Project description:Strong associations exist between branched chain amino acids (BCAA) and dysregulated glucose and lipid metabolism, but the underlying mechanisms are not well understood. Here we report that inhibition of the kinase (BDK) or overexpression of the phosphatase (PPM1K) that regulate branched-chain ketoacid dehydrogenase (BCKDH), the committed step of BCAA catabolism, lowers circulating BCAA, reduces hepatic steatosis and improves glucose tolerance in the absence of weight loss in Zucker fatty rats. Phosphoproteomics analysis identified ATP-citrate lyase (ACL) as an alternate substrate of BDK and PPM1K. Overexpression of BDK in liver of lean rats increased ACL phosphorylation and activated de novo lipogenesis. Moreover, BDK and PPM1K transcript levels were increased and repressed, respectively, in response to fructose feeding and expression of the ChREBP transcription factor. These studies identify BDK and PPM1K as a regulatory node that integrates BCAA, glucose, and lipid metabolism via reciprocal regulation of BCKDH and ACL. Modulation of this node relieves key disease phenotypes in a genetic model of severe obesity and metabolic dysfunction.

Project description:Histone acetylation is an important, reversible posttranslational protein modification and hallmark of epigenetic regulation. However, little is known about the dynamics of reversible hisotne acetylation, due to the lack of analytical methods that can capture site-specific acetylation and deacetylation reactions. We present a new approach that combines metabolic and chemical labeling (CoMetChem) using uniformly 13C-labeled glucose and stable isotope labeled acetic anhydride, which allows to quantify site-specific lysine acetylation dynamics in tryptic peptides using high-resolution mass spectrometry.

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:From Peterson et. al. 2018: SIRT3 is an NAD+-dependent mitochondrial protein deacetylase purported to influence metabolism through post-translational modification of metabolic enzymes. Fuel-stimulated insulin secretion, which involves mitochondrial metabolism, could be susceptible to SIRT3-mediated effects. We used CRISPR/Cas9 technology to manipulate SIRT3 expression in b-cells, resulting in wide-spread, SIRT3dependent changes in acetylation of key metabolic enzymes, but with no appreciable changes in glucose- or pyruvate-stimulated insulin secretion, or in metabolomic profile during glucose stimulation. Moreover, these broad changes in the SIRT3-targeted acetylproteome did not affect responses to nutritional or ER stress conditions. We also studied mice with global SIRT3 knockout fed either standard chow (STD) or high- fat/high-sucrose (HFHS) diets. Only when chronically fed a HFHS diet do SIRT3 KO animals exhibit a modest reduction in insulin secretion. We conclude that broad changes in mitochondrial protein acetylation in response to manipulation of SIRT3 are not sufficient to cause changes in islet function or metabolism.

Project description:Acetate, propionate and butyrate are the main short-chain fatty acids (SCFAs) that arise from the fermentation of fibers by the colonic microbiota. While many studies focus on the regulatory role of SCFAs, their quantitative role as a catabolic or anabolic substrate for the host has received relatively little attention. To investigate this aspect, we infused conscious mice with physiological quantities of stable isotopes [1-13C]acetate, [2-13C]propionate or [2,4-13C2]butyrate directly into the cecum, which is the natural production site in mice, and analyzed their interconversion by the microbiota as well as their metabolism by the host. Cecal interconversion - pointing to microbial cross-feeding - was high between acetate and butyrate, low between butyrate and propionate and almost absent between acetate and propionate. As much as 62% of infused propionate was used in whole-body glucose production, in line with its role as gluconeogenic substrate. Conversely, glucose synthesis from propionate accounted for 69% of total glucose production. The synthesis of palmitate and cholesterol in the liver was high from cecal acetate (2.8% and 0.7%, respectively) and butyrate (2.7% and 0.9%, respectively) as substrates, but low or absent from propionate (0.6% and 0.0%, respectively). Label incorporation due to chain elongation of stearate was approximately 8-fold higher than de novo synthesis of stearate. Microarray data suggested that SCFAs exert only a mild regulatory effect on the expression of genes involved in hepatic metabolic pathways during the 6h infusion period. Altogether, gut-derived acetate, propionate and butyrate play important roles as substrates for glucose, cholesterol and lipid metabolism. Mice were infused in cecum with stably-labelled isotopes of the three main short chain fatty acids or control solution. After 6 hrs, livers were removed and pooled RNA samples were subjected to gene expression profiling.

Project description:Macrophages are phagocytic cells in the innate immune system that infiltrate into resident tissues and subsequently polarize into at least two classical phenotypes: ‘pro-inflammatory’ M1 and ‘anti-inflammatory’ M2. Aberrant polarization can aggravate the pathophysiology of infectious diseases such as tuberculosis. Understanding the mechanisms that influence macrophage biology can lead to pharmacological control of polarization. We have developed a novel triomics approach utilizing liquid chromatography-tandem mass spectrometry (LC-MS/MS) to perform simultaneous analysis of metabolites, proteins, and histone modifications. Using human blood derived monocytes that were polarized in vitro towards M1- (IFN-γ) and M2- (IL-4) phenotypes, we found that elevated nitric oxide production in M1 macrophages, inhibits oxidative phosphorylation and upregulates glycolytic pathways. Due to the uncoupling of glycolysis and the citric acid cycle/oxidative phosphorylation, an accumulation of acetylated amino acids was measured. Stable isotope tracing of glucose revealed reduced histone acetylation of certain key markers such as H3K27Ac, and others. We propose that the reduction could be due to trapping of excess acetyl-coA into acetylated amino acids. Furthermore, nitric oxide seems to irreversibly bind B12, a necessary co-factor for methionine synthase, inhibiting endogenous methionine synthesis, which could alter the histone epigenetic methylation and therefore downstream gene and protein expression. Triomics also allowed us to identify novel arginine methylation and Nα-acetylation of aspartate, glutamate, and ornithine. We conclude that triomics approach demonstrates a dynamic interplay between cellular metabolism and epigenetics and this axis can ultimately influence macrophage phenotype and gene expression.

Project description:Histone modifications commonly integrate environmental stimuli to cellular metabolic outputs by affecting gene expression. Many modifications, including some histone acetylation marks, do not always correlate to transcription, thus pointing towards an alternative role of histone modifications as potential metabolic reservoirs. Using an approach that integrates mass spectrometry- based epi-proteomics and metabolomics with stable isotope tracer studies, we demonstrate that elevated lipids in histone acetyltransferase (HAT)-depleted hepatocytes result from carbon atoms flowing from the deacetylation of multi-acetylated histone H4 to fatty acids. Consistent with this, the enhanced lipid synthesis in HAT-depleted hepatocytes is dependent on the activity of histone deacetylases (HDACs) and acetyl-CoA synthetase ACSS2. Furthermore, we show that during diet-induced lipid synthesis there is a reduction of multi-acetylated histone H4 in hepatocytes and in mouse liver. In addition, overexpression of histone acetyltransferases can reverse diet-induced lipogenesis by blocking lipid droplet accumulation and maintaining the levels of multi-acetylated histone H4. This study unveils an additional link between epigenetics and metabolism whereby histone acetylation reservoirs may serve as a carbon source for lipid synthesis.

Project description:The mechanisms underlying the formation of acyl protein modifications remain poorly understood. By investigating the reactivity of endogenous acyl-CoA metabolites, we found a class of acyl-CoAs that undergoes intramolecular catalysis to form reactive intermediates which non-enzymatically modify proteins. Based on this mechanism, we predicted, validated, and characterized the protein modification: 3-hydroxy-3-methylglutaryl(HMG)-lysine. In a model of altered HMG-CoA metabolism, we found evidence of two additional protein modifications: 3-methylglutaconyl(MGc)-lysine and 3-methylglutaryl(MG)-lysine. Using quantitative proteomics, we compared the ‘acylomes’ of two reactive acyl-CoA species, namely HMG-CoA and glutaryl-CoA, which are generated in different pathways. We found proteins that are uniquely modified by each reactive metabolite, as well as common proteins and pathways. We identified the tricarboxylic acid cycle as a pathway commonly regulated by acylation, and validated malate dehydrogenase as a key target. These data identify a fundamental relationship between reactive acyl-CoA species and proteins, and define a new regulatory paradigm in metabolism.

Project description:Our studies indicate that glucose and acetate can regulate histone acetylation by altering the acetyl-CoA concentrations in the cell. The purpose of this study was to to determine whether specific gene sets correlated with acetyl-CoA availability. We conclude that 10% of glucose-regulated genes are acetyl-CoA regulated genes (genes suppressed or induced by low glucose and reversed by acetate). Acetate usually regulated gene expression in the same direction as glucose, suggesting that acetyl-CoA is a key mediator of glucose-dependent gene expression.

Project description:Our studies indicate that glucose and acetate can regulate histone acetylation by altering the acetyl-CoA concentrations in the cell. The purpose of this study was to to determine whether specific gene sets correlated with acetyl-CoA availability. We conclude that 10% of glucose-regulated genes are acetyl-CoA regulated genes (genes suppressed or induced by low glucose and reversed by acetate). Acetate usually regulated gene expression in the same direction as glucose, suggesting that acetyl-CoA is a key mediator of glucose-dependent gene expression. The experiments were performed in quadruplicates for each condition with a total of 12 samples