Project description:Inherited deficiencies of the lysine and tryptophan catabolic pathways, due to mutations in the glutaryl-CoA-dehydrogenase (GCDH) gene, cause glutaric aciduria type 1 (GA1). In mammals two metabolic routes for L-lysine oxidation exist, the mitochondrial saccharopine pathway, which is predominant in extracerebral tissue and the peroxysomal/cytosolic pipecolate pathway, the main pathway in adult brain. A unique feature of all pathways is the formation of glutaryl-CoA that is converted into crotonyl-CoA via GCDH. In this study we identified increased lysine glutarylation, a novel reversible post-translational modification, in various tissues and cultured cells of Gcdh KO mice as a result of glutaryl-CoA accumulation. Our analysis revealed that glutarylation is widespread in mitochondria. By using a proteomic approach, we identified 37 and 154 glutarylated mitochondrial proteins in brain and liver tissue from Gcdh KO mice, respectively. We further showed that glutarylation supresses glutamate dehydrogenase (GDH) and carbonic anhydrase 5B activity, plus the direct interaction between GCDH and GDH.

Project description:The posttranslational modification lysine malonylation is found in many proteins, including histones. However, it remains unclear whether histone malonylation is regulated or functionally relevant. Here, we report that availability of malonyl-co-enzyme A (malonyl-CoA), an endogenous provider of malonyl groups, affects lysine malonylation, and that the deacylase SIRT5 selectively reduces malonylation of histones. To determine if histone malonylation is enzymatically catalyzed, we knocked down each of the 22 lysine acetyltransferases (KATs) to test their malonyltransferase potential. KAT2A knockdown reduced and KAT2A overexpression increased levels of histone malonylation, respectively. By mass spectrometry, H2B_K5 was highly malonylated and significantly regulated by SIRT5 in mouse brain and liver. Acetyl-CoA carboxylase (ACC), the malonyl-CoA producing enzyme, was partly localized in the nucleolus, and histone malonylation increased nucleolar area and ribosomal RNA expression. Levels of global lysine malonylation and ACC expression were higher in older mouse brains than younger mice. These experiments highlight the role of histone malonylation in ribosomal gene expression.

Project description:Protein acylation links energetic substrate flux with cellular adaptive responses. SIRT5 is a NAD+-dependent lysine deacylase and removes both succinyl and malonyl group. Using affinity enrichment and label free quantitative proteomics, we characterized the SIRT5-regulated lysine malonylome in wild type (WT) and Sirt5-/- mice. 1137 malonyllysine sites were identified across 430 proteins, with 183 sites (from 120 proteins) significantly increased in the Sirt5-/- animals. Pathway analysis identified glycolysis as the top SIRT5-regulated pathway. Importantly, glycolytic flux was diminished in primary hepatocytes from Sirt5-/- compared to WT mice. Substitution of malonylated lysine residue 184 in glyceraldehyde 3-phosphate dehydrogenase with glutamic acid, a malonyllysine mimic, suppressed its enzymatic activity. Comparison of our previous reports on acylation reveals that malonylation targets a different set of proteins than acetylation and succinylation. These data demonstrate that SIRT5 is a global regulator of lysine malonylation and provide a mechanism for regulation of energetic flux through glycolysis.

Project description:We are studying the role of human sirtuin SIRT5 during viral infection with SARS-CoV-2. We performed RNA-sequencing of WT and SIRT5-KO human lung adenocarinoma A549 cells overexpressing ACE2 (A549-ACE2), in infected and mock-infected conditions. . Our analysis revealed that SARS-CoV-2 replication is attenuated in SIRT5-KO cells. In addition, SIRT5-KO cells expressed higher basal levels of innate immunity markers and mounted a stronger antiviral response. Our results indicate that SIRT5 is a proviral factor necessary for efficient viral replication.

Project description:Nε-lysine acetylation has emerged as a central mechanism to maintain quality control and protein homeostasis within the Endoplasmic Reticulum (ER) and secretory pathway. The ER acetylation machinery includes AT-1/SLC33A1, a membrane transporter that translocates acetyl-CoA from the cytosol to the ER lumen, and ATase1 and ATase2, two ER membrane-bound acetyltransferases that acetylate ER cargo proteins. Dysfunctional AT-1, as caused by loss-of-function mutations or gene duplication events, results in neurodevelopmental or neurodegenerative disorders. Experiments in our lab have demonstrated that these human diseases can be effectively recapitulated in mouse models. In this thesis, we used two models of dysregulated acetyl-CoA flux: AT-1S113R/+, a model of AT-1 haploinsufficiency, and AT-1 sTg, a model of systemic overexpression of AT-1. First, we examined upstream processes of cytosol-to-ER acetyl-CoA flux by evaluating the cytosolic pool of acetyl-CoA. The aberrant AT-1 models demonstrated distinct metabolic reprogramming of lipid metabolism and mitochondria bioenergetics. Dysregulated acetyl-CoA flux resulted in global changes at the level of the proteome and the acetyl-proteome. Second, we examined the downstream consequences of cytosol-to-ER acetyl-CoA flux. Specifically, we investigated the engagement and functional organization of the secretory pathway and used N-glycoproteomics to determine the quality of secreted proteins. Aberrant AT-1 models demonstrated reorganization of the ER, Golgi, and ERGIC, as well as a delay in glycoproteins clearing the Golgi apparatus. Additionally, AT-1 sTg mice showed a marked delay in protein trafficking to the cell surface. The N-glycoproteome revealed significant alterations, highlighting changes in the quality of the secretome.

Project description:: Prostate cancer (PCa) is the most commonly diagnosed genital cancer in men worldwide. Among patients who developed advanced PCa, 80% suffered from bone metastasis, with a sharp drop in the survival rate. Using quantitative global succinylome analysis, we characterized a significant increase of lysine 118 succinylation (K118su) of lactate dehydrogenase A (LDHA), which plays a role in increasing LDHA activity. As a substrate of SIRT5, LDHA-K118su significantly increased the migration and invasion of PCa cells and LDHA activity in PCa patients.

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:Mitochondrial Sirtuin 5 (SIRT5) is an NAD+-dependent demalonylase, desuccinylase, and deglutarylase that controls several metabolic pathways. A number of recent studies point to SIRT5 desuccinylase activity being important in maintaining cardiac function and metabolism under stress. Previously, we described a phenotype of increased mortality in whole-body SIRT5KO mice exposed to chronic pressure overload compared to their littermate WT controls. We developed a tamoxifen-inducible, heart-specific SIRT5KO mouse model to determine if the survival phenotype we reported was due to a cardiac-intrinsic or cardiac-extrinsic effect of SIRT5. We discovered that postnatal cardiac ablation of Sirt5 resulted in persistent accumulation of protein succinylation up to 30 weeks after SIRT5 depletion. Succinyl proteomics revealed that succinylation increased on proteins of oxidative metabolism between 15 and 31 weeks post ablation. Heart-specific SIRT5KO mice were exposed to chronic pressure overload to induce cardiac hypertrophy. We found that, in contrast to whole-body SIRT5KO mice, there was no difference in survival between heart-specific SIRT5KO mice and their littermate controls. Overall, the data presented here suggest that survival in SIRT5KO mice may be dictated by a multi-tissue or prenatal effect of SIRT5.

Project description:Lysine acylations, such as acetylation, succinylation, or glutarylation, are post-translational modifications that regulate protein function. In mitochondria, lysine acylation is predominantly non-enzymatic and only a specific subset of the proteome has been identified as acylated. Coenzyme A (CoA), a metabolite required in several metabolic pathways, can act as an acyl group carrier via a thioester bond. However, what controls the acylation of lysine residues in the mitochondria remains poorly understood. Using published datasets, we found that proteins with a CoA-binding site are more likely to be acetylated, succinylated, and glutarylated. Using computational modeling, we discovered that, in CoA-binding proteins, lysine residues near the CoA-binding pocket are more likely to be acylated than those far away from the CoA-binding pocket. We hypothesized that acyl-CoA binding enhances the acylation of nearby lysine residues. To experimentally test this hypothesis, we used enoyl-CoA hydratase short chain 1 (ECHS1), a mitochondrial protein with a CoA-binding pocket, and co-incubated ECHS1 with succinyl-CoA and CoA. Using mass spectrometry, we found that succinyl-CoA induced widespread lysine succinylation and that CoA competitively inhibited ECHS1 succinylation. In addition, CoA-induced inhibition at a particular lysine site was inversely correlated with the distance between this lysine residue and the CoA-binding pocket. This indicated that CoA acts as a competitive inhibitor of ECHS1 succinylation by binding to the CoA-binding pocket. Together, this study suggests proximal acylation at protein CoA-binding sites is a primary mechanism for lysine acylation in the mitochondria.

Project description:Acetyl groups are transferred from Acetyl-Coenzyme A (Ac-CoA) to protein N-termini and lysine side chains by N-terminal acetyltransferases (NATs) and lysine acetyltransferases (KATs), respectively. Building on lysine-CoA conjugates as KAT probes, we have synthesized peptide probes with CoA conjugated to N-terminal alanine (α-Ala-CoA), proline (α-Pro-CoA) or tri-glutamic acid (α-3Glu-CoA) units for interactome profiling of NAT complexes. These probes recruited catalytic and auxiliary subunits of the major NAT complexes from cell lysates specifically. The α-Ala-CoA probe was more specific in recruiting NAT catalytic and auxiliary subunits when compared to a lysine CoA-conjugate which bound only a subset of endogenous KATs. Interactome profiling with the α-Pro-CoA probe showed reduced NAT recruitment in favor of metabolic CoA binding proteins, while α-3Glu-CoA steered the interactome towards NAA80 and NatB. These findings agreed with the inherent substrate specificities of the target proteins and showed that N-terminal CoA-conjugated peptides are versatile probes for NAT complex profiling in lysates of physiological and pathological backgrounds.