72-89-9Relevant articles and documents
Interchain acetyl transfer in the E2 component of bacterial pyruvate dehydrogenase suggests a model with different roles for each chain in a trimer of the homooligomeric component
Song, Jaeyoung,Jordan, Frank
, p. 2795 - 2803 (2012)
The bacterial pyruvate dehydrogenase complex carries out conversion of pyruvate to acetyl-coenzyme A with the assistance of thiamin diphosphate (ThDP), several other cofactors, and three principal protein components, E1-E3, each present in multiple copies. The E2 component forms the core of the complexes, each copy consisting of variable numbers of lipoyl domains (LDs, lipoic acid covalently amidated at a lysine residue), peripheral subunit binding domains (PSBDs), and catalytic (or core) domains (CDs). The reaction starts with a ThDP-dependent decarboxylation on E1 to an enamine/C2α carbanion, followed by oxidation and acetyl transfer to form S-acetyldihydrolipoamide E2, and then transfer of this acetyl group from the LD to coenzyme A on the CD. The dihydrolipoamide E2 is finally reoxidized by the E3 component. This report investigates whether the acetyl group is passed from the LD to the CD in an intra- or interchain reaction. Using an Escherichia coli E2 component having a single LD, two types of constructs were prepared: one with a Lys to Ala substitution in the LD at the Lys carrying the lipoic acid, making E2 incompetent toward post-translational ligation of lipoic acid and, hence, toward reductive acetylation, and the other in which the His believed to catalyze the transthiolacetylation in the CD is substituted with A or C, the absence of His rendering it incompetent toward acetyl-CoA formation. Both kinetic evidence and mass spectrometric evidence support interchain transfer of the acetyl groups, providing a novel model for the presence of multiples of three chains in all E2 components, and their assembly in bacterial enzymes.
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Wilson
, p. 3205 (1952)
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The architecture of the diaminobutyrate acetyltransferase active site provides mechanistic insight into the biosynthesis of the chemical chaperone ectoine
Bremer, Erhard,Czech, Laura,Dickschat, Jeroen S.,Erb, Tobias J.,Hoeppner, Astrid,Kobus, Stefanie,Lauterbach, Lukas,Richter, Alexandra A.,Smits, Sander H. J.,Zarzycki, Jan
, p. 2822 - 2838 (2020)
Ectoine is a solute compatible with the physiologies of both prokaryotic and eukaryotic cells and is widely synthesized by bacteria as an osmotic stress protectant. Because it preserves functional attributes of proteins and macromolecular complexes, it is considered a chemical chaperone and has found numerous practical applications. However, the mechanism of its biosynthesis is incompletely understood. The second step in ectoine biosynthesis is catalyzed by L-2,4-diaminobutyrate acetyltransferase (EctA; EC 2.3.1.178), which transfers the acetyl group from acetyl-CoA to EctB-formed L-2,4-diaminobutyrate (DAB), yielding N-γ-acetyl-L-2,4-diaminobutyrate (N-γ- ADABA), the substrate of ectoine synthase (EctC). Here, we report the biochemical and structural characterization of the EctA enzyme from the thermotolerant bacterium Paenibacillus lautus (Pl). We found that (Pl)EctA forms a homodimer whose enzyme activity is highly regiospecific by producing N-γ- ADABA but not the ectoine catabolic intermediate N-α-acetyl- L-2,4-diaminobutyric acid. High-resolution crystal structures of (Pl)EctA (at 1.2-2.2?resolution) (i) for its apo-form, (ii) in complex with CoA, (iii) in complex with DAB, (iv) in complex with both CoA and DAB, and (v) in the presence of the product N-γ- ADABA were obtained. To pinpoint residues involved in DAB binding, we probed the structure-function relationship of (Pl)EctA by site-directed mutagenesis. Phylogenomics shows that EctA-type proteins from both Bacteria and Archaea are evolutionarily highly conserved, including catalytically important residues. Collectively, our biochemical and structural findings yielded detailed insights into the catalytic core of the EctA enzyme that laid the foundation for unraveling its reaction mechanism.
Identification of an α-Oxoamine Synthase and a One-Pot Two-Step Enzymatic Synthesis of α-Amino Ketones
Zhou, Ting,Gao, Du,Li, Jia-Xin,Xu, Min-Juan,Xu, Jun
supporting information, p. 37 - 41 (2020/12/21)
Alb29, an α-oxoamine synthase involved in albogrisin biosynthesis in Streptomyces albogriseolus MGR072, was characterized and responsible for the incorporation of l-glutamate to acyl-coenzyme A substrates. Combined with Alb29 and Mgr36 (an acyl-coenzyme A ligase), a one-pot enzymatic system was established to synthesize seven α-amino ketones. When these α-amino ketones were fed into the alb29 knockout strain Δalb29, respectively, the albogrisin analogs with different side chains were observed.
Characterization of acetyl-CoA synthetase kinetics and ATP-binding
Gallego-Jara, Julia,Terol, Gema Lozano,écija Conesa, Ana,Zambelli, Barbara,Cánovas Díaz, Manuel,de Diego Puente, Teresa
, p. 1040 - 1049 (2019/04/04)
Background: The superfamily of adenylating enzymes is a large family of enzymes broadly distributed from bacteria to humans. Acetyl-CoA synthetase (Acs), member of this family, is a metabolic enzyme with an essential role in Escherichia coli (E. coli) acetate metabolism, whose catalytic activity is regulated by acetylation/deacetylation in vivo. Methods: In this study, the kinetics and thermodynamic parameters of deacetylated and acetylated E. coli Acs were studied for the adenylating step. Moreover, the role of the T264, K270, D500 and K609 residues in catalysis and ATP-binding was also determined by Isothermal titration calorimetry. Results: The results showed that native Acs enzyme binds ATP in an endothermic way. The dissociation constant has been determined and ATP-binding showed no significant differences between acetylated and deacetylated enzyme, although kcat was much higher for the deacetylated enzyme. However, K609 lysine mutation resulted in an increase in ATP-Acs-affinity and in a total loss of enzymatic activity, while T264 and D500 mutant proteins showed a total loss of ATP-binding ability and a decrease in catalytic activity. K609 site-specified acetylation induced a change in Acs conformation which resulted in an exothermic and more energetic ATP-binding. Conclusions: The differences in ATP-binding could explain the broadly conserved inactivation of Acs when K609 is acetylated. General Significance: The results presented in this study demonstrate the importance of the selected residues in Acs ATP-binding and represent an advance in our understanding of the adenylation step of the superfamily of adenylating enzymes and of their acetylation/deacetylation regulation.
