NAD+-dependent formate dehydrogenase (FDH, EC 1.2.1.2) from the bacterium Staphylococcus aureus (SauFDH) plays an important role in the vital activity of this bacterium, especially in the form of biofilms. Understanding its mechanism and structure-function relationship can help to find special inhibitors of this enzyme, which can be used as medicines against staphylococci. The gene encoding SauFDH was successfully cloned and expressed in our laboratory. This enzyme has the highest kcat value among the described FDHs and also has a high temperature stability compared to other enzymes of this group. That is why it can also be considered as a promising catalyst for NAD(P)H regeneration in the processes of chiral synthesis with oxidoreductases. In this work, the principle of rational design was used to improve SauFDH catalytic efficiency. After bioinformatics analysis of the amino acid sequence in combination with visualization of the enzyme structure (PDB 6TTB), 9 probable catalytically significant positions 119, 194, 196, 217-219, 246, 303 and 323 were identified, and 16 new mutant forms of SauFDH were obtained and characterized by kinetic experiments. The introduction of the mentioned substitutions in most cases leads to a decrease in stability at high temperatures and an increase at low temperatures. Substitutions in positions 119 and 194 lead to a decreasing of KMNAD+. A consistent decrease in the Michaelis constant in the Ile-Val-Ala-Gly series at position 119 of SauFDH is shown. KMNAD+ of mutant SauFDH V119G decreased by 27 times compared to the wild-type enzyme. After substitution Phe194Val KMNAD + decreased by 3.5 times. The catalytic constant for this mutant form practically did not change. For this mutant form, an increase in catalytic efficiency was demonstrated through the use of a multicomponent buffer system.

Formate dehydrogenase from Candida boidinii (CbFDH; EC.1.2.1.2) is a useful enzyme for CO2 reduction to formate in the photoredox system of a visible-light sensitizer and an electron mediator in the presence of an electron donor. The electron mediator, cation radicals of 4,4\'-bipyridinium salts (4,4\'-BPs) act as the co-enzyme for CbFDH in the CO2 reduction to formate. We found that the CbFDH-catalyzed CO2 reduction to formate could be controlled by the ionic substituents introduced into the cation radical of 4,4\'-BPs [Y. Amao, Sustainable Energy Fuels, 2018, 2, 1928-1950]. By using 1,1\'-diaminoethyl-4,4\'-bipyridinium salt (DABP), 1-aminoethyl-1\'-methyl-4,4\'-bipyridinium salt (AMBP), 1,1\'-carboxymethyl-4,4\'-bipyridinium salt (DCBP), and 1-carboxymethyl-1\'-methyl-4,4\'-bipyridinium salt (CMBP), the introduction of an amino-group into 4,4\'-BP accelerates the CbFDH-catalyzed CO2 reduction to formate, while the introduction of a carboxy-group into 4,4\'-BP slows the CO2 reduction to formate. This work clarified the direct interaction of the cation radicals of DABP, DCBP, AMBP, CMBP, and MV in the substrate-binding site of CbFDH by the docking simulation. In addition, a mechanistic investigation for the CbFDH-catalyzed CO2 reduction to formate with cation radicals of DABP, DCBP, AMBP, CMBP, and MV was carried out based on the energy of molecular orbitals calculated by density functional theory (DFT).

Bis(dithiolene)tungsten complexes, W(VI)O2 (L = dithiolene)2 and W(IV)O (L = dithiolene)2, which mimic the active site of formate dehydrogenases, have been characterized by cyclic voltammetry and controlled potential electrolysis in acetonitrile. They are shown to be able to catalyze the electroreduction of protons into hydrogen in acidic organic media, with good Faradaic yields (75-95%) and good activity (rate constants of 100 s(-1)), with relatively high overpotentials (700 mV). They also catalyze proton reduction into hydrogen upon visible light irradiation, in combination with [Ru(bipyridine)3](2+) as a photosensitizer and ascorbic acid as a sacrificial electron donor. On the basis of detailed DFT calculations, a reaction mechanism is proposed in which the starting W(VI)O2 (L = dithiolene)2 complex acts as a precatalyst and hydrogen is further formed from a key reduced W-hydroxo-hydride intermediate.

The study of protein conformation in ionic liquids (ILs) is crucial to understand enzymatic activity. Steady-state fluorescence is a proven, rapid and easy method to evaluate the protein structure in aqueous solutions, but it is discussed when used in ILs. In this work, the structure of the formate dehydrogenase from Candida boidinii (FDH, EC: 1.2.1.2) in three imidazolium-based ILs (dimethylimidazolium dimethylphosphate [MMIm][Me(2)PO(4)], 1-butyl-3-methylimidazolium acetate [BMIm][CH(3)COO], and dimethylimidazolium methylphosphonate [MMIm][CH(3)HPO(2)(OCH(3))]) is studied by fluorescence spectroscopy. The UV-vis spectroscopic analysis shows that the decrease of the FDH fluorescence is not only due to the high light absorption of these ILs. The Stern-Volmer analysis clearly shows that these ILs are quenchers of the indole fluorescence, while this quenching property is not found when imidazole is used. Fluorescence spectra of the FDH in the presence of the ILs show that a maximal ionic liquid concentration (MILc), which could be used for steady-state fluorescence study, should be defined. Therefore, FDH conformation could not be directly related to the decrease of its fluorescence in ILs. Nevertheless, the structure of the FDH could be evaluated with dynamic and static quenchers like iodide or acrylamide, used below the MILc, demonstrating the relevance of this parameter. The Stern-Volmer constants (K(SV)(Q)), calculated in the presence of the different ILs, demonstrate that these ILs are strong denaturing agents, each one acting with a different mechanism. This report provides a suitable and easy-to-apply method to study any enzyme structures in ILs by steady-state fluorescence.

A theoretical study of the hydride transfer between formate anion and nicotinamide adenine dinucleotide (NAD(+)) catalyzed by the enzyme formate dehydrogenase (FDH) has been carried out by a combination of two hybrid quantum mechanics/molecular mechanics techniques: statistical simulation methods and internal energy minimizations. Free energy profiles, obtained for the reaction in the enzyme active site and in solution, allow obtaining a comparative analysis of the behavior of both condensed media. Moreover, calculations of the reaction in aqueous media can be used to probe the dramatic differences between reactants state in the enzyme active site and in solution. The results suggest that the enzyme compresses the substrate and the cofactor into a conformation close to the transition structure by means of favorable interactions with the amino acid residues of the active site, thus facilitating the relative orientation of donor and acceptor atoms to favor the hydride transfer. Moreover, a permanent field created by the protein reduces the work required to reach the transition state (TS) with a concomitant polarization of the cofactor that would favor the hydride transfer. In contrast, in water the TS is destabilized with respect to the reactant species because the polarity of the solute diminishes as the reaction proceeds, and consequently the reaction field, which is created as a response to the change in the solute polarity, is also decreased. Therefore protein structure is responsible of both effects; substrate preorganization and TS stabilization thus diminishing the activation barrier. Because of the electrostatic features of the catalyzed reaction, both media preferentially stabilize the ground-state, thus explaining the small rate constant enhancement of this enzyme, but FDH does so to a much lower extent than aqueous solution. Finally, a good agreement between experimental and theoretical kinetic isotope effects is found, thus giving some credit to our results.

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A comparative study of the thermostability of NAD+-dependent formate dehydrogenases (FDHs; EC 1.2.1.2) from both methylotrophic bacteria Pseudomonas sp. 101 and Moraxella sp. Cl, the methane-utilizing yeast Candida boidinii, and plants Arabidopsis thaliana and Glycine max (soybean) was performed. All the enzymes studied were produced by expression in E. coli cells. The enzymes were irreversibly inactivated in one stage according to first-order reaction kinetics. The FDH from Pseudomonas sp. 101 appeared as the most thermostable enzyme; its counterpart from G. max exhibited the lowest stability. The enzymes from Moraxella sp. Cl, C. boidinii, and A. thaliana showed similar thermostability profiles. The temperature dependence of the inactivation rate constant of A. thaliana FDH was studied. The data of differential scanning calorimetry was complied with the experimental results on the inactivation kinetics of these enzymes. Values of the melting heat were determined for all the enzymes studied.

Molybdenum enzymes containing the pterin cofactor are a diverse group of enzymes that catalyse in general oxygen atom transfer reactions. Aiming at studying the amino acid residues, which are important for the enzymatic specificity, we used nitrate reductase from Ralstonia eutropha (R.e.NAP) as a model system for mutational studies at the active site. We mutated amino acids at the Mo active site (Cys181 and Arg421) as well as amino acids in the funnel leading to it (Met182, Asp196, Glu197, and the double mutant Glu197-Asp196). The mutations were made on the basis of the structural comparison of nitrate reductases with formate dehydrogenases (FDH), which show very similar three-dimensional structures, but clear differences in amino acids surrounding the active site. For mutations Arg421Lys and Glu197Ala we found a reduced nitrate activity while the other mutations resulted in complete loss of activity. In spite of the partial of total loss of nitrate reductase activity, these mutants do not, however, display FDH activity.

Lysine 85 (K85) in the primary structure of the catalytic subunit of the periplasmic nitrate reductase (NAP-A) of Ralstonia eutropha H16 is highly conserved in periplasmic nitrate reductases and in the structurally related catalytic subunit of the formate dehydrogenases of various bacterial species. It is located between an [4Fe-4S] center and one of the molybdopterin-guanine dinucleotides mediating the through bonds electron flow to convert the specific substrate of the respective enzymes. To examine the role of K85, the structure of NAP-A of R. eutropha strain H16 was modeled on the basis of the crystal structure from the Desulfovibrio desulfuricans enzyme (Dias et al. Structure Fold Des. 7(1) (1999) 65) and K85 was replaced by site-directed mutagenesis, yielding K85R and K85M, respectively. The specific nitrate reductase activity was determined in periplasmic extracts. The mutant enzyme carrying K85R showed 23% of the wild-type activity, whereas the replacement by a polar, uncharged residue (K85M) resulted in complete loss of the catalytic activity. The reduced nitrate reductase activity of K85R was not due to different quantities of the expressed gene product, as controlled immunologically by NAP-specific antibodies. The results indicate that K85 is optimized for the electron transport flux to reduce nitrate to nitrite in NAP-A, and that the positive charge alone cannot meet further structural requirement for efficient electron flow.

The oxidation of formate associated with fast acidification of medium by whole Escherichia coli cells lacking both hya and hyb hydrogenases was studied. The extent of acidification was dependent on the amount of formate added. An average H+/formate ratio of 1.3 was obtained. The proton release was inhibited by carbonyl cyanide m-chlorophenylhydrazone. Inverted vesicles of E. coli were found to translocate protons upon oxidation of formate at pH 6.5. The extent of alkalization was also dependent on the amount of formate added. The maximum H+/formate ratio for this reaction was close to 0.6. Formate oxidation by inverted vesicles from E. coli (delta hya delta hyb) was sensitive to the protonophore carbonyl cyanide m-chlorophenylhydrazone. It was supposed that the hydrogenase 3 (hyc) component of E. coli formate hydrogen lyase is responsible for the translocation of protons at low pH.