Modulation of GABAA receptor desensitization uncouples sleep onset and maintenance in Drosophila

Sleep in Drosophila shares many features with mammalian sleep, but it remains unknown whether spontaneous and evoked activity of individual neurons change with the sleep/wake cycle in flies as they do in mammals. Here we used calcium imaging to assess how the Kenyon cells in the fly mushroom bodies change their activity and reactivity to stimuli during sleep, wake, and after short or long sleep deprivation. As before, sleep was defined as a period of immobility of >5 min associated with a reduced behavioral response to a stimulus. We found that calcium levels in Kenyon cells decline when flies fall asleep and increase when they wake up. Moreover, calcium transients in response to two different stimuli are larger in awake flies than in sleeping flies. The activity of Kenyon cells is also affected by sleep/wake history: in awake flies, more cells are spontaneously active and responding to stimuli if the last several hours (5-8 h) before imaging were spent awake rather than asleep. By contrast, long wake (≥29 h) reduces both baseline and evoked neural activity and decreases the ability of neurons to respond consistently to the same repeated stimulus. The latter finding may underlie some of the negative effects of sleep deprivation on cognitive performance and is consistent with the occurrence of local sleep during wake as described in behaving rats. Thus, calcium imaging uncovers new similarities between fly and mammalian sleep: fly neurons are more active and reactive in wake than in sleep, and their activity tracks sleep/wake history.T he fundamental features that characterize mammalian sleep also define Drosophila melanogaster sleep (1-3). Most crucially, in both flies and mammals, sleep is distinguished from simple rest (quiet wake) by an increased arousal threshold, i.e., a reduced ability to respond to external stimuli. Moreover, in flies and mammals sleep is controlled homeostatically by the duration as well by the intensity of prior wake, suggesting basic similarities in the mechanisms of sleep regulation across species. Thus, in flies both sleep deprivation and a rich learning experience lead to a sleep rebound characterized by overall increased sleep time, increased arousal threshold, and longer sleep episodes (4-6). As in mammals, overall neuronal activity in flies is also high during wake and low during sleep (6-8). Specifically, a seminal study using local field potential (LFP) recordings from the Drosophila medial protocerebrum found high spike-like potentials that disappeared after the block of synaptic transmission in the mushroom bodies (MBs) (7). This high spike activity was present when flies were moving or had been quiescent for only a few seconds, but disappeared with sleep (i.e., after periods of immobility >5 min), when the overall LFP power in all frequencies also decreased by ∼60% (7). The study concluded that neural activity in the sleeping fly brain, or at least in a central region spanning the MBs, resembles that seen in mammals in several brainstem cell groups including noradrenergic ne...

Section: Discussionmentioning

confidence: 99%

Sleep- and wake-dependent changes in neuronal activity and reactivity demonstrated in fly neurons using in vivo calcium imaging

Bushey

Tononi

Cirelli

2015

“…For sleep analysis, data from days 6 -8 were collected by using 1-min bin. The sleep-like resting state is defined as no movement for 5 min (32)(33)(34). Total sleep measures the amount of sleep per 24 h, whereas maximum sleep measures the duration of the longest sleep episode in each genotype.…”

Section: Methodsmentioning

confidence: 99%

Light-arousal and circadian photoreception circuits intersect at the large PDF cells of the Drosophila brain

Shang

Griffith

Rosbash

2008

Self Cite

277

278

The neural circuits that regulate sleep and arousal as well as their integration with circadian circuits remain unclear, especially in Drosophila. This issue intersects with that of photoreception, because light is both an arousal signal in diurnal animals and an entraining signal for the circadian clock. To identify neurons and circuits relevant to light-mediated arousal as well as circadian phase-shifting, we developed genetic techniques that link behavior to single cell-type resolution within the Drosophila central brain. We focused on the unknown function of the 10 PDFcontaining large ventral lateral neurons (l-LNvs) of the Drosophila circadian brain network and show here that these cells function in light-dependent arousal. They also are important for phase shifting in the late-night (dawn), indicating that the circadian photoresponse is a network property and therefore non-cell-autonomous. The data further indicate that the circuits underlying light-induced arousal and circadian photoentrainment intersect at the l-LNvs and then segregate.L ight promotes arousal in diurnal species. Drosophila arousalsleep circuits remain largely uncharacterized. Exceptions are the mushroom body with a role in sleep-arousal (1, 2) as well as neurons of the pars intercerebralis (PI) and the ellipsoid body (EB) of the central complex (CC) with roles in locomotion (3, 4). Importantly, there is no indication of how the poorly understood fly sleep-movement circuits are coordinated or communicate with the well-studied brain circadian network, or whether these Ϸ150 circadian neurons impact directly on sleep or arousal.

“…Although dDA1 is strongly expressed in MBs, where most genes affecting baseline sleep in Drosophila are expressed (26)(27)(28)(29)(30)(31), the average amount of sleep and activity during waking were indistinguishable between WT and dumb 1 flies (Fig. S4 A and B), in contrast to fmn flies, which have lowered baseline amounts of sleep and increased locomotor activity during waking (ref.…”

Section: Meth-induced Wakefulness Does Not Involve Modulation Of Dda1mentioning

confidence: 99%

Drosophila D1 dopamine receptor mediates caffeine-induced arousal

Andretic

Kim

Jones

et al. 2008

The arousing and motor-activating effects of psychostimulants are mediated by multiple systems. In Drosophila, dopaminergic transmission is involved in mediating the arousing effects of methamphetamine, although the neuronal mechanisms of caffeine (CAFF)-induced wakefulness remain unexplored. Here, we show that in Drosophila, as in mammals, the wake-promoting effect of CAFF involves both the adenosinergic and dopaminergic systems. By measuring behavioral responses in mutant and transgenic flies exposed to different drug-feeding regimens, we show that CAFFinduced wakefulness requires the Drosophila D1 dopamine receptor (dDA1) in the mushroom bodies. In WT flies, CAFF exposure leads to downregulation of dDA1 expression, whereas the transgenic overexpression of dDA1 leads to CAFF resistance. The wakepromoting effects of methamphetamine require a functional dopamine transporter as well as the dDA1, and they engage brain areas in addition to the mushroom bodies.ptimal behavioral performance in humans and animals depends on an adequate arousal level, which often involves diffuse afferent inputs from the dopaminergic system. Caffeine (CAFF) displays strong arousing properties and is the most consumed psychoactive drug in the world. CAFF competitively inhibits adenosine A1 and A2 receptors, antagonizing the effects of the sleep-promoting neuromodulator adenosine that accumulates during waking (1). CAFF also leads to increased dopaminergic and glutamatergic transmission in different striatal subcompartments, which has been linked to its activating and reinforcing effects (2-4).Although CAFF-induced wakefulness has been related to modulation of cholinergic and histaminergic arousal systems (5, 6), CAFF's induction of increased dopaminergic transmission and its effect on wakefulness have not been adequately examined. Animals with increased dopaminergic transmission, such as dopamine transporter (DAT) mutant mice, have decreased non-rapid eye movement sleep and increased sensitivity to the wake-promoting action of CAFF (7). Dopaminergic action on both the D1 and D2 receptors contributes to the alert waking state, based on the action of centrally administered D1 and D2 agonists in rodents (8). Molecularly, CAFF modulates D2 transcription in vitro and in vivo (9). Motor-activating effects of CAFF are diminished in D2R mutant mice (10, 11); however, the role of D2R in the arousing effect of CAFF remains unknown, and functional tests of the brain regions mediating these effects are lacking in mammals.We have shown previously that the wake-promoting effects of methamphetamine (METH) in Drosophila are mediated through dopaminergic transmission, indicating some evolutionary conservation in the behavioral and neurochemical effects of psychostimulants (12).Treatment of flies with CAFF induces wakefulness; however, the mechanism underlying this activity is currently unknown (13,14). In the present study, we investigate the role of dopamine signaling in the wake-inducing properties of CAFF and METH, with emphasis on the role of the Dr...