Linking bioenergetic function of mitochondria to tissue-specific molecular fingerprints

Mitochondria are dynamic organelles with diverse functions in tissues such as liver and skeletal muscle. To unravel the mitochondrial contribution to tissue-specific physiology, we performed a systematic comparison of the mitochondrial proteome and lipidome of mice and assessed the consequences here...

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Published in:American journal of physiology: endocrinology and metabolism 2019-08, Vol.317 (2), p.E374-E387
Main Authors: Kappler, Lisa, Hoene, Miriam, Hu, Chunxiu, von Toerne, Christine, Li, Jia, Bleher, Daniel, Hoffmann, Christoph, Böhm, Anja, Kollipara, Laxmikanth, Zischka, Hans, Königsrainer, Alfred, Häring, Hans-Ulrich, Peter, Andreas, Xu, Guowang, Sickmann, Albert, Hauck, Stefanie M, Weigert, Cora, Lehmann, Rainer
Format: Article
Language:English
Subjects:
Animals
ATP
ATP synthase
Bioenergetics
Electron transfer
Electron transport chain
Energy Metabolism - physiology
Fatty acids
Female
Gluconeogenesis
Humans
Ketogenesis
Lipids
Liver
Liver - chemistry
Liver - metabolism
Male
Mice
Mice, Inbred C57BL
Mitochondria
Mitochondria - metabolism
Mitochondria, Liver - metabolism
Mitochondria, Muscle - metabolism
Mitochondrial Proteins - analysis
Mitochondrial Proteins - metabolism
Muscle, Skeletal - chemistry
Muscle, Skeletal - metabolism
Muscles
Musculoskeletal system
Organ Specificity
Organelles
Oxidation
Oxidative phosphorylation
Peptide Mapping - methods
Phosphorylation
Protein composition
Proteins
Proteome - analysis
Proteome - metabolism
Proteomics
Pyruvic acid
Quinone oxidoreductase
Quinones
Respiration
Respirometry
Skeletal muscle
Substrate preferences
Substrates
Tissues
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Summary:Mitochondria are dynamic organelles with diverse functions in tissues such as liver and skeletal muscle. To unravel the mitochondrial contribution to tissue-specific physiology, we performed a systematic comparison of the mitochondrial proteome and lipidome of mice and assessed the consequences hereof for respiration. Liver and skeletal muscle mitochondrial protein composition was studied by data-independent ultra-high-performance (UHP)LC-MS/MS-proteomics, and lipid profiles were compared by UHPLC-MS/MS lipidomics. Mitochondrial function was investigated by high-resolution respirometry in samples from mice and humans. Enzymes of pyruvate oxidation as well as several subunits of complex I, III, and ATP synthase were more abundant in muscle mitochondria. Muscle mitochondria were enriched in cardiolipins associated with higher oxidative phosphorylation capacity and flexibility, in particular CL(18:2) and 22:6-containing cardiolipins. In contrast, protein equipment of liver mitochondria indicated a shuttling of complex I substrates toward gluconeogenesis and ketogenesis and a higher preference for electron transfer via the flavoprotein quinone oxidoreductase pathway. Concordantly, muscle and liver mitochondria showed distinct respiratory substrate preferences. Muscle respired significantly more on the complex I substrates pyruvate and glutamate, whereas in liver maximal respiration was supported by complex II substrate succinate. This was a consistent finding in mouse liver and skeletal muscle mitochondria and human samples. Muscle mitochondria are tailored to produce ATP with a high capacity for complex I-linked substrates. Liver mitochondria are more connected to biosynthetic pathways, preferring fatty acids and succinate for oxidation. The physiologic diversity of mitochondria may help to understand tissue-specific disease pathologies and to develop therapies targeting mitochondrial function.
ISSN:0193-1849
1522-1555
DOI:10.1152/ajpendo.00088.2019