OPA1 affects lipid metabolism and atherosclerosis progression

Abstract

Abstract Funding Acknowledgements Type of funding sources: Foundation. Main funding source(s): European Atherosclerosis Society Introduction Mitochondria are involved in cellular metabolism, energy generation, calcium homeostasis, sterol and bile acids (BAs) production. Mitochondria continuously undergo biogenesis, fusion, fission and mitophagy, maintaining a continuous balance between all forms. Purpose On these premises, we test the impact of OPA1, an inner mitochondria membrane fusion protein, on mitochondrial tethering on lipid metabolism in the liver and the atherosclerotic plaque. Methods OPA1HepKO and OPA1 TG on LDLR KO background were fed with a Western-type diet (WTD) respectively for 12 weeks. Inverse calorimetry, GTT, and LipidToleranceTest (LTT) were performed. Paraffin-embedded tissues were used for histological analysis, frozen tissues were used for OMICs analysis. VSMCs were isolated and cultured with VLDL (50 µg/ml). Results While OPA1HepKO mice display altered systemic metabolism with reduced body weight and reduced circulating lipid levels OPA1 overexpression on LDLR KO background showed significantly high cholesterol levels. OPA1 deficiency impair hepatic bile acid conjugation with significant accumulation of primary unconjugated bile acids in the liver. On the contrary OPA1 overexpression leads to a reduction of unconjugated bile acids and higher percentage of conjugated bile acids. OPA1 reduction leads to a reduced atherosclerotic plaque while, on the contrary, its overexpression doesn’t affect atherosclerosis despite an increase in circulating lipid and lipoprotein levels. OPA1 overexpression is therefore promoting plaque stabilization with VSMCs that are less prone to change their metabolism to synthetic. Conclusion Hepatic Opa1 deficiency alters bile acids production and therefore circulating lipid profile with a consequent reduction in atherosclerotic plaque formation. OPA1 overexpression in the aorta affects plaque stability despite the highest levels of circulating lipids.