Temporal Precision in the Mammalian Circadian System: A Reliable Clock from Less Reliable Neurons

Herzog, Erik D.; Aton, Sara J.; Numano, Rika; Sakaki, Yoshiyuki; Tei, Hajime

doi:10.1177/0748730403260776

Cited by 251 publications

(247 citation statements)

References 52 publications

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“…In particular, the number of cells and the proportions of different cell types affect period and the stability of rhythms [8,19,12,18]. If functionally different cells are produced at different times, as the present results indicate [4], then small changes in the duration or intensity of proliferation of SCN progenitors at different times in development could be one source of variation (both within and between species) in the overall function of the nucleus.…”

Section: Discussionmentioning

confidence: 56%

Development of the mouse suprachiasmatic nucleus: Determination of time of cell origin and spatial arrangements within the nucleus

Kabrita

Davis

2008

Brain Research

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The suprachiasmatic nucleus (SCN) in mammals functions as the principal circadian pacemaker synchronizing diverse physiological and behavioral processes to environmental stimuli. It consists of heterogeneous populations of cells with unique spatial organization that can vary among species, but are commonly discussed within a framework of two principal regions, the ventrolateral or dorsomedial halves of the nucleus or in other instances the core and shell. In both hamsters and rats, cells of different SCN regions have been shown to have different developmental histories. Using bromodeoxyuridine as a marker of cell division, the present study investigated the time of SCN cell origin in mice (C57BL/6) and their settling patterns within the nucleus. Results show that SCN cytogenesis occurs between embryonic days 12 and 15 and is complete 5 days prior to birth. Cells born on embryonic day 12 are mainly confined to a ventrolateral region of the mid-SCN, whereas cells produced later on embryonic days 13.5 and 14.5 form a cap around the cells produced first and extend into the posterior and anterior ends of the nucleus. These results suggest an ordered spatiotemporal program of SCN cytogenesis whereby a mid-SCN core is born first followed by a surrounding shell of later-born cells. Variation in cytogenesis could affect the relative sizes of different SCN regions and, thereby, affect its function. The relative contributions of a highly ordered program of cytogenesis and intercellular interactions after post-mitotic cells leave the germinal epithelium remain to be determined.

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Section: Discussionmentioning

confidence: 56%

Development of the mouse suprachiasmatic nucleus: Determination of time of cell origin and spatial arrangements within the nucleus

Kabrita

Davis

2008

Brain Research

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“…It is a network of multiple autonomous noisy oscillators, which communicate via neuropeptides to synchronize and form a coherent oscillator (Herzog et al 2004;Liu et al 2007). This coherent oscillator then coordinates the timing of daily behaviours, such as the sleep/wake cycle.…”

Section: Modelling Coupled Stochastic Mammalian Neuronsmentioning

confidence: 99%

Synchrony and entrainment properties of robust circadian oscillators

Bagheri

Taylor

Meeker

et al. 2008

J. R. Soc. Interface.

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Systems theoretic tools (i.e. mathematical modelling, control, and feedback design) advance the understanding of robust performance in complex biological networks. We highlight phase entrainment as a key performance measure used to investigate dynamics of a single deterministic circadian oscillator for the purpose of generating insight into the behaviour of a population of (synchronized) oscillators. More specifically, the analysis of phase characteristics may facilitate the identification of appropriate coupling mechanisms for the ensemble of noisy (stochastic) circadian clocks. Phase also serves as a critical control objective to correct mismatch between the biological clock and its environment. Thus, we introduce methods of investigating synchrony and entrainment in both stochastic and deterministic frameworks, and as a property of a single oscillator or population of coupled oscillators.

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“…Although in Welsh et al's preparation a substantial number of neural connections remained, in a tissue explant from the SCN even more are retained. Herzog, Aton, Numano, Sakaki, and Tei (2004) showed that over a seven--day interval the SD of Per1 expression in explants was much less than the SD for the firing rate of dispersed neurons and closely approximated that of the running wheel behavior in the intact mouse. As shown in panels A and B of Figure 6, using a luciferase knock--in under the Per2 gene in SCN slices dispersed SCN neurons, Liu, Welsh, Ko, Tran, Zhang, Priest, Buhr, Singer, Meeker, Verma, Doyle, Takahashi, and Kay (2007) provided a compelling demonstration of the contrast in synchronization obtained between a SCN slice and dispersed neurons.…”

Section: Integrating Intracellular Operations Into An Intercellular Nmentioning

confidence: 87%

Mechanists Must be Holists Too! Perspectives from Circadian Biology

Bechtel

2016

J Hist Biol

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The pursuit of mechanistic explanations in biology has produced a great deal of knowledge about the parts, operations, and organization of mechanisms taken to be responsible for biological phenomena. Holist critics have often raised important criticisms of proposed mechanistic explanations, but until recently holists have not had alternative research strategies through which to advance explanations. This paper argues both that the results of mechanistic strategies has forced mechanists to confront ways in which whole systems affect their components and that new representational and modeling strategies are providing tools for understanding these effects of whole systems upon components. Drawing from research on the mechanism responsible for circadian rhythms in mammals, I develop two examples in which mechanistic analysis is being integrated into a more holist perspective: research revealing intercellular integration of circadian mechanisms with those involved in cell metabolism and research revealing that stable rhythms are dependent on how individual cells in the suprachiasmatic nucleus synchronize with each other to generate regular rhythms. Tools such as network diagramming and computational modeling are providing means to integrate mechanistic models into accounts of whole systems.

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Temporal Precision in the Mammalian Circadian System: A Reliable Clock from Less Reliable Neurons

Cited by 251 publications

References 52 publications

Development of the mouse suprachiasmatic nucleus: Determination of time of cell origin and spatial arrangements within the nucleus

Development of the mouse suprachiasmatic nucleus: Determination of time of cell origin and spatial arrangements within the nucleus

Synchrony and entrainment properties of robust circadian oscillators

Mechanists Must be Holists Too! Perspectives from Circadian Biology

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