Abstract
Hypermetabolism, a futile cycle of energy production and consumption, has been proposed as an adaptative response to deficiencies in mitochondrial oxidative phosphorylation. However, the cellular costs of hypermetabolism remain largely unknown. Here we studied the consequences of hypermetabolism in human motor neurons harboring a heteroplasmic mutation in MT-ATP6, which impairs ATP synthase assembly. Respirometry, metabolomics, and proteomics analyses of the motor neurons showed that elevated ATP production rates were accompanied with increased demand for acetyl-Coenzyme A (acetyl-CoA) and depleted pantothenate (vitamin B5), and the proteome was remodeled to support the metabolic adaptation. Mitochondrial membrane potential and coupling efficiency remained stable, and the therapeutic agent avanafil did not affect metabolite levels. However, a redistribution of acetyl-CoA usage resulted in metabolic trade-offs, including reduced histone acetylation and altered maintenance of the neurotransmitter acetylcholine, revealing potential vulnerabilities in motor neurons. These findings advance the understanding of cellular metabolic consequences imposed by hypermetabolic conditions.