MitoSAM-dependent lipoylation controls postnatal heart development via metabolic remodeling
Rumyantseva, A.; Wilhalm, A.; Carter, W.; Tippetts, T. S.; Moedas, M.; Rosenberger, F. A.; Moore, D.; Vegvari, A.; Hinze, Y.; Muellner-Wong, L.; Alsina, D.; Wibom, R.; Winston, R.; Mathews, T. P.; Lund, L. H.; Andersson, D. C.; Pironti, G.; Wedell, A.; DeBerardinis, R. J.; Freyer, C.; Wredenberg, A.
Show abstract
The neonatal heart undergoes a rapid metabolic transition from fetal glycolysis to oxidative phosphorylation, requiring coordinated metabolic remodeling. Mechanisms driving this transition remain unclear. Here, we demonstrate that sufficient mitochondrial S-adenosylmethionine (mitoSAM), imported via the solute carrier Slc25a26, is essential for this shift by sustaining the lipoylation of 2-oxoacid dehydrogenases, critical for TCA cycle activation. Proteomic and metabolomic profiling revealed that reduced mitoSAM availability impaired lipoylation, blocking TCA cycle function and restricting nucleotide synthesis, while mitochondrial gene expression and respiratory capacity remained largely intact. In vivo EdU labeling showed persistent cardiomyocyte proliferation imposing further strain on nucleotide pools. Supplementation with medium-chain triglycerides during the suckling-to-weaning transition restored metabolic function and normalized cardiac growth and morphology. Our data reveal a critical developmental window in which mitoSAM-dependent lipoylation ensures heart maturation.
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