Carnitine Acetyltransferase Mitigates Metabolic Inertia and Muscle Fatigue during Exercise

S.E. Seiler; T. R. Koves; J.R. Gooding; K.E. Wong; R.D. Stevens; O.R. Ilkayeva; A.H. Wittmann; K. L. Debalsi; M.N. Davies; L. Lindeboom; P. Schrauwen; V.B. Schrauwen-Hinderling; D. M. Muoio

doi:10.1016/j.cmet.2015.06.003

Carnitine Acetyltransferase Mitigates Metabolic Inertia and Muscle Fatigue during Exercise

S.E. Seiler, T. R. Koves, J.R. Gooding, K.E. Wong, R.D. Stevens, O.R. Ilkayeva, A.H. Wittmann, K. L. Debalsi, M.N. Davies, L. Lindeboom, P. Schrauwen, V.B. Schrauwen-Hinderling, D. M. Muoio^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Acylcarnitine metabolites have gained attention as biomarkers of nutrient stress, but their physiological relevance and metabolic purpose remain poorly understood. Short-chain carnitine conjugates, including acetylcarnitine, derive from their corresponding acyl-CoA precursors via the action of carnitine acetyltransferase (CrAT), a bidirectional mitochondrial matrix enzyme. We show here that contractile activity reverses acetylcarnitine flux in muscle, from net production and efflux at rest to net uptake and consumption during exercise. Disruption of this switch in mice with muscle-specific CrAT deficiency resulted in acetyl-CoA deficit, perturbed energy charge, and diminished exercise tolerance, whereas acetylcarnitine supplementation produced opposite outcomes in a CrAT-dependent manner. Likewise, in exercise-trained compared to untrained humans, post-exercise phosphocreatine recovery rates were positively associated with CrAT activity and coincided with dramatic shifts in muscle acetylcarnitine dynamics. These findings show acetylcarnitine serves as a critical acetyl buffer for working muscles and provide insight into potential therapeutic strategies for combatting exercise intolerance.

Original language	English
Pages (from-to)	65-76
Number of pages	12
Journal	Cell Metabolism
Volume	22
Issue number	1
DOIs	https://doi.org/10.1016/j.cmet.2015.06.003
Publication status	Published - 7 Jul 2015

Keywords

HUMAN SKELETAL-MUSCLE
PYRUVATE-DEHYDROGENASE COMPLEX
DICHLOROACETATE
ACETYLCARNITINE
ONSET
MICE
ACCUMULATION
PERFORMANCE

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Seiler, S. E., Koves, T. R., Gooding, J. R., Wong, K. E., Stevens, R. D., Ilkayeva, O. R., Wittmann, A. H., Debalsi, K. L., Davies, M. N., Lindeboom, L., Schrauwen, P., Schrauwen-Hinderling, V. B., & Muoio, D. M. (2015). Carnitine Acetyltransferase Mitigates Metabolic Inertia and Muscle Fatigue during Exercise. Cell Metabolism, 22(1), 65-76. https://doi.org/10.1016/j.cmet.2015.06.003

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abstract = "Acylcarnitine metabolites have gained attention as biomarkers of nutrient stress, but their physiological relevance and metabolic purpose remain poorly understood. Short-chain carnitine conjugates, including acetylcarnitine, derive from their corresponding acyl-CoA precursors via the action of carnitine acetyltransferase (CrAT), a bidirectional mitochondrial matrix enzyme. We show here that contractile activity reverses acetylcarnitine flux in muscle, from net production and efflux at rest to net uptake and consumption during exercise. Disruption of this switch in mice with muscle-specific CrAT deficiency resulted in acetyl-CoA deficit, perturbed energy charge, and diminished exercise tolerance, whereas acetylcarnitine supplementation produced opposite outcomes in a CrAT-dependent manner. Likewise, in exercise-trained compared to untrained humans, post-exercise phosphocreatine recovery rates were positively associated with CrAT activity and coincided with dramatic shifts in muscle acetylcarnitine dynamics. These findings show acetylcarnitine serves as a critical acetyl buffer for working muscles and provide insight into potential therapeutic strategies for combatting exercise intolerance.",

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AU - Seiler, S.E.

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AU - Wong, K.E.

AU - Stevens, R.D.

AU - Ilkayeva, O.R.

AU - Wittmann, A.H.

AU - Debalsi, K. L.

AU - Davies, M.N.

AU - Lindeboom, L.

AU - Schrauwen, P.

AU - Schrauwen-Hinderling, V.B.

AU - Muoio, D. M.

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AB - Acylcarnitine metabolites have gained attention as biomarkers of nutrient stress, but their physiological relevance and metabolic purpose remain poorly understood. Short-chain carnitine conjugates, including acetylcarnitine, derive from their corresponding acyl-CoA precursors via the action of carnitine acetyltransferase (CrAT), a bidirectional mitochondrial matrix enzyme. We show here that contractile activity reverses acetylcarnitine flux in muscle, from net production and efflux at rest to net uptake and consumption during exercise. Disruption of this switch in mice with muscle-specific CrAT deficiency resulted in acetyl-CoA deficit, perturbed energy charge, and diminished exercise tolerance, whereas acetylcarnitine supplementation produced opposite outcomes in a CrAT-dependent manner. Likewise, in exercise-trained compared to untrained humans, post-exercise phosphocreatine recovery rates were positively associated with CrAT activity and coincided with dramatic shifts in muscle acetylcarnitine dynamics. These findings show acetylcarnitine serves as a critical acetyl buffer for working muscles and provide insight into potential therapeutic strategies for combatting exercise intolerance.

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