The methyl cycle is a conserved regulator of biological clocks

Jean-Michel Fustin; Shiqi Ye; Christin Rakers; Marijke Versteven; Samantha J. Cargill; T. Katherine Tamai; Yao Xu; Maria Luísa Jabbur; Rika Kojima; Melisa L. Lamberti; Kumiko Yoshioka-Kobayashi; David Whitmore; Ryoichiro Kageyama; Takuya Matsuo; Ralf Stanewsky; Diego A. Golombek; Carl Hirschie Johnson; Gerben van Ooijen; Hitoshi Okamura

doi:10.1101/653667

The methyl cycle is a conserved regulator of biological clocks

Jean-Michel Fustin, Shiqi Ye, Christin Rakers, Marijke Versteven, Samantha J. Cargill, T. Katherine Tamai, Yao Xu, Maria Luísa Jabbur, Rika Kojima, Melisa L. Lamberti, Kumiko Yoshioka-Kobayashi, David Whitmore, Ryoichiro Kageyama, Takuya Matsuo, Ralf Stanewsky, Diego A. Golombek, Carl Hirschie Johnson, Gerben van Ooijen, Hitoshi Okamura

Division of Diabetes, Endocrinology & Gastroenterology (L5)

Research output: Contribution to journal › Article

Abstract

The methyl cycle is a universally conserved metabolic pathway operating in prokaryotes and eukaryotes. In this pathway, the amino acid methionine is used to synthesize S-adenosylmethionine, the methyl donor co-substrate in the methylation of nucleic acids, histone and non-histone proteins and many other molecules within the cell. The methylation of nucleic acids and proteins is the foundation of epigenetic and epitranscriptomic regulations of gene expression, but whether the methyl cycle centrally regulates gene expression and function by controlling the availability of methyl moieties is poorly understood.

From cyanobacteria to humans, a circadian clock that involves an exquisitely regulated transcription-translation-feedback loop driving oscillations in gene expression and orchestrating physiology and behavior has been described. We reported previously that inhibition of the methyl cycle in mammalian cells caused the lengthening of the period of these oscillations, suggesting the methyl cycle may indeed act as a central regulator of gene expression, at least in mammals. Here, we investigated whether the methyl cycle, given its universal presence among living beings, regulates the circadian clock in species across the phylogenetic tree of life.

We reveal a remarkable evolutionary conservation of the link between the methyl cycle and the circadian clock. Moreover, we show that the methyl cycle also regulates the somite segmentation clock, another transcription-translation negative feedback loop-based timing mechanism that orchestrate embryonic development in vertebrates, highlighting the methyl cycle as a master regulator of biological clocks.

SIGNIFICANCE STATEMENT Here we reveal that the methyl cycle, a universal metabolic pathway leading to the synthesis of S-adenosylmethionine, the methyl donor co-substrate in virtually all transmethylation reactions within the cell, is a conserved regulator of biological clocks. These discoveries highlight the methyl cycle as a metabolic hub that regulates gene expression via the availability of methyl moieties for the methylation of nucleic acids, proteins and many other molecules with the cell.

Original language	Undefined
Journal	bioRxiv
DOIs	https://doi.org/10.1101/653667
Publication status	Published - 29 May 2019

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10.1101/653667

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Fustin, J.-M., Ye, S., Rakers, C., Versteven, M., Cargill, S. J., Tamai, T. K., Xu, Y., Jabbur, M. L., Kojima, R., Lamberti, M. L., Yoshioka-Kobayashi, K., Whitmore, D., Kageyama, R., Matsuo, T., Stanewsky, R., Golombek, D. A., Johnson, C. H., Ooijen, G. V., & Okamura, H. (2019). The methyl cycle is a conserved regulator of biological clocks. bioRxiv. https://doi.org/10.1101/653667

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title = "The methyl cycle is a conserved regulator of biological clocks",

abstract = "The methyl cycle is a universally conserved metabolic pathway operating in prokaryotes and eukaryotes. In this pathway, the amino acid methionine is used to synthesize S-adenosylmethionine, the methyl donor co-substrate in the methylation of nucleic acids, histone and non-histone proteins and many other molecules within the cell. The methylation of nucleic acids and proteins is the foundation of epigenetic and epitranscriptomic regulations of gene expression, but whether the methyl cycle centrally regulates gene expression and function by controlling the availability of methyl moieties is poorly understood.From cyanobacteria to humans, a circadian clock that involves an exquisitely regulated transcription-translation-feedback loop driving oscillations in gene expression and orchestrating physiology and behavior has been described. We reported previously that inhibition of the methyl cycle in mammalian cells caused the lengthening of the period of these oscillations, suggesting the methyl cycle may indeed act as a central regulator of gene expression, at least in mammals. Here, we investigated whether the methyl cycle, given its universal presence among living beings, regulates the circadian clock in species across the phylogenetic tree of life.We reveal a remarkable evolutionary conservation of the link between the methyl cycle and the circadian clock. Moreover, we show that the methyl cycle also regulates the somite segmentation clock, another transcription-translation negative feedback loop-based timing mechanism that orchestrate embryonic development in vertebrates, highlighting the methyl cycle as a master regulator of biological clocks.SIGNIFICANCE STATEMENT Here we reveal that the methyl cycle, a universal metabolic pathway leading to the synthesis of S-adenosylmethionine, the methyl donor co-substrate in virtually all transmethylation reactions within the cell, is a conserved regulator of biological clocks. These discoveries highlight the methyl cycle as a metabolic hub that regulates gene expression via the availability of methyl moieties for the methylation of nucleic acids, proteins and many other molecules with the cell.",

author = "Jean-Michel Fustin and Shiqi Ye and Christin Rakers and Marijke Versteven and Cargill, {Samantha J.} and Tamai, {T. Katherine} and Yao Xu and Jabbur, {Maria Lu{\'i}sa} and Rika Kojima and Lamberti, {Melisa L.} and Kumiko Yoshioka-Kobayashi and David Whitmore and Ryoichiro Kageyama and Takuya Matsuo and Ralf Stanewsky and Golombek, {Diego A.} and Johnson, {Carl Hirschie} and Ooijen, {Gerben van} and Hitoshi Okamura",

year = "2019",

month = may,

day = "29",

doi = "10.1101/653667",

language = "Undefined",

journal = "bioRxiv",

publisher = "Cold Spring Harbor Laboratory Press",

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TY - JOUR

T1 - The methyl cycle is a conserved regulator of biological clocks

AU - Fustin, Jean-Michel

AU - Ye, Shiqi

AU - Rakers, Christin

AU - Versteven, Marijke

AU - Cargill, Samantha J.

AU - Tamai, T. Katherine

AU - Xu, Yao

AU - Jabbur, Maria Luísa

AU - Kojima, Rika

AU - Lamberti, Melisa L.

AU - Yoshioka-Kobayashi, Kumiko

AU - Whitmore, David

AU - Kageyama, Ryoichiro

AU - Matsuo, Takuya

AU - Stanewsky, Ralf

AU - Golombek, Diego A.

AU - Johnson, Carl Hirschie

AU - Ooijen, Gerben van

AU - Okamura, Hitoshi

PY - 2019/5/29

Y1 - 2019/5/29

N2 - The methyl cycle is a universally conserved metabolic pathway operating in prokaryotes and eukaryotes. In this pathway, the amino acid methionine is used to synthesize S-adenosylmethionine, the methyl donor co-substrate in the methylation of nucleic acids, histone and non-histone proteins and many other molecules within the cell. The methylation of nucleic acids and proteins is the foundation of epigenetic and epitranscriptomic regulations of gene expression, but whether the methyl cycle centrally regulates gene expression and function by controlling the availability of methyl moieties is poorly understood.From cyanobacteria to humans, a circadian clock that involves an exquisitely regulated transcription-translation-feedback loop driving oscillations in gene expression and orchestrating physiology and behavior has been described. We reported previously that inhibition of the methyl cycle in mammalian cells caused the lengthening of the period of these oscillations, suggesting the methyl cycle may indeed act as a central regulator of gene expression, at least in mammals. Here, we investigated whether the methyl cycle, given its universal presence among living beings, regulates the circadian clock in species across the phylogenetic tree of life.We reveal a remarkable evolutionary conservation of the link between the methyl cycle and the circadian clock. Moreover, we show that the methyl cycle also regulates the somite segmentation clock, another transcription-translation negative feedback loop-based timing mechanism that orchestrate embryonic development in vertebrates, highlighting the methyl cycle as a master regulator of biological clocks.SIGNIFICANCE STATEMENT Here we reveal that the methyl cycle, a universal metabolic pathway leading to the synthesis of S-adenosylmethionine, the methyl donor co-substrate in virtually all transmethylation reactions within the cell, is a conserved regulator of biological clocks. These discoveries highlight the methyl cycle as a metabolic hub that regulates gene expression via the availability of methyl moieties for the methylation of nucleic acids, proteins and many other molecules with the cell.

AB - The methyl cycle is a universally conserved metabolic pathway operating in prokaryotes and eukaryotes. In this pathway, the amino acid methionine is used to synthesize S-adenosylmethionine, the methyl donor co-substrate in the methylation of nucleic acids, histone and non-histone proteins and many other molecules within the cell. The methylation of nucleic acids and proteins is the foundation of epigenetic and epitranscriptomic regulations of gene expression, but whether the methyl cycle centrally regulates gene expression and function by controlling the availability of methyl moieties is poorly understood.From cyanobacteria to humans, a circadian clock that involves an exquisitely regulated transcription-translation-feedback loop driving oscillations in gene expression and orchestrating physiology and behavior has been described. We reported previously that inhibition of the methyl cycle in mammalian cells caused the lengthening of the period of these oscillations, suggesting the methyl cycle may indeed act as a central regulator of gene expression, at least in mammals. Here, we investigated whether the methyl cycle, given its universal presence among living beings, regulates the circadian clock in species across the phylogenetic tree of life.We reveal a remarkable evolutionary conservation of the link between the methyl cycle and the circadian clock. Moreover, we show that the methyl cycle also regulates the somite segmentation clock, another transcription-translation negative feedback loop-based timing mechanism that orchestrate embryonic development in vertebrates, highlighting the methyl cycle as a master regulator of biological clocks.SIGNIFICANCE STATEMENT Here we reveal that the methyl cycle, a universal metabolic pathway leading to the synthesis of S-adenosylmethionine, the methyl donor co-substrate in virtually all transmethylation reactions within the cell, is a conserved regulator of biological clocks. These discoveries highlight the methyl cycle as a metabolic hub that regulates gene expression via the availability of methyl moieties for the methylation of nucleic acids, proteins and many other molecules with the cell.

UR - https://doi.org/10.1101/653667

U2 - 10.1101/653667

DO - 10.1101/653667

M3 - Article

JO - bioRxiv

JF - bioRxiv

ER -

The methyl cycle is a conserved regulator of biological clocks

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Centre for Biological Timing

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The methyl cycle is a conserved regulator of biological clocks

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