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Quantitative phosphoproteomic analysis of the molecular substrates of sleep need

Author

Listed:
  • Zhiqiang Wang

    (University of Tsukuba)

  • Jing Ma

    (University of Tsukuba)

  • Chika Miyoshi

    (University of Tsukuba)

  • Yuxin Li

    (St. Jude Children’s Research Hospital)

  • Makito Sato

    (University of Tsukuba)

  • Yukino Ogawa

    (University of Tsukuba)

  • Tingting Lou

    (University of Tsukuba)

  • Chengyuan Ma

    (National Institute of Biological Sciences)

  • Xue Gao

    (National Institute of Biological Sciences)

  • Chiyu Lee

    (University of Tsukuba)

  • Tomoyuki Fujiyama

    (University of Tsukuba)

  • Xiaojie Yang

    (University of Tsukuba)

  • Shuang Zhou

    (National Institute of Biological Sciences)

  • Noriko Hotta-Hirashima

    (University of Tsukuba)

  • Daniela Klewe-Nebenius

    (University of Tsukuba)

  • Aya Ikkyu

    (University of Tsukuba)

  • Miyo Kakizaki

    (University of Tsukuba)

  • Satomi Kanno

    (University of Tsukuba)

  • Liqin Cao

    (University of Tsukuba)

  • Satoru Takahashi

    (University of Tsukuba)

  • Junmin Peng

    (St. Jude Children’s Research Hospital)

  • Yonghao Yu

    (University of Texas Southwestern Medical Center)

  • Hiromasa Funato

    (University of Tsukuba
    Toho University)

  • Masashi Yanagisawa

    (University of Tsukuba
    University of Texas Southwestern Medical Center
    University of Tsukuba)

  • Qinghua Liu

    (University of Tsukuba
    National Institute of Biological Sciences
    Tsinghua University
    University of Texas Southwestern Medical Center)

Abstract

Sleep and wake have global effects on brain physiology, from molecular changes1–4 and neuronal activities to synaptic plasticity3–7. Sleep–wake homeostasis is maintained by the generation of a sleep need that accumulates during waking and dissipates during sleep8–11. Here we investigate the molecular basis of sleep need using quantitative phosphoproteomic analysis of the sleep-deprived and Sleepy mouse models of increased sleep need. Sleep deprivation induces cumulative phosphorylation of the brain proteome, which dissipates during sleep. Sleepy mice, owing to a gain-of-function mutation in the Sik3 gene 12 , have a constitutively high sleep need despite increased sleep amount. The brain proteome of these mice exhibits hyperphosphorylation, similar to that seen in the brain of sleep-deprived mice. Comparison of the two models identifies 80 mostly synaptic sleep-need-index phosphoproteins (SNIPPs), in which phosphorylation states closely parallel changes of sleep need. SLEEPY, the mutant SIK3 protein, preferentially associates with and phosphorylates SNIPPs. Inhibition of SIK3 activity reduces phosphorylation of SNIPPs and slow wave activity during non-rapid-eye-movement sleep, the best known measurable index of sleep need, in both Sleepy mice and sleep-deprived wild-type mice. Our results suggest that phosphorylation of SNIPPs accumulates and dissipates in relation to sleep need, and therefore SNIPP phosphorylation is a molecular signature of sleep need. Whereas waking encodes memories by potentiating synapses, sleep consolidates memories and restores synaptic homeostasis by globally downscaling excitatory synapses4–6. Thus, the phosphorylation–dephosphorylation cycle of SNIPPs may represent a major regulatory mechanism that underlies both synaptic homeostasis and sleep–wake homeostasis.

Suggested Citation

  • Zhiqiang Wang & Jing Ma & Chika Miyoshi & Yuxin Li & Makito Sato & Yukino Ogawa & Tingting Lou & Chengyuan Ma & Xue Gao & Chiyu Lee & Tomoyuki Fujiyama & Xiaojie Yang & Shuang Zhou & Noriko Hotta-Hira, 2018. "Quantitative phosphoproteomic analysis of the molecular substrates of sleep need," Nature, Nature, vol. 558(7710), pages 435-439, June.
  • Handle: RePEc:nat:nature:v:558:y:2018:i:7710:d:10.1038_s41586-018-0218-8
    DOI: 10.1038/s41586-018-0218-8
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    Cited by:

    1. Enrico Pracucci & Robert T. Graham & Laura Alberio & Gabriele Nardi & Olga Cozzolino & Vinoshene Pillai & Giacomo Pasquini & Luciano Saieva & Darren Walsh & Silvia Landi & Jinwei Zhang & Andrew J. Tre, 2023. "Daily rhythm in cortical chloride homeostasis underpins functional changes in visual cortex excitability," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    2. Kazuhiro Kon & Koji L. Ode & Tomoyuki Mano & Hiroshi Fujishima & Riina R. Takahashi & Daisuke Tone & Chika Shimizu & Shinnosuke Shiono & Saori Yada & Kyoko Matsuzawa & Shota Y. Yoshida & Junko Yoshida, 2024. "Cortical parvalbumin neurons are responsible for homeostatic sleep rebound through CaMKII activation," Nature Communications, Nature, vol. 15(1), pages 1-19, December.

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