Lipidomics unveils lipid dyshomeostasis and low circulating plasmalogens as biomarkers in a monogenic mitochondrial disorder
Matthieu Ruiz, Alexanne Cuillerier, Caroline Daneault, Sonia Deschênes, Isabelle Robillard Frayne, Bertrand Bouchard, Anik Forest, Julie Thompson Legault, The LSFC Consortium, Frederic M. Vaz, John D. Rioux, Yan Burelle, Christine Des Rosiers
Matthieu Ruiz, Alexanne Cuillerier, Caroline Daneault, Sonia Deschênes, Isabelle Robillard Frayne, Bertrand Bouchard, Anik Forest, Julie Thompson Legault, The LSFC Consortium, Frederic M. Vaz, John D. Rioux, Yan Burelle, Christine Des Rosiers
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Research Article Cell biology Metabolism

Lipidomics unveils lipid dyshomeostasis and low circulating plasmalogens as biomarkers in a monogenic mitochondrial disorder

Abstract

Mitochondrial dysfunction characterizes many rare and common age-associated diseases. The biochemical consequences, underlying clinical manifestations, and potential therapeutic targets, remain to be better understood. We tested the hypothesis that lipid dyshomeostasis in mitochondrial disorders goes beyond mitochondrial fatty acid β-oxidation, particularly in liver. This was achieved using comprehensive untargeted and targeted lipidomics in a case-control cohort of patients with Leigh syndrome French-Canadian variant (LSFC), a mitochondrial disease caused by mutations in LRPPRC, and in mice harboring liver-specific inactivation of Lrpprc (H-Lrpprc–/–). We discovered a plasma lipid signature discriminating LSFC patients from controls encompassing lower levels of plasmalogens and conjugated bile acids, which suggest perturbations in peroxisomal lipid metabolism. This premise was reinforced in H-Lrpprc–/– mice, which compared with littermates recapitulated a similar, albeit stronger peroxisomal metabolic signature in plasma and liver including elevated levels of very-long-chain acylcarnitines. These mice also presented higher transcript levels for hepatic markers of peroxisome proliferation in addition to lipid remodeling reminiscent of nonalcoholic fatty liver diseases. Our study underscores the value of lipidomics to unveil unexpected mechanisms underlying lipid dyshomeostasis ensuing from mitochondrial dysfunction herein implying peroxisomes and liver, which likely contribute to the pathophysiology of LSFC, but also other rare and common mitochondrial diseases.

Authors

Matthieu Ruiz, Alexanne Cuillerier, Caroline Daneault, Sonia Deschênes, Isabelle Robillard Frayne, Bertrand Bouchard, Anik Forest, Julie Thompson Legault, The LSFC Consortium, Frederic M. Vaz, John D. Rioux, Yan Burelle, Christine Des Rosiers

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Figure 7

Mitochondrial and peroxisomal pathway contribution to the lipidomic signature observed in LSFC patients and in H-Lrpprc–/– mice.

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Mitochondrial and peroxisomal pathway contribution to the lipidomic sign...
This schematic depicts the metabolic pathways in mitochondria (in blue) and peroxisomes (in green) that are related to the lipid perturbations reported in this study (increased or decreased levels, as indicated by upward or downward arrows, respectively) in plasma and/or liver (the green star indicates changes in liver only). The lightning bolt indicates the proposed sites of pathway perturbations. Beyond OXPHOS deficiency, LRPPRC-dependent mitochondrial dysfunction results in major perturbations of lipid metabolism. Here we confirm and extend our previous observations of an important dysregulation of mitochondrial FA β-oxidation (12, 15), as suggested by the accumulation of ACs of various chain length, especially LCACs, MCACs, and hydroxylated ACs. This dysregulation is likely to result in cytosolic FA overflow, which favors tissue triglyceride (TG) accumulation, but also FA elongation, which in turn promotes the synthesis of VLCFAs, which are substrates for peroxisomal β-oxidation (shown in green). The accumulation in VLCACs in liver tissues suggests, however, a mismatch between VLCFA formation and their peroxisomal oxidation, which may be reduced as suggested by decreased Acox1 (downward red arrow) expression in liver. The presence of additional perturbations in peroxisomal metabolism is also reflected by changes in livers and plasma of (i) odd-numbered carbon chain ACs (increased), which may result from impaired phytanic acid oxidation, as well as (ii) lower levels of DHA and conjugated bile acids. Lastly, this is also reflected by the lower circulating levels of plasmalogens, which may exert a positive feedback (red dashed arrow) on Far1 expression (upward red arrow), and thereby result in enhanced hepatic plasmalogen biosynthesis (suggested by higher Agps expression; upward red arrow) and tissue levels.