Kristofer S. Fritz scite author profile

The non-enzymatic free radical generation of reactive aldehydes is known to contribute to diseases of sustained oxidative stress including rheumatoid arthritis, atherosclerosis, neurodegenerative and a number of liver diseases. At the same time, the accumulation of lipid electrophiles has been demonstrated to play a role in cell signaling events through modification of proteins critical for cellular homeostasis. Given the broad scope of reactivity profiles and the ability to modify numerous proteomic and genomic processes, new emphasis is being placed on a systems-based analysis of the consequences of electrophilic adduction. This review focuses on the generation and chemical reactivity of lipid-derived aldehydes with a special focus on the homeostatic responses to electrophilic stress.

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The human sirtuin family: Evolutionary divergences and functions

Vassilopoulos

et al. 2011

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The sirtuin family of proteins is categorised as class III histone deacetylases that play complex and important roles in ageing-related pathological conditions such as cancer and the deregulation of metabolism. There are seven members in humans, divided into four classes, and evolutionarily conserved orthologues can be found in most forms of life, including both eukaryotes and prokaryotes. The highly conserved catalytic core domain composed of a large oxidised nicotinamide adenine dinucleotide (NAD+)-binding Rossmann fold subunit suggests that these proteins belong to a family of nutrient-sensing regulators. Along with their function in regulating cellular metabolism in response to stressful conditions, they are implicated in modifying a wide variety of substrates; this increases the complexity of unravelling the interplay of sirtuins and their partners. Over the past few years, all of these new findings have attracted the interest of researchers exploring potential therapeutic implications related to the function of sirtuins. It remains to be elucidated whether, indeed, sirtuins can serve as molecular targets for the treatment of human illnesses.

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4-Hydroxynonenal Inhibits SIRT3 via Thiol-Specific Modification

Fritz¹,

Galligan²,

Smathers³

et al. 2011

Chem. Res. Toxicol.

114

104

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4-Hydroxynonenal (4-HNE) is an endogenous product of lipid peroxidation known to play a role in cellular signaling through protein modification and is a major precursor for protein carbonyl adducts found in alcoholic liver disease (ALD). In the present study, a greater than 2-fold increase in protein carbonylation of sirtuin 3 (SIRT3), a mitochondrial class III histone deacetylase, is reported in liver mitochondrial extracts of ethanol consuming mice. The consequence of this in vivo carbonylation on SIRT3 deacetylase activity is unknown. Interestingly, mitochondrial protein hyperacetylation was observed in a time-dependent increase in a model of chronic ethanol consumption; however, the underlying mechanisms for this remain unknown. Tandem mass spectrometry was used to identify and characterize the in vitro covalent modification of rSIRT3 by 4-HNE at Cys280, a critical zinc-binding residue, and the resulting inhibition of rSIRT3 activity via pathophysiologically relevant concentrations of 4-HNE. Computational-based molecular modeling simulations indicate that 4-HNE modification alters the conformation of the zinc-binding domain inducing minor changes within the active site, resulting in the allosteric inhibition of SIRT3 activity. These conformational data are supported by the calculated binding energies derived from molecular docking studies suggesting the substrate peptide of acetyl-CoA synthetase 2 (AceCS2-Kac), displays a greater affinity for native SIRT3 compared with the 4-HNE adducted protein. The results of this study characterize altered mitochondrial protein acetylation in a mouse model of chronic ethanol ingestion and thiol-specific allosteric inhibition of rSIRT3 resulting from 4-HNE adduction.

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Mitochondrial Acetylome Analysis in a Mouse Model of Alcohol-Induced Liver Injury Utilizing SIRT3 Knockout Mice

et al. 2012

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Mitochondrial protein hyperacetylation is a known consequence of sustained ethanol consumption and has been proposed to play a role in the pathogenesis of alcoholic liver disease (ALD). The mechanisms underlying this altered acetylome, however, remain unknown. The mitochondrial deacetylase sirtuin 3 (SIRT3) is reported to be the major regulator of mitochondrial protein deacetylation and remains a central focus for studies on protein acetylation. To investigate the mechanisms underlying ethanol-induced mitochondrial acetylation, we employed a model for ALD in both wild-type (WT) and SIRT3 knockout (KO) mice using a proteomics and bioinformatics approach. Here, WT and SIRT3 KO groups were compared in a mouse model of chronic ethanol consumption, revealing pathways relevant to ALD, including lipid and fatty acid metabolism, antioxidant response, amino acid biosynthesis and the electron-transport chain, each displaying proteins with altered acetylation. Interestingly, protein hyperacetylation resulting from ethanol consumption and SIRT3 ablation suggests ethanol-induced hyperacetylation targets numerous biological processes within the mitochondria, the majority of which are known to be acetylated through SIRT3-dependent mechanisms. These findings reveal overall increases in 91 mitochondrial targets for protein acetylation, identifying numerous critical metabolic and antioxidant pathways associated with ALD, suggesting an important role for mitochondrial protein acetylation in the pathogenesis of ALD.

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