Project description:We report that human acetyl-CoA synthetase 2 (AceCS2) is a mitochondrial matrix protein. AceCS2 is reversibly acetylated at Lys-642 in the active site of the enzyme. The mitochondrial sirtuin SIRT3 interacts with AceCS2 and deacetylates Lys-642 both in vitro and in vivo. Deacetylation of AceCS2 by SIRT3 activates the acetyl-CoA synthetase activity of AceCS2. This report identifies the first acetylated substrate protein of SIRT3. Our findings show that a mammalian sirtuin directly controls the activity of a metabolic enzyme by means of reversible lysine acetylation. Because the activity of a bacterial ortholog of AceCS2, called ACS, is controlled via deacetylation by a bacterial sirtuin protein, our observation highlights the conservation of a metabolic regulatory pathway from bacteria to humans.

Project description:Protein acetylation is a rapid mechanism for control of protein function. Acetyl-CoA synthetase (AMP-forming, Acs) is the paradigm for the control of metabolic enzymes by lysine acetylation. In many bacteria, type I or II protein acetyltransferases acetylate Acs, however, in actinomycetes type III protein acetyltransferases control the activity of Acs. We measured changes in the activity of the Streptomyces lividans Acs (SlAcs) enzyme upon acetylation by PatB using in vitro and in vivo analyses. In addition to the acetylation of residue K610, residue S608 within the acetylation motif of SlAcs was also acetylated (PKTRSGK610 ). S608 acetylation rendered SlAcs inactive and non-acetylatable by PatB. It is unclear whether acetylation of S608 is enzymatic, but it was clear that this modification occurred in vivo in Streptomyces. In S. lividans, an NAD+ -dependent sirtuin deacetylase from Streptomyces, SrtA (a homologue of the human SIRT4 protein) was needed to maintain SlAcs function in vivo. We have characterized a sirtuin-dependent reversible lysine acetylation system in Streptomyces lividans that targets and controls the Acs enzyme of this bacterium. These studies raise questions about acetyltransferase specificity, and describe the first Acs enzyme in any organism whose activity is modulated by O-Ser and Nɛ -Lys acetylation.

Project description:Metabolic production of acetyl coenzyme A (acetyl-CoA) is linked to histone acetylation and gene regulation, but the precise mechanisms of this process are largely unknown. Here we show that the metabolic enzyme acetyl-CoA synthetase 2 (ACSS2) directly regulates histone acetylation in neurons and spatial memory in mammals. In a neuronal cell culture model, ACSS2 increases in the nuclei of differentiating neurons and localizes to upregulated neuronal genes near sites of elevated histone acetylation. A decrease in ACSS2 lowers nuclear acetyl-CoA levels, histone acetylation, and responsive expression of the cohort of neuronal genes. In adult mice, attenuation of hippocampal ACSS2 expression impairs long-term spatial memory, a cognitive process that relies on histone acetylation. A decrease in ACSS2 in the hippocampus also leads to defective upregulation of memory-related neuronal genes that are pre-bound by ACSS2. These results reveal a connection between cellular metabolism, gene regulation, and neural plasticity and establish a link between acetyl-CoA generation 'on-site' at chromatin for histone acetylation and the transcription of key neuronal genes.

Project description:Posttranslational modifications are mechanisms for rapid control of protein function used by cells from all domains of life. Acetylation of the epsilon amino group (Nε) of an active-site lysine of the AMP-forming acetyl coenzyme A (acetyl-CoA) synthetase (Acs) enzyme is the paradigm for the posttranslational control of the activity of metabolic enzymes. In bacteria, this active-site lysine of Acs enzymes can be modified by a number of different GCN5-type N-acetyltransferases (GNATs). Acs activity is lost as a result of acetylation and is restored by deacetylation. Using a heterologous host, we show that Campylobacter jejuni NCTC11168 synthesizes enzymes that control Acs function by reversible lysine acetylation (RLA). This work validates the function of gene products encoded by the cj1537c, cj1715, and cj1050c loci, namely, the AMP-forming acetate-CoA ligase (CjAcs), a type IV GCN5-type lysine acetyltransferase (GNAT [CjLatA]), and a NAD+-dependent (class III) sirtuin deacylase (CjCobB), respectively. To our knowledge, these are the first in vivo and in vitro data on C. jejuni enzymes that control the activity of CjAcs. IMPORTANCE This work provides the experimental evidence needed to support the assignment of function to three key enzymes, two of which control the reversible posttranslational modification of an active-site lysyl residue of the central metabolic enzyme acetyl-CoA synthetase (CjAcs). We can now generate Campylobacter jejuni mutant strains defective in these functions, so we can establish the conditions in which this mode of regulation of CjAcs is triggered in this bacterium. Such knowledge may provide new therapeutic strategies for the control of this pathogen.

Project description:Lysine acylation is a posttranslational modification used by cells of all domains of life to modulate cellular processes in response to metabolic stress. The paradigm for the role of lysine acylation in metabolism is the acetyl-coenzyme A synthetase (Acs) enzyme. In prokaryotic and eukaryotic cells alike, Acs activity is downregulated by acetylation and reactivated by deacetylation. Proteins belonging to the bacterial GCN5-related N-acetyltransferase (bGNAT) superfamily acetylate the epsilon amino group of an active site lysine, inactivating Acs. A deacetylase can remove the acetyl group, thereby restoring activity. Here we show the Acs from Staphylococcus aureus (SaAcs) activates acetate and weakly activates propionate, but does not activate >C3 organic acids or dicarboxylic acids (e.g. butyrate, malonate and succinate). SaAcs activity is regulated by AcuA (SaAcuA); a type-IV bGNAT. SaAcuA can acetylate or propionylate SaAcs reducing its activity by >90% and 95% respectively. SaAcuA also succinylated SaAcs, with this being the first documented case of a bacterial GNAT capable of succinylation. Inactive SaAcsAc was deacetylated (hence reactivated) by the NAD+ -dependent (class III) sirtuin protein deacetylase (hereafter SaCobB). In vivo and in vitro evidence show that SaAcuA and SaCobB modulate the level of SaAcs activity in S. aureus.

Project description:Recent proteomics studies have revealed that protein acetylation is an abundant and evolutionarily conserved post-translational modification from prokaryotes to eukaryotes. Although an astonishing number of acetylated proteins have been identified in those studies, the acetyltransferases that target these proteins remain largely unknown. Here we characterized MSMEG_5458, one of the GCN5-related N-acetyltransferases (GNAT's) in Mycobacterium smegmatis, and show that it is a protein acetyltransferase (MsPat) that specifically acetylates the ε-amino group of a highly conserved lysine residue in acetyl-CoA synthetase (ACS) with a k(cat)/K(m) of nearly 10(4) M(-1) s(-1). This acetylation results in the inactivation of ACS activity. Lysine acetylation by MsPat is dependent on 3',5'-cyclic adenosine monophosphate (cAMP), an important second messenger, indicating that MsPat is a downstream target of the intracellular cAMP signaling pathway. To the best of our knowledge, this is the first protein acetyltransferase in mycobacteria that both is dependent on cAMP and targets a central metabolic enzyme by a specific post-translational modification. Since cAMP is synthesized by adenylate cyclases (AC's) that sense various environmental signals, we hypothesize that the acetylation and inactivation of ACS is important for mycobacteria to adjust to environmental changes. In addition, we show that Rv1151c, a sirtuin-like deacetylase in Mycobacterium tuberculosis, reactivates acetylated ACS through an NAD(+)-dependent deacetylation. Therefore, Pat and the sirtuin-like deacetylase in mycobacteria constitute a reversible acetylation system that regulates the activity of ACS.

Project description:Determining how histone acetylation is regulated is vital for treating the many diseases associated with its misregulation, including heart disease, neurological disorders, and cancer. We have previously reported that acetyl-CoA levels alter p300 histone acetylation in a site-specific manner in vitro. Here, we further investigate how changing acetyl-CoA concentrations alter the histone acetylation pattern by altering p300 specificity. Interestingly, these changes are not a simple global change in acetylation, but rather site specific changes, whereby acetylation at some sites increase while others decrease. We also demonstrate how the p300 inhibitor C646 can pharmacologically alter p300 histone acetylation patterns in vitro and in cells. This study provides insight into the mechanisms regulating p300 residue specificity, a potential means for altering p300 dependent histone acetylation, and an investigation into altering histone acetylation patterns in cells.

Project description:Recent proteomics studies suggest high abundance and a much wider role for lysine acetylation (K-Ac) in cellular functions. Nevertheless, cross influence between K-Ac and other post-translational modifications (PTMs) has not been carefully examined. Here, we used a variety of bioinformatics tools to analyze several available K-Ac datasets. Using gene ontology databases, we demonstrate that K-Ac sites are found in all cellular compartments. KEGG analysis indicates that the K-Ac sites are found on proteins responsible for a diverse and wide array of vital cellular functions. Domain structure prediction shows that K-Ac sites are found throughout a wide variety of protein domains, including those in heat shock proteins and those involved in cell cycle functions and DNA repair. Secondary structure prediction proves that K-Ac sites are preferentially found in ordered structures such as alpha helices and beta sheets. Finally, by mutating K-Ac sites in silico and predicting the effect on nearby phosphorylation sites, we demonstrate that the majority of lysine acetylation sites have the potential to impact protein phosphorylation, methylation, and ubiquitination status. Our work validates earlier smaller-scale studies on the acetylome and demonstrates the importance of PTM crosstalk for regulation of cellular function.

Project description:Acetyl-CoA synthetase (ACS) catalyzes the formation of AcCoA from acetate, ATP and Coenzyme A, allowing the organism to grow on acetate as the sole carbon source. ACS was the first enzyme in Mycobacterium tuberculosis shown to be regulated by posttranslational acetylation by the cAMP-dependent protein acetyltransferase. This modification results in the inactivation of the enzyme and can be reversed in the presence of NAD(+) and a mycobacterial sirtuin-like deacetylase. In this study we characterize the kinetic mechanism of MtACS, where the overall reaction can be divided into two half-reactions: the acetyl-adenylate forming reaction and the thiol-ligation reaction. We also provide evidence for the existence of the acetyl-adenylate intermediate via (31)P NMR spectroscopy. Furthermore, we dissect the regulatory role of K617 acetylation and show that acetylation inhibits only the first, adenylation half-reaction while leaving the second half reaction unchanged. Finally, we demonstrate that the chemical mechanism of the enzyme relies on a conformational change which is controlled by the protonation state of aspartate 525. Together with our earlier results, this suggests a degree of regulation of enzyme activity that is appropriate for the role of the enzyme in central carbon metabolism.

Project description:The high-affinity biosynthetic pathway for converting acetate to acetyl-coenzyme A (acetyl-CoA) is catalyzed by the central metabolic enzyme acetyl-coenzyme A synthetase (Acs), which is finely regulated both at the transcriptional level via cyclic AMP (cAMP)-driven trans-activation and at the post-translational level via acetylation inhibition. In this study, we discovered that cAMP directly binds to Salmonella enterica Acs (SeAcs) and inhibits its activity in a substrate-competitive manner. In addition, cAMP binding increases SeAcs acetylation by simultaneously promoting Pat-dependent acetylation and inhibiting CobB-dependent deacetylation, resulting in enhanced SeAcs inhibition. A crystal structure study and site-directed mutagenesis analyses confirmed that cAMP binds to the ATP/AMP pocket of SeAcs, and restrains SeAcs in an open conformation. The cAMP contact residues are well conserved from prokaryotes to eukaryotes, suggesting a general regulatory mechanism of cAMP on Acs.