Circadian desynchronization of core body temperature and sleep stages in the rat

Cambras, Trinitat; Weller, John R.; Anglès-Pujoràs, Montserrat; Lee, Michael L.; Christopher, Andrea S.; Dı́ez-Noguera, Antoni; Krueger, James M.; Iglesia, Horacio O. de la

doi:10.1073/pnas.0702424104

Cited by 98 publications

(108 citation statements)

References 30 publications

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“…In support of this view, we have previously shown that desynchrony of sleep stages in the forced desynchronized rat emerges from the desynchrony of specific neuronal subpopulations within the SCN. 8,9 Our current findings indicate that the local circadian misalignment of neurons within the SCN circuitry, through the desynchrony of sleep stages, may impair higher cognitive functions such as long-term hippocampus memory consolidation.…”

Section: Discussionmentioning

confidence: 99%

“…Analysis of ECoG sleep recordings in these animals reveals that whereas NREM sleep is temporally organized according to both periodicities, REMS only exhibits a ~25-h rhythm. 8,9 The different rhythmicity of each sleep stage leads to a cycle that alternates between days in which sleep architecture (the temporal distribution of NREM and REM sleep) is similar to that of LD24 rats (aligned days, Figure 2C and 2D), and days in which wakefulness does not occur primarily during the dark phase and REM predominates in the dark phase (misaligned days, Figure 2E and 2F).…”

Section: Forced Desynchronized Rats Show Abnormal Timing Of Rem and Nmentioning

confidence: 99%

“…However, forced desynchronized rats show desynchrony in other circadian rhythms that could be responsible for memory deficits. 5,9,15,16 To determine whether memory deficits in LD22 misaligned animals are associated specifically with our observed fragmentation of NREM and REM sleep, we repeated our contextual fear conditioning experiments in all three experimental groups while simultaneously recording the vigilance states with ECoG electrodes after training for each animal. We plotted a survival curve and fitted an exponential decay curve for each animal and sleep stage during the light phase one day after training.…”

Section: Nrem and Rem Sleep Fragmentation But Not Total Sleep Fragmementioning

confidence: 99%

“…[8][9][10] We tested whether this abnormal timing of sleep stages leads to deficits in total sleep or in specific sleep stages. We calculated the percent of sleep throughout: (1) a 24-h period in LD24-housed animals, (2) a 22-h period in LD22-housed animals during aligned phases, or (3) a 22-h period in LD22-housed animals during misaligned phases.…”

Section: Forced Desynchronized Rats Show No Deficits In Total Sleep mentioning

confidence: 99%

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Fragmentation of Rapid Eye Movement and Nonrapid Eye Movement Sleep without Total Sleep Loss Impairs Hippocampus-Dependent Fear Memory Consolidation

Lee

Katsuyama

Duge

et al. 2016

Sleep

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Study Objectives: Sleep is important for consolidation of hippocampus-dependent memories. It is hypothesized that the temporal sequence of nonrapid eye movement (NREM) sleep and rapid eye movement (REM) sleep is critical for the weakening of nonadaptive memories and the subsequent transfer of memories temporarily stored in the hippocampus to more permanent memories in the neocortex. A great body of evidence supporting this hypothesis relies on behavioral, pharmacological, neural, and/or genetic manipulations that induce sleep deprivation or stage-specific sleep deprivation. Methods:We exploit an experimental model of circadian desynchrony in which intact animals are not deprived of any sleep stage but show fragmentation of REM and NREM sleep within nonfragmented sleep bouts. We test the hypothesis that the shortening of NREM and REM sleep durations post-training will impair memory consolidation irrespective of total sleep duration. Results: When circadian-desynchronized animals are trained in a hippocampus-dependent contextual fear-conditioning task they show normal short-term memory but impaired long-term memory consolidation. This impairment in memory consolidation is positively associated with the post-training fragmentation of REM and NREM sleep but is not significantly associated with the fragmentation of total sleep or the total amount of delta activity. We also show that the sleep stage fragmentation resulting from circadian desynchrony has no effect on hippocampus-dependent spatial memory and no effect on hippocampusindependent cued fear-conditioning memory. Conclusions: Our findings in an intact animal model, in which sleep deprivation is not a confounding factor, support the hypothesis that the stereotypic sequence and duration of sleep stages play a specific role in long-term hippocampus-dependent fear memory consolidation.

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Section: Discussionmentioning

confidence: 99%

Section: Forced Desynchronized Rats Show Abnormal Timing Of Rem and Nmentioning

confidence: 99%

Section: Nrem and Rem Sleep Fragmentation But Not Total Sleep Fragmementioning

confidence: 99%

Section: Forced Desynchronized Rats Show No Deficits In Total Sleep mentioning

confidence: 99%

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Fragmentation of Rapid Eye Movement and Nonrapid Eye Movement Sleep without Total Sleep Loss Impairs Hippocampus-Dependent Fear Memory Consolidation

Lee

Katsuyama

Duge

et al. 2016

Sleep

Self Cite

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“…Several lines of evidence point toward the existence of multiple distinct oscillators in cells and/or tissues of organisms contributing to circadian timing. First, there exist free-running rhythms with different period lengths in the same organism (Morse et al 1994;Sai and Johnson 1999;Cambras et al 2007), and there is residual rhythmicity in strains that are defective in known oscillator components (Loros et al 1986;Stanewsky et al 1998;Emery et al 2000;Collins et al 2005). Second, some tissue-specific oscillators are constructed differently from the core oscillators located in the brain (Stanewsky et al 1998;Ivanchenko et al 2001;Krishnan et al 2001;Hardin et al 2003;Collins et al 2005).…”

Section: Introductionmentioning

confidence: 99%

Complexity of theNeurospora crassaCircadian Clock System: Multiple Loops and Oscillators

Paula

Vitalini²,

Gomer³

et al. 2007

Cold Spring Harbor Symposia on Quantitative Biology

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Organisms from bacteria to humans use a circadian clock to control daily biochemical, physiological, and behavioral rhythms. We review evidence from Neurospora crassa that suggests that the circadian clock is organized as a network of genes and proteins that form coupled evening-and morning-specific oscillatory loops that can function automously, respond differently to environmental inputs, and regulate phase-specific outputs. There is also evidence for coupled morning and evening oscillator loops in plants, insects, and mammals, suggesting conservation of clock organization. From a systems perspective, fungi provide a powerful model organism for investigating oscillator complexity, communication between oscillators, and addressing reasons why the system has evolved to be so complex.

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Experimental assessment of the network properties of the Drosophila circadian clock

Beckwith

Ceriani

2015

J of Comparative Neurology

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Circadian rhythms are conserved across kingdoms and coordinate physiology and behavior for appropriate time-keeping. The neuronal populations that govern circadian rhythms are described in many animal models, and the current challenge is to understand how they interact to control overt rhythms, remaining plastic enough to respond and adapt to a changing environment. In Drosophila melanogaster, the circadian network comprises about 150 neurons, and the main synchronizer is the neuropeptide pigment-dispersing factor (PDF), released by the well-characterized central pacemaker neurons, the small ventral lateral neurons (sLNvs). However, the rules and properties governing the communication and coupling between this central pacemaker and downstream clusters are not fully elucidated. Here we genetically manipulate the speed of the molecular clock specifically in the central pacemaker neurons of Drosophila and provide experimental evidence of their restricted ability to synchronize downstream clusters. We also demonstrate that the sLNv-controlled clusters have an asymmetric entrainment range and were able to experimentally assess it. Our data imply that different clusters are subjected to different coupling strengths, and display independent endogenous periods. Finally, the manipulation employed here establishes a suitable paradigm to test other network properties as well as the cell-autonomous mechanisms running in different circadian-relevant clusters.

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Circadian desynchronization of core body temperature and sleep stages in the rat

Cited by 98 publications

References 30 publications

Fragmentation of Rapid Eye Movement and Nonrapid Eye Movement Sleep without Total Sleep Loss Impairs Hippocampus-Dependent Fear Memory Consolidation

Fragmentation of Rapid Eye Movement and Nonrapid Eye Movement Sleep without Total Sleep Loss Impairs Hippocampus-Dependent Fear Memory Consolidation

Complexity of theNeurospora crassaCircadian Clock System: Multiple Loops and Oscillators

Experimental assessment of the network properties of the Drosophila circadian clock

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