Mitochondrial bioenergetics and cardiolipin remodeling abnormalities in mitochondrial trifunctional protein deficiency
Eduardo Vieira Neto, Meicheng Wang, Austin J. Szuminsky, Lethicia Ferraro, Erik Koppes, Yudong Wang, Clinton Van’t Land, Al-Walid Mohsen, Geancarlo Zanatta, Areeg H. El-Gharbawy, Tamil S. Anthonymuthu, Yulia Y. Tyurina, Vladimir A. Tyurin, Valerian Kagan, Hülya Bayır, Jerry Vockley
Eduardo Vieira Neto, Meicheng Wang, Austin J. Szuminsky, Lethicia Ferraro, Erik Koppes, Yudong Wang, Clinton Van’t Land, Al-Walid Mohsen, Geancarlo Zanatta, Areeg H. El-Gharbawy, Tamil S. Anthonymuthu, Yulia Y. Tyurina, Vladimir A. Tyurin, Valerian Kagan, Hülya Bayır, Jerry Vockley
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Research Article Genetics Metabolism

Mitochondrial bioenergetics and cardiolipin remodeling abnormalities in mitochondrial trifunctional protein deficiency

Abstract

Mitochondrial trifunctional protein (TFP) deficiency is an inherited metabolic disorder leading to a block in long-chain fatty acid β-oxidation. Mutations in HADHA and HADHB, which encode the TFP α and β subunits, respectively, usually result in combined TFP deficiency. A single common mutation, HADHA c.1528G>C (p.E510Q), leads to isolated 3-hydroxyacyl-CoA dehydrogenase deficiency. TFP also catalyzes a step in the remodeling of cardiolipin (CL), a phospholipid critical to mitochondrial membrane stability and function. We explored the effect of mutations in TFP subunits on CL and other phospholipid content and composition and the consequences of these changes on mitochondrial bioenergetics in patient-derived fibroblasts. Abnormalities in these parameters varied extensively among different fibroblasts, and some cells were able to maintain basal oxygen consumption rates similar to controls. Although CL reduction was universally identified, a simultaneous increase in monolysocardiolipins was discrepant among cells. A similar profile was seen in liver mitochondria isolates from a TFP-deficient mouse model. Response to new potential drugs targeting CL metabolism might be dependent on patient genotype.

Authors

Eduardo Vieira Neto, Meicheng Wang, Austin J. Szuminsky, Lethicia Ferraro, Erik Koppes, Yudong Wang, Clinton Van’t Land, Al-Walid Mohsen, Geancarlo Zanatta, Areeg H. El-Gharbawy, Tamil S. Anthonymuthu, Yulia Y. Tyurina, Vladimir A. Tyurin, Valerian Kagan, Hülya Bayır, Jerry Vockley

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Figure 1

Ribbon and stick representation of part of the TFP-LCHAD active site highlighting residues predicted to play role in catalysis and substrate binding and activation.

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Ribbon and stick representation of part of the TFP-LCHAD active site hig...
(A) Illustration of the triad αH498-αGlu510-αT547 of the native protein active site where the αGlu510 carboxylate is anchored to the peptide backbone through a hydrogen bond between αT547 backbone amide NH and αGlu510 Oε1. The carboxylate Oε2 is at an interacting distance to αH498 Nε1 hydrogen and the αT547 hydroxyl. (B) Illustration of the E510Q mutant protein showing how mutant αGln510 Nε1 can render the αH498 imidazole inert. Atomic coordinates used in this modeling according to Xia et al. (9) 6DV2.pdb. Carbon residues are depicted in green, oxygen in red, nitrogen in blue, and hydrogen in white.