Project description:A double knockout (DKO) mouse model harboring muscle-specific deficits in acetyl CoA buffering by carnitine acetyltransferase (CrAT), and lysine deacetylation by SIRT3, resulted in additive hyperacetylation of the mitochondrial proteome, which was augmented exponentially by chronic high fat feeding. Whereas DKO mice developed a more severe form of diet-induced insulin resistance than either single KO mouse line, the functional profiles of hyperacetylated mitochondria were largely negative. Of the >120 measures of respiratory kinetics and thermodynamics assayed in DKO skeletal muscle mitochondria, the most consistently observed traits of a markedly heightened acetyl-lysine landscape were enhanced oxygen flux in the context of a long chain fatty acid fuel, and elevated rates of complex I-dependent electron leak. In sum, the findings challenge the notion that lysine acetylation causes broad-ranging damage to mitochondrial quality and performance, and raise the possibility that acetyl-lysine turnover, rather than acetyl-lysine stoichiometry, modulates redox balance and carbon flux.

Project description:Circumstantial evidence links the development of heart failure to perturbations in oxidative metabolism and corresponding shifts in post-translational modifications (PTMs) of mitochondrial proteins, including lysine acetylation (Kac). Nonetheless, direct evidence that acetyl-PTMs compromise mitochondrial performance remains sparse. Here, we used a respiratory diagnostics platform and serial assessment of cardiac phenotype to evaluate functional consequences of mitochondrial hyperacetylation caused by cardiac deficiency of carnitine acetyltransferase (CrAT) and sirtuin 3 (Sirt3); enzymes that oppose Kac by buffering the acetyl CoA pool and catalyzing lysine deacetylation, respectively. Although the dual knockout (DKO) manipulation raised the cardiac acetyl-lysine landscape well beyond that observed in response to Sirt3 deficiency or pathophysiological heart remodeling, bioenergetics of DKO mitochondria were remarkably normal. Moreover, DKO hearts were not more vulnerable to pressure overload-induced dysfunction resulting from chronic transaortic constriction. The findings challenge the premise that hyperacetylation per se threatens metabolic resilience by causing broad-ranging damage to mitochondrial proteins. See Davidson et. al. 2019 for further experimental details, reagents, and references.

Project description:Nicotinamide riboside supplements (NRS) have been touted as a nutraceutical that promotes cardiometabolic and musculoskeletal health by enhancing nicotinamide adenine dinucleotide (NAD+) biosynthesis, mitochondrial function and/or the activities of NAD-dependent sirtuin deacetylase enzymes. This investigation examined the impact of NRS on whole body energy homeostasis, skeletal muscle mitochondrial function, and corresponding shifts in the acetyl-lysine proteome, in the context of diet-induced obesity using C57BL/6NJ mice. The study also included a genetically-modified mouse model that imposes greater demand on sirtuin flux and associated NAD+ consumption, specifically within muscle tissues. In general, whole body glucose control was modestly improved by NRS when administered at the midpoint of a chronic high fat diet, but not when given as a preventative therapy upon initiation of the diet. Contrary to anticipated outcomes, the study produced little evidence that NRS increases tissue NAD+ levels, augments mitochondrial function and/or mitigates diet-induced hyperacetylation of the skeletal muscle proteome.

Project description:Tumor cells exhibit aberrant metabolism characterized by high glycolysis even in the presence of oxygen. This metabolic reprogramming, known as the Warburg effect, provides tumor cells with the substrates and redox potential required for the generation of biomass. Here, we show that the mitochondrial NAD-dependent deacetylase SIRT3 is a crucial regulator of the Warburg effect. SIRT3 loss promotes a metabolic profile consistent with high glycolysis required for anabolic processes in vivo and in vitro. Mechanistically, SIRT3 mediates metabolic reprogramming independently of mitochondrial oxidative metabolism and through HIF1a, a transcription factor that controls expression of key glycolytic enzymes. SIRT3 loss increases reactive oxygen species production, resulting in enhanced HIF1a stabilization. Strikingly, SIRT3 is deleted in 40% of human breast cancers, and its loss correlates with the upregulation of HIF1a target genes. Finally, we find that SIRT3 overexpression directly represses the Warburg effect in breast cancer cells. In sum, we identify SIRT3 as a regulator of HIF1a and a suppressor of the Warburg effect. RNA isolated from brown adipose tissue of SIRT3 WT and KO mice. 5 wild-type samples and 5 SIRT3 KO samples

Project description:Mitochondrial dysfunction is one of many key factors in the etiology of alcoholic liver disease (ALD). Lysine acetylation is known to regulate numerous mitochondrial metabolic pathways and recent reports demonstrate that alcohol-induced protein acylation negatively impacts these processes. To identify regulatory mechanisms attributed to alcohol-induced protein post-translational modifications, we employed a model of alcohol consumption within the context of wild type (WT), sirtuin 3 knockout (SIRT3 KO), and sirtuin 5 knockout(SIRT5 KO) mice to manipulate hepatic mitochondrial protein acylation. Mitochondrial fractions were examined by label-free quantitative HPLC-MS/MS to reveal competition between lysine acetylation and succinylation. A class of proteins defined as “differential acyl switching proteins” demonstrate select sensitivity to alcohol-induced protein acylation. A number of these proteins reveal saturated lysine-site occupancy, suggesting a significant level of differential stoichiometry in the setting of ethanol consumption. We hypothesize that ethanol downregulates numerous mitochondrial metabolic pathways through differential acyl switching proteins.

Project description:Martin et al. JCI Insigh (2017). Increasing NAD+ levels by supplementing with the precursor nicotinamide mononucleotide (NMN) improves cardiac function in multiple mouse models of disease. While NMN influences several aspects of mitochondrial metabolism, the molecular mechanisms by which increased NAD+ enhances cardiac function are poorly understood. A putative mechanism of NAD+ therapeutic action is via activation of the mitochondrial NAD+-dependent protein deacetylase sirtuin 3 (SIRT3). We assessed the therapeutic efficacy of NMN and the role of SIRT3 in the Friedreich’s Ataxia cardiomyopathy mouse model (FXNKO). At baseline, the FXNKO heart has mitochondrial protein hyperacetylation, reduced Sirt3 mRNA expression, and evidence of increased NAD+ salvage. Remarkably, NMN administered to FXNKO mice restores cardiac function to near-normal levels. To determine whether SIRT3 is required for NMN therapeutic efficacy, we generated SIRT3KO and SIRT3KO/FXNKO (dKO) knockout models. The improvement in cardiac function upon NMN treatment in the FXNKO is lost in the dKO model, demonstrating that the effects of NMN are dependent upon cardiac SIRT3. Coupled with cardio- protection, SIRT3 mediates NMN-induced improvements in both cardiac and extra-cardiac metabolic function and energy metabolism. Taken together, these results serve as important preclinical data for NMN supplementation or SIRT3 activator therapy in Friedreich’s Ataxia patients.

Project description:Sirtuin 3 (SIRT3) is an NAD+-dependent deacetylase involved in various physiological and pathological processes. However, the role of SIRT3 in regulating human stem cell senescence remains largely unknown. Here, we observed the downregulated expression of SIRT3 in senescent human mesenchymal stem cells (hMSCs). SIRT3 deficiency accelerated cellular senescence in hMSCs, along with compromised nuclear integrity, loss of heterochromatin and increased DNA damage. These aging-associated nuclear defects were attenuated by the reintroduction of SIRT3. Mechanistic studies demonstrated the interaction of SIRT3 with nuclear envelope proteins and heterochromatin-associated proteins. Further findings revealed that SIRT3 deficiency led to the loss of lamina-associated domains (LADs) from the nuclear lamina, increased chromatin accessibility and aberrant transcription of repetitive sequences. Meanwhile, the overexpression of nuclear-localized SIRT3 rescued the senescence phenotypes. Taken together, our study reveals a novel role of nuclear SIRT3 in stabilizing heterochromatin and counteracting hMSC senescence, which may provide new clinical therapeutic targets to ameliorate aging-related diseases.

Project description:SIRT3 has been shown to inhibit HCMV infection, but the mechanism under the antiviral effect is not clear. To identify the mediator of SIRT3 antiviral function, we aim to identify and quantify SIRT3 interactions during HCMV infection. A set of large-scale IPs were performed to determine the specific interactions with SIRT3 during infection, while small-scale IPs were conducted to determine the temporal interactions over the life cycle of infection. The mitochondrial proteome was used to characterize the changes of protein abundances after infection, and it was used for the normalization of acetylation.

Project description:In this project, the protein acetylation levels in human platelets and in WT and SIRT3-/- mouse platelets during storage were examined.

Project description:The dysregulated energy metabolism of glioblastoma cells is a critical factor in tumor development and progression. Lysine acetylation, regulated by the mitochondrial enzyme SIRT3, is known to play a key role in the metabolic phenotype of glioblastoma. To better understand how SIRT3 regulates mitochondrial metabolism, we inhibited SIRT3 and examined the proteome and acetylome of two glioblastoma cell lines with different metabolic preferences. Our results indicate that protein synthesis machineries are regulated by lysine acetylation and play a role in the metabolic phenotype. We also identified new SIRT3 targets that have not been previously associated with specific functions, highlighting their potential as future targets for further study. These findings enhance our understanding of the complex regulation of energy metabolism in glioblastoma and provide potential targets for future therapies.