Computational Study of Enantioselective Carboligation Catalyzed by Benzoylformate Decarboxylase

Benzoylformate decarboxylase (BFDC) is a thiamin-diphosphate enzyme that catalyzes the decarboxylation of benzoylformate to yield benzaldehyde and carbon dioxide. In addition to its natural reaction, BFDC is able to catalyze carboligation reactions in a highly enantioselective fashion, making the enzyme a potentially important biocatalyst. Here we use density functional theory calculations to investigate the detailed mechanism of BFDC-catalyzed carboligation and to elucidate the sources of the enantioselectivity. Benzaldehyde and acetaldehyde are studied as acceptors, for, when reacting with a benzaldehyde donor, they yield products with opposite enantiospecificity. For each of the acceptors, several possible binding modes to the active site are initially examined before the individual reaction paths leading to the two enantiomeric products are followed. The calculated energies are in good agreement with the experimental results, and the analysis of the transition states gives insight into the origins of the enantioselectivity

A Theoretical Study of the Benzoylformate Decarboxylase Reaction Mechanism

Density functional theory calculations are used to investigate the detailed reaction mechanism of benzoylformate decarboxylase, a thiamin diphosphate (ThDP)-dependent enzyme that catalyzes the nonoxidative decarboxylation of benzoylformate yielding benzaldehyde and carbon dioxide. A large model of the active site is constructed on the basis of the X-ray structure, and it is used to characterize the involved intermediates and transition states and evaluate their energies. There is generally good agreement between the calculations and available experimental data. The roles of the various active site residues are discussed and the results are compared to mutagenesis experiments. Importantly, the calculations identify off-cycle intermediate species of the ThDP cofactor that can have implications on the kinetics of the reaction

Catalysis by [Ga4L6]12− metallocage on the Nazarov cyclization : the basicity of complexed alcohol is key

The Nazarov cyclization is investigated in solution and within K[GaL] supramolecular organometallic cage by means of computational methods. The reaction needs acidic condition in solution but works at neutral pH in the presence of the metallocage. The reaction steps for the process are analogous in both media: (a) protonation of the alcohol group, (b) water loss and (c) cyclization. The relative Gibbs energies of all the steps are affected by changing the environment from solvent to the metallocage. The first step in the mechanism, the alcohol protonation, turns out to be the most critical one for the acceleration of the reaction inside the metallocage. In order to calculate the relative stability of protonated alcohol inside the cavity, we propose a computational scheme for the calculation of basicity for species inside cavities and can be of general use. These results are in excellent agreement with the experiments, identifying key steps of catalysis and providing an in-depth understanding of the impact of the metallocage on all the reaction steps

A combined experimental-theoretical study of the ligW-catalyzed decarboxylation of 5-carboxyvanillate in the metabolic pathway for lignin degradation

Although it is a member of the amidohydrolase superfamily, LigW catalyzes the nonoxidative decarboxylation of 5-carboxyvanillate to form vanillate in the metabolic pathway for bacterial lignin degradation. We now show that membrane inlet mass spectrometry (MIMS) can be used to measure transient CO₂ concentrations in real time, thereby permitting us to establish that C–C bond cleavage proceeds to give CO₂ rather than HCO₃^– as the initial product in the LigW-catalyzed reaction. Thus, incubation of LigW at pH 7.0 with the substrate 5-carboxyvanillate results in an initial burst of CO₂ formation that gradually decreases to an equilibrium value as CO₂ is nonenzymatically hydrated to HCO₃^–. The burst of CO₂ is completely eliminated with the simultaneous addition of substrate and excess carbonic anhydrase to the enzyme, demonstrating that CO₂ is the initial reaction product. This finding is fully consistent with the results of density functional theory calculations, which also provide support for a mechanism in which protonation of the C5 carbon takes place prior to C–C bond cleavage. The calculated barrier of 16.8 kcal/mol for the rate-limiting step, the formation of the C5-protonated intermediate, compares well with the observed <i>k</i>_cat value of 27 s^–1 for Sphingomonas paucimobilis LigW, which corresponds to an energy barrier of ∼16 kcal/mol. The MIMS-based strategy is superior to alternate methods of establishing whether CO₂ or HCO₃^– is the initial reaction product, such as the use of pH-dependent dyes to monitor very small changes in solution pH. Moreover, the MIMS-based assay is generally applicable to studies of all enzymes that produce and/or consume small-molecule, neutral gases

Reaction Mechanism and Substrate Specificity of Iso-orotate Decarboxylase: A Combined Theoretical and Experimental Study

The C-C bond cleavage catalyzed by metal-dependent iso-orotate decarboxylase (IDCase) from the thymidine salvage pathway is of interest for the elucidation of a (hypothetical) DNA demethylation pathway. IDCase appears also as a promising candidate for the synthetic regioselective carboxylation of N-heteroaromatics. Herein, we report a joint experimental-theoretical study to gain insights into the metal identity, reaction mechanism, and substrate specificity of IDCase. In contrast to previous assumptions, the enzyme is demonstrated by ICPMS/MS measurements to contain a catalytically relevant Mn2+ rather than Zn2+. Quantum chemical calculations revealed that decarboxylation of the natural substrate (5-carboxyuracil) proceeds via a (reverse) electrophilic aromatic substitution with formation of CO2. The occurrence of previously proposed tetrahedral carboxylate intermediates with concomitant formation of HCO3- could be ruled out on the basis of prohibitively high energy barriers. In contrast to related o-benzoic acid decarboxylases, such as γ-resorcylate decarboxylase and 5-carboxyvanillate decarboxylase, which exhibit a relaxed substrate tolerance for phenolic acids, IDCase shows high substrate fidelity. Structural and energy comparisons suggest that this is caused by a unique hydrogen bonding of the heterocyclic natural substrate (5-carboxyuracil) to the surrounding residues. Analysis of calculated energies also shows that the reverse carboxylation of uracil is impeded by a strongly disfavored uphill reaction

Peptide Release on the Ribosome Involves Substrate-Assisted Base Catalysis

Termination of protein synthesis on the ribosome involves hydrolysis of the ester bond between the P-site tRNA and the nascent peptide chain. This reaction occurs in the peptidyl transferase center and is triggered by the class I release factors RF1 and RF2 in prokaryotes. Peptidyl-tRNA hydrolysis is pH-dependent, and experimental results suggest that an ionizable group with pK(a) &gt; 9 is involved in the reaction. The nature of this group is, however, unknown. To resolve this problem, we conducted density functional theory calculations using a large cluster model of the peptidyl transferase center. Our calculations reveal that peptidyl-tRNA hydrolysis occurs via a base-catalyzed mechanism with a predicted activation energy of 15.8 kcal mol(-1), which is in good agreement with experimental data. In this mechanism, the P-site A76 2'-OH group is deprotonated and acts as the general base by activating the nucleophilic water molecule. The energy cost of deprotonating the 2'-hydroxyl group at pH 7.5 is estimated to be about 8 kcal mo1(-1), on the basis of its experimental plc in aqueous solution, and this step is predicted to be the source of the observed pH dependence. The proposed mechanism is consistent not only with experimentally derived activation energies but also with the observed kinetic solvent isotope effect