Elsevier

Molecular Metabolism

Volume 54, December 2021, 101359
Molecular Metabolism

Original Article
Exercise prevents fatty liver by modifying the compensatory response of mitochondrial metabolism to excess substrate availability

https://doi.org/10.1016/j.molmet.2021.101359Get rights and content
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open access

Highlights

  • High-energy diet promotes mitochondrial respiration in liver independent of training.

  • High-energy diet combined with training disconnects substrate oxidation from lipid synthesis.

  • High-energy diet combined with training reduces complex I formation in the liver.

  • Trained skeletal muscle unburdens the liver from substrate overload.

  • Comprehensive resource of mitochondrial adaptations to high-energy diet and training.

Abstract

Objective

Liver mitochondria adapt to high-calorie intake. We investigated how exercise alters the early compensatory response of mitochondria, thus preventing fatty liver disease as a long-term consequence of overnutrition.

Methods

We compared the effects of a steatogenic high-energy diet (HED) for six weeks on mitochondrial metabolism of sedentary and treadmill-trained C57BL/6N mice. We applied multi-OMICs analyses to study the alterations in the proteome, transcriptome, and lipids in isolated mitochondria of liver and skeletal muscle as well as in whole tissue and examined the functional consequences by high-resolution respirometry.

Results

HED increased the respiratory capacity of isolated liver mitochondria, both in sedentary and in trained mice. However, proteomics analysis of the mitochondria and transcriptomics indicated that training modified the adaptation of the hepatic metabolism to HED on the level of respiratory complex I, glucose oxidation, pyruvate and acetyl-CoA metabolism, and lipogenesis. Training also counteracted the HED-induced glucose intolerance, the increase in fasting insulin, and in liver fat by lowering diacylglycerol species and c-Jun N-terminal kinase (JNK) phosphorylation in the livers of trained HED-fed mice, two mechanisms that can reverse hepatic insulin resistance. In skeletal muscle, the combination of HED and training improved the oxidative capacity to a greater extent than training alone by increasing respiration of isolated mitochondria and total mitochondrial protein content.

Conclusion

We provide a comprehensive insight into the early adaptations of mitochondria in the liver and skeletal muscle to HED and endurance training. Our results suggest that exercise disconnects the HED-induced increase in mitochondrial substrate oxidation from pyruvate and acetyl-CoA-driven lipid synthesis. This could contribute to the prevention of deleterious long-term effects of high fat and sugar intake on hepatic mitochondrial function and insulin sensitivity.

Keywords

Exercise
Mitochondrial supercomplexes
Acetyl-CoA
MAFLD
Lipidomics
Proteomics

Cited by (0)

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Miriam Hoene and Lisa Kappler contributed equally.