Suprachiasmatic nucleus: Cellular clocks and networks

Sato Honma; Daisuke Ono; Yohko Suzuki; Natsuko Inagaki; Tomoko Yoshikawa; Wataru Nakamura; Ken Ichi Honma

doi:10.1016/B978-0-444-59427-3.00029-0

Suprachiasmatic nucleus: Cellular clocks and networks

Sato Honma^*, Daisuke Ono, Yohko Suzuki, Natsuko Inagaki, Tomoko Yoshikawa, Wataru Nakamura, Ken Ichi Honma

^*Corresponding author for this work

Exchange Division, Organization for International Education and Exchange

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

43 Scopus citations

Abstract

The suprachiasmatic nucleus (SCN), the master circadian clock of mammals, is composed of multiple circadian oscillator neurons. Most of them exhibit significant circadian rhythms in their clock gene expression and spontaneous firing when cultured in dispersed cells, as well as in an organotypic slice. The distribution of periods depends on the SCN tissue organization, suggesting that cell-to-cell interaction is important for synchronization of the constituent oscillator cells. This cell-to-cell interaction involves both synaptic interactions and humoral mediators. Cellular oscillators form at least three separate but mutually coupled regional pacemakers, and two of them are involved in the photoperiodic regulation of behavioral rhythms in mice. Coupling of cellular oscillators in the SCN tissue compensates for the dysfunction due to clock gene mutations, on the one hand, and desynchronization within and between the regional pacemakers that suppresses the coherent rhythm expression from the SCN, on the other hand. The multioscillator pacemaker structure of the SCN is advantageous for responding to a wide range of environmental challenges without losing coherent rhythm outputs.

Original language	English
Title of host publication	Progress in Brain Research
Publisher	Elsevier B.V.
Pages	129-141
Number of pages	13
DOIs	https://doi.org/10.1016/B978-0-444-59427-3.00029-0
State	Published - 2012

Publication series

Name	Progress in Brain Research
Volume	199
ISSN (Print)	0079-6123
ISSN (Electronic)	1875-7855

Keywords

Bioluminescence imaging
Clock genes
Multi-electrode array
Neural network
Oscillatory coupling
Photoperiods
Suprachiasmatic nucleus

ASJC Scopus subject areas

General Neuroscience

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10.1016/B978-0-444-59427-3.00029-0

Cite this

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title = "Suprachiasmatic nucleus: Cellular clocks and networks",

abstract = "The suprachiasmatic nucleus (SCN), the master circadian clock of mammals, is composed of multiple circadian oscillator neurons. Most of them exhibit significant circadian rhythms in their clock gene expression and spontaneous firing when cultured in dispersed cells, as well as in an organotypic slice. The distribution of periods depends on the SCN tissue organization, suggesting that cell-to-cell interaction is important for synchronization of the constituent oscillator cells. This cell-to-cell interaction involves both synaptic interactions and humoral mediators. Cellular oscillators form at least three separate but mutually coupled regional pacemakers, and two of them are involved in the photoperiodic regulation of behavioral rhythms in mice. Coupling of cellular oscillators in the SCN tissue compensates for the dysfunction due to clock gene mutations, on the one hand, and desynchronization within and between the regional pacemakers that suppresses the coherent rhythm expression from the SCN, on the other hand. The multioscillator pacemaker structure of the SCN is advantageous for responding to a wide range of environmental challenges without losing coherent rhythm outputs.",

keywords = "Bioluminescence imaging, Clock genes, Multi-electrode array, Neural network, Oscillatory coupling, Photoperiods, Suprachiasmatic nucleus",

author = "Sato Honma and Daisuke Ono and Yohko Suzuki and Natsuko Inagaki and Tomoko Yoshikawa and Wataru Nakamura and Honma, {Ken Ichi}",

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AU - Yoshikawa, Tomoko

AU - Nakamura, Wataru

AU - Honma, Ken Ichi

PY - 2012

Y1 - 2012

N2 - The suprachiasmatic nucleus (SCN), the master circadian clock of mammals, is composed of multiple circadian oscillator neurons. Most of them exhibit significant circadian rhythms in their clock gene expression and spontaneous firing when cultured in dispersed cells, as well as in an organotypic slice. The distribution of periods depends on the SCN tissue organization, suggesting that cell-to-cell interaction is important for synchronization of the constituent oscillator cells. This cell-to-cell interaction involves both synaptic interactions and humoral mediators. Cellular oscillators form at least three separate but mutually coupled regional pacemakers, and two of them are involved in the photoperiodic regulation of behavioral rhythms in mice. Coupling of cellular oscillators in the SCN tissue compensates for the dysfunction due to clock gene mutations, on the one hand, and desynchronization within and between the regional pacemakers that suppresses the coherent rhythm expression from the SCN, on the other hand. The multioscillator pacemaker structure of the SCN is advantageous for responding to a wide range of environmental challenges without losing coherent rhythm outputs.

AB - The suprachiasmatic nucleus (SCN), the master circadian clock of mammals, is composed of multiple circadian oscillator neurons. Most of them exhibit significant circadian rhythms in their clock gene expression and spontaneous firing when cultured in dispersed cells, as well as in an organotypic slice. The distribution of periods depends on the SCN tissue organization, suggesting that cell-to-cell interaction is important for synchronization of the constituent oscillator cells. This cell-to-cell interaction involves both synaptic interactions and humoral mediators. Cellular oscillators form at least three separate but mutually coupled regional pacemakers, and two of them are involved in the photoperiodic regulation of behavioral rhythms in mice. Coupling of cellular oscillators in the SCN tissue compensates for the dysfunction due to clock gene mutations, on the one hand, and desynchronization within and between the regional pacemakers that suppresses the coherent rhythm expression from the SCN, on the other hand. The multioscillator pacemaker structure of the SCN is advantageous for responding to a wide range of environmental challenges without losing coherent rhythm outputs.

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KW - Clock genes

KW - Multi-electrode array

KW - Neural network

KW - Oscillatory coupling

KW - Photoperiods

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ER -

Suprachiasmatic nucleus: Cellular clocks and networks

Abstract

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Keywords

ASJC Scopus subject areas

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