Intrinsic Regulation of Spatiotemporal Organization within the Suprachiasmatic Nucleus

Evans, Jennifer; Leise, Tanya; Castanon-Cervantes, Oscar; Davidson, Alec J.

doi:10.1371/journal.pone.0015869

Cited by 99 publications

(154 citation statements)

References 48 publications

(71 reference statements)

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“…In agreement with the results of a previous study [24], composite maps generated using slices collected from all the mice confirm there are pronounced regional phase differences both across and within rostrocaudal SCN slices (figure 5a). As found in previous detailed analyses [24], one of the most salient organizational features is a late-peaking node located within the rostral slice. Additionally, the middle SCN contained early-peaking regions within the dorsal-most and ventral-most regions and the caudal SCN appeared to be the most homogeneous in phase.…”

Section: (Iv) Statistical Analysessupporting

confidence: 91%

“…After imaging, SCN slices were analysed for arginine vasopressin (AVP) and vasoactive intestinal polypeptide (VIP) expression as in [24]. Briefly, slices were treated with colchicine-treated medium (25 mg ml 21 ), fixed with 4% paraformaldehyde, and then cyprotected.…”

Section: Materials and Methods (A) Experimental Procedures (I) Breedinmentioning

confidence: 99%

“…(ii) Criteria for slice inclusion As in [24], consistency in slice position was assessed using a metric based on the bioluminescence profile of each slice (figure 1c). For each slice, bioluminescence was summed over the first cycle in vitro, from which the width/height ratio of the bioluminescence profile was calculated ( figure 1g).…”

Section: Materials and Methods (A) Experimental Procedures (I) Breedinmentioning

confidence: 99%

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Neural correlates of individual differences in circadian behaviour

et al. 2015

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Daily rhythms in mammals are controlled by the circadian system, which is a collection of biological clocks regulated by a central pacemaker within the suprachiasmatic nucleus (SCN) of the anterior hypothalamus. Changes in SCN function have pronounced consequences for behaviour and physiology; however, few studies have examined whether individual differences in circadian behaviour reflect changes in SCN function. Here, PERIOD2::LUCIFERASE mice were exposed to a behavioural assay to characterize individual differences in baseline entrainment, rate of re-entrainment and free-running rhythms. SCN slices were then collected for ex vivo bioluminescence imaging to gain insight into how the properties of the SCN clock influence individual differences in behavioural rhythms. First, individual differences in the timing of locomotor activity rhythms were positively correlated with the timing of SCN rhythms. Second, slower adjustment during simulated jetlag was associated with a larger degree of phase heterogeneity among SCN neurons. Collectively, these findings highlight the role of the SCN network in determining individual differences in circadian behaviour. Furthermore, these results reveal novel ways that the network organization of the SCN influences plasticity at the behavioural level, and lend insight into potential interventions designed to modulate the rate of resynchronization during transmeridian travel and shift work.

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Section: (Iv) Statistical Analysessupporting

confidence: 91%

Section: Materials and Methods (A) Experimental Procedures (I) Breedinmentioning

confidence: 99%

Section: Materials and Methods (A) Experimental Procedures (I) Breedinmentioning

confidence: 99%

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Neural correlates of individual differences in circadian behaviour

et al. 2015

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“…7C, and Tables S3 and S4). patterns of clock gene expression using in situ hybridization and bioluminescence imaging (2,(10)(11)(12)(13)(14). However, the autonomous expression of a clock gene is either absent or undetectable in certain regions, particularly those where neurons receive major light information from the retina (18).…”

Section: Resultsmentioning

confidence: 99%

“…Heterogeneous distribution of the circadian phase in SCN slices was shown by in situ hybridization and bioluminescence studies examining clock gene expression (e.g., Per1 or Per2) (10)(11)(12)(13)(14). Disruption of intercellular coupling by inhibiting neuronal firing with tetrodotoxin (TTX) or mechanical isolation of SCN subregions severely reduced clock gene expression and mutual synchronization (10,11).…”

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confidence: 99%

Topological specificity and hierarchical network of the circadian calcium rhythm in the suprachiasmatic nucleus

Enoki

Kuroda

Ono³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

107

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The circadian pacemaker in the hypothalamic suprachiasmatic nucleus (SCN) is a hierarchical multioscillator system in which neuronal networks play crucial roles in expressing coherent rhythms in physiology and behavior. However, our understanding of the neuronal network is still incomplete. Intracellular calcium mediates the input signals, such as phase-resetting stimuli, to the core molecular loop involving clock genes for circadian rhythm generation and the output signals from the loop to various cellular functions, including changes in neurotransmitter release. Using a unique large-scale calcium imaging method with genetically encoded calcium sensors, we visualized intracellular calcium from the entire surface of SCN slice in culture including the regions where autonomous clock gene expression was undetectable. We found circadian calcium rhythms at a single-cell level in the SCN, which were topologically specific with a larger amplitude and more delayed phase in the ventral region than the dorsal. The robustness of the rhythm was reduced but persisted even after blocking the neuronal firing with tetrodotoxin (TTX). Notably, TTX dissociated the circadian calcium rhythms between the dorsal and ventral SCN. In contrast, a blocker of gap junctions, carbenoxolone, had only a minor effect on the calcium rhythms at both the single-cell and network levels. These results reveal the topological specificity of the circadian calcium rhythm in the SCN and the presence of coupled regional pacemakers in the dorsal and ventral regions. Neuronal firings are not necessary for the persistence of the calcium rhythms but indispensable for the hierarchical organization of rhythmicity in the SCN. yellow cameleon 3.60 | Nipkow-spinning disk confocal | adeno-associated virus | time-lapse imaging | acrophase map

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Coupled network of the circadian clocks: a driving force of rhythmic physiology

2020

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The circadian system is composed of coupled endogenous oscillators that allow living beings, including humans, to anticipate and adapt to daily changes in their environment. In mammals, circadian clocks form a hierarchically organized network with a ‘master clock’ located in the suprachiasmatic nucleus of the hypothalamus, which ensures entrainment of subsidiary oscillators to environmental cycles. Robust rhythmicity of body clocks is indispensable for temporally coordinating organ functions, and the disruption or misalignment of circadian rhythms caused for instance by modern lifestyle is strongly associated with various widespread diseases. This review aims to provide a comprehensive overview of our current knowledge about the molecular architecture and system‐level organization of mammalian circadian oscillators. Furthermore, we discuss the regulatory roles of peripheral clocks for cell and organ physiology and their implication in the temporal coordination of metabolism in human health and disease. Finally, we summarize methods for assessing circadian rhythmicity in humans.

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Intrinsic Regulation of Spatiotemporal Organization within the Suprachiasmatic Nucleus

Cited by 99 publications

References 48 publications

Neural correlates of individual differences in circadian behaviour

Neural correlates of individual differences in circadian behaviour

Topological specificity and hierarchical network of the circadian calcium rhythm in the suprachiasmatic nucleus

Coupled network of the circadian clocks: a driving force of rhythmic physiology

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