Mitochondria directly sense osmotic stress to trigger rapid metabolic remodeling via regulation of pyruvate dehydrogenase phosphorylation

Takeshi Ikizawa; Kazutaka Ikeda; Makoto Arita; Shojiro Kitajima; Tomoyoshi Soga; Hidenori Ichijo; Isao Naguro

doi:10.1016/j.jbc.2022.102837

Mitochondria directly sense osmotic stress to trigger rapid metabolic remodeling via regulation of pyruvate dehydrogenase phosphorylation

Takeshi Ikizawa, Kazutaka Ikeda, Makoto Arita, Shojiro Kitajima, Tomoyoshi Soga, Hidenori Ichijo, Isao Naguro

研究成果: Article › 査読

抄録

A high-salt diet significantly impacts various diseases, ilncluding cancer and immune diseases. Recent studies suggest that the high-salt/hyperosmotic environment in the body may alter the chronic properties of cancer and immune cells in the disease context. However, little is known about the acute metabolic changes in hyperosmotic stress. Here, we found that hyperosmotic stress for a few minutes induces Warburg-like metabolic remodeling in HeLa and Raw264.7 cells and suppresses fatty acid oxidation. Regarding Warburg-like remodeling, we determined that the pyruvate dehydrogenase phosphorylation status was altered bidirectionally (high in hyperosmolarity and low in hypoosmolarity) to osmotic stress in isolated mitochondria, suggesting that mitochondria themselves have an acute osmosensing mechanism. Additionally, we demonstrate that Warburg-like remodeling is required for HeLa cells to maintain ATP levels and survive under hyperosmotic conditions. Collectively, our findings suggest that cells exhibit acute metabolic remodeling under osmotic stress via the regulation of pyruvate dehydrogenase phosphorylation by direct osmosensing within mitochondria.

本文言語	English
論文番号	102837
ジャーナル	Journal of Biological Chemistry
巻	299
号	2
DOI	https://doi.org/10.1016/j.jbc.2022.102837
出版ステータス	Published - 2023 2月

ASJC Scopus subject areas

生化学
分子生物学
細胞生物学

UN SDG

この成果は、次の持続可能な開発目標に貢献しています

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10.1016/j.jbc.2022.102837

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@article{f58f25e8064948419f97b49e23cf07b5,

title = "Mitochondria directly sense osmotic stress to trigger rapid metabolic remodeling via regulation of pyruvate dehydrogenase phosphorylation",

abstract = "A high-salt diet significantly impacts various diseases, ilncluding cancer and immune diseases. Recent studies suggest that the high-salt/hyperosmotic environment in the body may alter the chronic properties of cancer and immune cells in the disease context. However, little is known about the acute metabolic changes in hyperosmotic stress. Here, we found that hyperosmotic stress for a few minutes induces Warburg-like metabolic remodeling in HeLa and Raw264.7 cells and suppresses fatty acid oxidation. Regarding Warburg-like remodeling, we determined that the pyruvate dehydrogenase phosphorylation status was altered bidirectionally (high in hyperosmolarity and low in hypoosmolarity) to osmotic stress in isolated mitochondria, suggesting that mitochondria themselves have an acute osmosensing mechanism. Additionally, we demonstrate that Warburg-like remodeling is required for HeLa cells to maintain ATP levels and survive under hyperosmotic conditions. Collectively, our findings suggest that cells exhibit acute metabolic remodeling under osmotic stress via the regulation of pyruvate dehydrogenase phosphorylation by direct osmosensing within mitochondria.",

keywords = "acyl-carnitine, metabolic remodeling, mitochondria, osmotic stress, pyruvate dehydrogenase",

author = "Takeshi Ikizawa and Kazutaka Ikeda and Makoto Arita and Shojiro Kitajima and Tomoyoshi Soga and Hidenori Ichijo and Isao Naguro",

note = "Funding Information: We thank S. Torii, K. Ohshima, and S. Shimizu (Department of Pathological Cell Biology, Medical Research Institute, Tokyo Medical and Dental University) for teaching us the mitochondria isolation technique; S. Hasegawa and R. Inagi (Division of CKD Pathophysiology, The University of Tokyo) for allowing us to use the equipment of extracellular flux analyzer; and K. Saito, K. Kato, and K. Umetsu (Institute for Advanced Biosciences, Keio University) for performing MS analysis and analyzing data of the metabolome analysis using 13C6-glucose tracer. We also thank all of the members of Laboratory of Cell Signaling in The University of Tokyo for critical discussions. This work was supported by the research funds from the Yamagata prefectural government and Tsuruoka city. T. I. K. I. M. A. S. K. and T. S. methodology; T. I. and I. N. validation; T. I. and I. N. formal analysis; T. I. K. I. M. A. S. K. and T. S. investigation; T. I. H. I. and I. N. writing–original draft; T. I. and I. N. visualization; T. I. K. I. S. K. and I. N. data curation; K. I. M. A. S. K. T. S. software; M. A. T. S. and H. I. resources; H. I. and I. N. conceptualization; H. I. and I. N. writing–review and editing; H. I. and I. N. supervision; I. N. project administration. This work was supported by the Japan Science and Technology Agency (JST) under the Moonshot R&D-MILLENNIA program (grant number JPMJMS2022-18 to H. I.), Japan Agency for Medical Research and Development (AMED) under the Project for Elucidating and Controlling Mechanisms of Aging and Longevity (grant number JP21gm5010001 to H. I.), Japan Society for the Promotion of Science (JSPS) under the Grant-in-Aid for Scientific Research on Innovative Areas (KAKENHI; grant number JP17H06419 to I. N. and JP15H05897 to M. A.) and the Grant-in-Aid for Scientific Research (KAKENHI; grant numbers JP18H03995, JP21H04760 to H. I. JP18H02569, JP22H02761 to I. N. JP20K07598 to S. K.), Nakatomi Foundation to I. N. Naito Grant for the advancement of natural science to I. N, and Takeda Science Foundation to S. K. Funding Information: We thank S. Torii, K. Ohshima, and S. Shimizu (Department of Pathological Cell Biology, Medical Research Institute, Tokyo Medical and Dental University) for teaching us the mitochondria isolation technique; S. Hasegawa and R. Inagi (Division of CKD Pathophysiology, The University of Tokyo) for allowing us to use the equipment of extracellular flux analyzer; and K. Saito, K. Kato, and K. Umetsu (Institute for Advanced Biosciences, Keio University) for performing MS analysis and analyzing data of the metabolome analysis using 13 C 6 -glucose tracer. We also thank all of the members of Laboratory of Cell Signaling in The University of Tokyo for critical discussions. This work was supported by the research funds from the Yamagata prefectural government and Tsuruoka city. Funding Information: This work was supported by the Japan Science and Technology Agency (JST) under the Moonshot R&D-MILLENNIA program (grant number JPMJMS2022-18 to H. I.), Japan Agency for Medical Research and Development (AMED) under the Project for Elucidating and Controlling Mechanisms of Aging and Longevity (grant number J P21gm5010001 to H. I.), Japan Society for the Promotion of Science (JSPS) under the Grant-in-Aid for Scientific Research on Innovative Areas (KAKENHI; grant number JP17H06419 to I. N., and JP15H05897 to M. A.) and the Grant-in-Aid for Scientific Research (KAKENHI; grant numbers JP18H03995 , JP21H04760 to H. I., JP18H02569 , JP22H02761 to I. N., JP20K07598 to S. K.), Nakatomi Foundation to I. N., Naito Grant for the advancement of natural science to I. N, and Takeda Science Foundation to S. K. Publisher Copyright: {\textcopyright} 2022 The Authors",

year = "2023",

month = feb,

doi = "10.1016/j.jbc.2022.102837",

language = "English",

volume = "299",

journal = "Journal of Biological Chemistry",

issn = "0021-9258",

publisher = "American Society for Biochemistry and Molecular Biology Inc.",

number = "2",

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TY - JOUR

T1 - Mitochondria directly sense osmotic stress to trigger rapid metabolic remodeling via regulation of pyruvate dehydrogenase phosphorylation

AU - Ikizawa, Takeshi

AU - Ikeda, Kazutaka

AU - Arita, Makoto

AU - Kitajima, Shojiro

AU - Soga, Tomoyoshi

AU - Ichijo, Hidenori

AU - Naguro, Isao

N1 - Funding Information: We thank S. Torii, K. Ohshima, and S. Shimizu (Department of Pathological Cell Biology, Medical Research Institute, Tokyo Medical and Dental University) for teaching us the mitochondria isolation technique; S. Hasegawa and R. Inagi (Division of CKD Pathophysiology, The University of Tokyo) for allowing us to use the equipment of extracellular flux analyzer; and K. Saito, K. Kato, and K. Umetsu (Institute for Advanced Biosciences, Keio University) for performing MS analysis and analyzing data of the metabolome analysis using 13C6-glucose tracer. We also thank all of the members of Laboratory of Cell Signaling in The University of Tokyo for critical discussions. This work was supported by the research funds from the Yamagata prefectural government and Tsuruoka city. T. I. K. I. M. A. S. K. and T. S. methodology; T. I. and I. N. validation; T. I. and I. N. formal analysis; T. I. K. I. M. A. S. K. and T. S. investigation; T. I. H. I. and I. N. writing–original draft; T. I. and I. N. visualization; T. I. K. I. S. K. and I. N. data curation; K. I. M. A. S. K. T. S. software; M. A. T. S. and H. I. resources; H. I. and I. N. conceptualization; H. I. and I. N. writing–review and editing; H. I. and I. N. supervision; I. N. project administration. This work was supported by the Japan Science and Technology Agency (JST) under the Moonshot R&D-MILLENNIA program (grant number JPMJMS2022-18 to H. I.), Japan Agency for Medical Research and Development (AMED) under the Project for Elucidating and Controlling Mechanisms of Aging and Longevity (grant number JP21gm5010001 to H. I.), Japan Society for the Promotion of Science (JSPS) under the Grant-in-Aid for Scientific Research on Innovative Areas (KAKENHI; grant number JP17H06419 to I. N. and JP15H05897 to M. A.) and the Grant-in-Aid for Scientific Research (KAKENHI; grant numbers JP18H03995, JP21H04760 to H. I. JP18H02569, JP22H02761 to I. N. JP20K07598 to S. K.), Nakatomi Foundation to I. N. Naito Grant for the advancement of natural science to I. N, and Takeda Science Foundation to S. K. Funding Information: We thank S. Torii, K. Ohshima, and S. Shimizu (Department of Pathological Cell Biology, Medical Research Institute, Tokyo Medical and Dental University) for teaching us the mitochondria isolation technique; S. Hasegawa and R. Inagi (Division of CKD Pathophysiology, The University of Tokyo) for allowing us to use the equipment of extracellular flux analyzer; and K. Saito, K. Kato, and K. Umetsu (Institute for Advanced Biosciences, Keio University) for performing MS analysis and analyzing data of the metabolome analysis using 13 C 6 -glucose tracer. We also thank all of the members of Laboratory of Cell Signaling in The University of Tokyo for critical discussions. This work was supported by the research funds from the Yamagata prefectural government and Tsuruoka city. Funding Information: This work was supported by the Japan Science and Technology Agency (JST) under the Moonshot R&D-MILLENNIA program (grant number JPMJMS2022-18 to H. I.), Japan Agency for Medical Research and Development (AMED) under the Project for Elucidating and Controlling Mechanisms of Aging and Longevity (grant number J P21gm5010001 to H. I.), Japan Society for the Promotion of Science (JSPS) under the Grant-in-Aid for Scientific Research on Innovative Areas (KAKENHI; grant number JP17H06419 to I. N., and JP15H05897 to M. A.) and the Grant-in-Aid for Scientific Research (KAKENHI; grant numbers JP18H03995 , JP21H04760 to H. I., JP18H02569 , JP22H02761 to I. N., JP20K07598 to S. K.), Nakatomi Foundation to I. N., Naito Grant for the advancement of natural science to I. N, and Takeda Science Foundation to S. K. Publisher Copyright: © 2022 The Authors

PY - 2023/2

Y1 - 2023/2

N2 - A high-salt diet significantly impacts various diseases, ilncluding cancer and immune diseases. Recent studies suggest that the high-salt/hyperosmotic environment in the body may alter the chronic properties of cancer and immune cells in the disease context. However, little is known about the acute metabolic changes in hyperosmotic stress. Here, we found that hyperosmotic stress for a few minutes induces Warburg-like metabolic remodeling in HeLa and Raw264.7 cells and suppresses fatty acid oxidation. Regarding Warburg-like remodeling, we determined that the pyruvate dehydrogenase phosphorylation status was altered bidirectionally (high in hyperosmolarity and low in hypoosmolarity) to osmotic stress in isolated mitochondria, suggesting that mitochondria themselves have an acute osmosensing mechanism. Additionally, we demonstrate that Warburg-like remodeling is required for HeLa cells to maintain ATP levels and survive under hyperosmotic conditions. Collectively, our findings suggest that cells exhibit acute metabolic remodeling under osmotic stress via the regulation of pyruvate dehydrogenase phosphorylation by direct osmosensing within mitochondria.

AB - A high-salt diet significantly impacts various diseases, ilncluding cancer and immune diseases. Recent studies suggest that the high-salt/hyperosmotic environment in the body may alter the chronic properties of cancer and immune cells in the disease context. However, little is known about the acute metabolic changes in hyperosmotic stress. Here, we found that hyperosmotic stress for a few minutes induces Warburg-like metabolic remodeling in HeLa and Raw264.7 cells and suppresses fatty acid oxidation. Regarding Warburg-like remodeling, we determined that the pyruvate dehydrogenase phosphorylation status was altered bidirectionally (high in hyperosmolarity and low in hypoosmolarity) to osmotic stress in isolated mitochondria, suggesting that mitochondria themselves have an acute osmosensing mechanism. Additionally, we demonstrate that Warburg-like remodeling is required for HeLa cells to maintain ATP levels and survive under hyperosmotic conditions. Collectively, our findings suggest that cells exhibit acute metabolic remodeling under osmotic stress via the regulation of pyruvate dehydrogenase phosphorylation by direct osmosensing within mitochondria.

KW - acyl-carnitine

KW - metabolic remodeling

KW - mitochondria

KW - osmotic stress

KW - pyruvate dehydrogenase

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U2 - 10.1016/j.jbc.2022.102837

DO - 10.1016/j.jbc.2022.102837

M3 - Article

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JO - Journal of Biological Chemistry

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