. These effects are additive with those of isoflurane, consistent with a role for α2A-AR presynaptic heteroreceptor inhibition of nonadrenergic synaptic transmission in the anesthetic-sparing effects of α2A-AR agonists.

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Chemogenetics—A Transformational and Translational Platform

English

Roth

2015

JAMA Neurol

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Neuronal ensembles sufficient for recovery sleep and the sedative actions of α2 adrenergic agonists

Cited by 228 publications

References 48 publications

Bottom-Up versus Top-Down Induction of Sleep by Zolpidem Acting on Histaminergic and Neocortex Neurons

Bottom-Up versus Top-Down Induction of Sleep by Zolpidem Acting on Histaminergic and Neocortex Neurons

α2-Adrenergic Receptor and Isoflurane Modulation of Presynaptic Ca2+ Influx and Exocytosis in Hippocampal Neurons

Chemogenetics—A Transformational and Translational Platform

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