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Abstract
Mitochondrial lysine acetylation regulates several metabolic pathways in cardiac cells. The current study investigated whether GCN5L1-mediated lysine acetylation regulates cardiac mitochondrial metabolic proteins in response to a high fat diet (HFD). GCN5L1 cardiac-specific knockout (cKO) mice showed significantly reduced mitochondrial protein acetylation following a HFD relative to wildtype (WT) mice. GCN5L1 cKO mice did not display any decrease in ex vivo cardiac workload in response to a HFD. In contrast, ex vivo cardiac function in HFD-fed WT mice dropped ~ 50% relative to low fat diet (LFD) fed controls. The acetylation status of electron transport chain Complex I protein NDUFB8 was significantly increased in WT mice fed a HFD, but remained unchanged in GCN5L1 cKO mice relative to LFD controls. Finally, we observed that inhibitory acetylation of superoxide dismutase 2 (SOD2) at K122 was increased in WT (but not cKO mice) on a HFD. This correlated with significantly increased cardiac lipid peroxidation in HFD-fed WT mice relative to GCN5L1 cKO animals under the same conditions. We conclude that increased GCN5L1 expression in response to a HFD promotes increased lysine acetylation, and that this may play a role in the development of reactive oxygen species (ROS) damage caused by nutrient excess.
Highlights
Mitochondrial lysine acetylation regulates several metabolic pathways in cardiac cells
To investigate a role for GCN5L1 in this process in vivo, we first examined the total level of mitochondrial protein acetylation in WT and GCN5L1 cardiac-specific knockout (cKO) mouse hearts under low fat diet (LFD) and high fat diet (HFD)
Using a HFD feeding model combined with cardiac-specific deletion of GCN5L1, we demonstrate for the first time in vivo that GCN5L1 mediates the acetylation of NDUFB8 (ETC Complex I) and superoxide dismutase 2 (SOD2) (ROS amelioration) in response to nutrient excess
Summary
Mitochondrial lysine acetylation regulates several metabolic pathways in cardiac cells. The current study investigated whether GCN5L1-mediated lysine acetylation regulates cardiac mitochondrial metabolic proteins in response to a high fat diet (HFD). The acetylation status of electron transport chain Complex I protein NDUFB8 was significantly increased in WT mice fed a HFD, but remained unchanged in GCN5L1 cKO mice relative to LFD controls. We observed that inhibitory acetylation of superoxide dismutase 2 (SOD2) at K122 was increased in WT (but not cKO mice) on a HFD This correlated with significantly increased cardiac lipid peroxidation in HFD-fed WT mice relative to GCN5L1 cKO animals under the same conditions. GCN5L1 expression is necessary for the acetylation of the ETC Complex I protein NDUFB8, as well as inhibitory acetylation of mitochondrial superoxide dismutase 2 (SOD2) at K122 under HFD conditions This results in decreased lipid peroxidation in GCN5L1 cKO mice, relative to wildtype animals, following. These data indicate that the acetylation of cardiac mitochondrial proteins by GCN5L1 under HFD conditions may lead to cardiac dysfunction, as a downstream consequence of increased cellular damage from lipid peroxidation
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