Dietary protein restriction elevates FGF21 levels and energy requirements to maintain body weight in lean men

Trine S Nicolaisen; Aslak E Lyster; Kim A Sjøberg; Daniel T Haas; Christian T Voldstedlund; Anne-Marie Lundsgaard; Jakob K Jensen; Ea M Madsen; Casper K Nielsen; Mads Bloch-Ibenfeldt; Nicolai J Wewer Albrechtsen; Adam J Rose; Natalie Krahmer; Christoffer Clemmensen; Erik A Richter; Andreas M Fritzen; Bente Kiens

doi:10.1038/s42255-025-01236-7

Dietary protein restriction elevates FGF21 levels and energy requirements to maintain body weight in lean men

Trine S Nicolaisen, Aslak E Lyster, Kim A Sjøberg, Daniel T Haas, Christian T Voldstedlund, Anne-Marie Lundsgaard, Jakob K Jensen, Ea M Madsen, Casper K Nielsen, Mads Bloch-Ibenfeldt, Nicolai J Wewer Albrechtsen, Adam J Rose, Natalie Krahmer, Christoffer Clemmensen, Erik A Richter, Andreas M Fritzen, Bente Kiens^*

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

Dietary protein restriction increases energy expenditure and enhances insulin sensitivity in mice. However, the effects of a eucaloric protein-restricted diet in healthy humans remain unexplored. Here, we show in lean, healthy men that a protein-restricted diet meeting the minimum protein requirements for 5 weeks necessitates an increase in energy intake to uphold body weight, regardless of whether proteins are replaced with fats or carbohydrates. Upon reverting to the customary higher protein intake in the following 5 weeks, energy requirements return to baseline levels, thus preventing weight gain. We also show that fasting plasma FGF21 levels increase during protein restriction. Proteomic analysis of human white adipose tissue and in FGF21-knockout mice reveal alterations in key components of the electron transport chain within white adipose tissue mitochondria. Notably, in male mice, these changes appear to be dependent on FGF21. In conclusion, we demonstrate that maintaining body weight during dietary protein restriction in healthy, lean men requires a higher energy intake, partially driven by FGF21-mediated mitochondrial adaptations in adipose tissue.

Original language	English
Journal	Nature Metabolism
ISSN	2522-5812
DOIs	https://doi.org/10.1038/s42255-025-01236-7
Publication status	E-pub ahead of print - 2025

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Nicolaisen, T. S., Lyster, A. E., Sjøberg, K. A., Haas, D. T., Voldstedlund, C. T., Lundsgaard, A.-M., Jensen, J. K., Madsen, E. M., Nielsen, C. K., Bloch-Ibenfeldt, M., Wewer Albrechtsen, N. J., Rose, A. J., Krahmer, N., Clemmensen, C., Richter, E. A., Fritzen, A. M., & Kiens, B. (2025). Dietary protein restriction elevates FGF21 levels and energy requirements to maintain body weight in lean men. Nature Metabolism. Advance online publication. https://doi.org/10.1038/s42255-025-01236-7

Nicolaisen, TS, Lyster, AE, Sjøberg, KA, Haas, DT, Voldstedlund, CT , Lundsgaard, A-M, Jensen, JK, Madsen, EM, Nielsen, CK, Bloch-Ibenfeldt, M , Wewer Albrechtsen, NJ, Rose, AJ, Krahmer, N, Clemmensen, C , Richter, EA , Fritzen, AM & Kiens, B 2025, 'Dietary protein restriction elevates FGF21 levels and energy requirements to maintain body weight in lean men', Nature Metabolism. https://doi.org/10.1038/s42255-025-01236-7

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title = "Dietary protein restriction elevates FGF21 levels and energy requirements to maintain body weight in lean men",

abstract = "Dietary protein restriction increases energy expenditure and enhances insulin sensitivity in mice. However, the effects of a eucaloric protein-restricted diet in healthy humans remain unexplored. Here, we show in lean, healthy men that a protein-restricted diet meeting the minimum protein requirements for 5 weeks necessitates an increase in energy intake to uphold body weight, regardless of whether proteins are replaced with fats or carbohydrates. Upon reverting to the customary higher protein intake in the following 5 weeks, energy requirements return to baseline levels, thus preventing weight gain. We also show that fasting plasma FGF21 levels increase during protein restriction. Proteomic analysis of human white adipose tissue and in FGF21-knockout mice reveal alterations in key components of the electron transport chain within white adipose tissue mitochondria. Notably, in male mice, these changes appear to be dependent on FGF21. In conclusion, we demonstrate that maintaining body weight during dietary protein restriction in healthy, lean men requires a higher energy intake, partially driven by FGF21-mediated mitochondrial adaptations in adipose tissue.",

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T1 - Dietary protein restriction elevates FGF21 levels and energy requirements to maintain body weight in lean men

AU - Nicolaisen, Trine S

AU - Lyster, Aslak E

AU - Sjøberg, Kim A

AU - Haas, Daniel T

AU - Voldstedlund, Christian T

AU - Lundsgaard, Anne-Marie

AU - Jensen, Jakob K

AU - Madsen, Ea M

AU - Nielsen, Casper K

AU - Bloch-Ibenfeldt, Mads

AU - Wewer Albrechtsen, Nicolai J

AU - Rose, Adam J

AU - Krahmer, Natalie

AU - Clemmensen, Christoffer

AU - Richter, Erik A

AU - Fritzen, Andreas M

AU - Kiens, Bente

PY - 2025

Y1 - 2025

N2 - Dietary protein restriction increases energy expenditure and enhances insulin sensitivity in mice. However, the effects of a eucaloric protein-restricted diet in healthy humans remain unexplored. Here, we show in lean, healthy men that a protein-restricted diet meeting the minimum protein requirements for 5 weeks necessitates an increase in energy intake to uphold body weight, regardless of whether proteins are replaced with fats or carbohydrates. Upon reverting to the customary higher protein intake in the following 5 weeks, energy requirements return to baseline levels, thus preventing weight gain. We also show that fasting plasma FGF21 levels increase during protein restriction. Proteomic analysis of human white adipose tissue and in FGF21-knockout mice reveal alterations in key components of the electron transport chain within white adipose tissue mitochondria. Notably, in male mice, these changes appear to be dependent on FGF21. In conclusion, we demonstrate that maintaining body weight during dietary protein restriction in healthy, lean men requires a higher energy intake, partially driven by FGF21-mediated mitochondrial adaptations in adipose tissue.

AB - Dietary protein restriction increases energy expenditure and enhances insulin sensitivity in mice. However, the effects of a eucaloric protein-restricted diet in healthy humans remain unexplored. Here, we show in lean, healthy men that a protein-restricted diet meeting the minimum protein requirements for 5 weeks necessitates an increase in energy intake to uphold body weight, regardless of whether proteins are replaced with fats or carbohydrates. Upon reverting to the customary higher protein intake in the following 5 weeks, energy requirements return to baseline levels, thus preventing weight gain. We also show that fasting plasma FGF21 levels increase during protein restriction. Proteomic analysis of human white adipose tissue and in FGF21-knockout mice reveal alterations in key components of the electron transport chain within white adipose tissue mitochondria. Notably, in male mice, these changes appear to be dependent on FGF21. In conclusion, we demonstrate that maintaining body weight during dietary protein restriction in healthy, lean men requires a higher energy intake, partially driven by FGF21-mediated mitochondrial adaptations in adipose tissue.

U2 - 10.1038/s42255-025-01236-7

DO - 10.1038/s42255-025-01236-7

M3 - Journal article

C2 - 40050437

SN - 2522-5812

JO - Nature Metabolism

JF - Nature Metabolism

ER -