Antioxidant efficiency of oxovitisin, a new class of red wine pyranoanthocyanins, revealed through quantum mechanical investigations.

Oxovitisin is a natural antioxidant present in aged wine and comes from the chemical transformation undergone by anthocyanins and pyranoanthocyanins. Its antioxidant radical scavenging capacity was theoretically explored by density functional theory (DFT)/B3LYP methods. The O-H bond dissociation energy (BDE), the ionization potential (IP), the proton affinity (PA), and the metal-oxovitisin binding energy (BE) parameters were computed in the gas-phase and in water and benzene solutions. Results provided molecular insight into factors that influence radical scavenging potential of this new class of anthocyanins.

Can human prolidase enzyme use different metals for full catalytic activity?

The catalytic hydrolysis of the Gly-Pro substrate by the bimetallic prolidase active site model cluster has been investigated at the DF/B3LYP level of theory, in order to provide fundamental insights into the still poorly understood mechanism of prolidase catalysis. To date, the majority of prolidases exhibits metal-dependent activity, requiring two divalent cations such as Zn(2+), Mn(2+), or Co(2+) for maximal activity. In addition, it has been shown recently that two different metal ions in the active site of human prolidase (Zn and Mn) can coexist, with the protein remaining partially active. With the purpose of identifying which is the most efficient dimetallic center for the prolidase catalyzed reaction, Zn(II), Co(II), and Mn(II) have been examined as potential catalytic metals for this enzyme. Furthermore, to better elucidate the exact roles played by the metals occupying the site 1 and site 2 positions, the hetero-bimetallic active site having Zn and Mn cations has been also investigated, considering the two derivatives Mn1-Zn2 and Zn1-Mn2. The rate-determining step of the hydrolysis reaction is always found to be the nucleophilic addition of the hydroxide ion on the carbonyl carbon of the scissile peptide bond, followed by the less energetically demanding proline-peptide C-N bond scission. The analysis of the involved energy barriers does not indicate clearly a preference for a particular metal by the prolidase enzyme. Instead, we may point out a slightly better behavior of the cobalt-containing cluster as far as both tetrahedral formation and its decomposition are concerned, due to a greater degree of ligands-to-metals charge transfer. The mixed Mn-Zn hetero-dimetallic clusters appear to be also able to perform the hydrolysis of the Pro-Gly substrate, with a slight preference for the Mn1-Zn2 configuration.

Detailed Investigation of the OH Radical Quenching by Natural Antioxidant Caffeic Acid Studied by Quantum Mechanical Models.

The effectiveness of naturally occurring antioxidant caffeic acid in the inactivation of the very damaging hydroxyl radical has been theoretically investigated by means of hybrid density functional theory. Three possible pathways by which caffeic acid may inactivate free radicals were analyzed: hydrogen abstraction from all available hydrogen atoms, hydroxyl radical addition to all carbon atoms in the molecule, and single electron transfer. The reaction paths were traced independently, and the respective thermal rate constants were calculated using variational transition-state theory including the contribution of tunneling. The more reactive sites in caffeic acid are the C4OH phenolic group and the C4 carbon atom, for the hydrogen abstraction and radical addition, respectively. The single electron transfer process seems to be thermodynamically unfavored, in both polar and nonpolar media. Both hydrogen abstraction and radical addition are very feasible, with a slight preference for the latter, with a rate constant of 7.29 × 10(10) M(-1) s(-1) at 300 K. Tunnel effects are found to be quite unimportant in both cases. Results indicate caffeic acid as a potent natural antioxidant in trapping and scavenging hydroxyl radicals.

On the inhibitor effects of bergamot juice flavonoids binding to the 3-hydroxy-3-methylglutaryl-CoA reductase (HMGR) enzyme.

Density functional theory was applied to study the binding mode of new flavonoids as possible inhibitors of the 3-hydroxy-3-methylglutaryl-CoA reductase (HMGR), an enzyme that catalyzes the four-electron reduction of HMGCoA to mevalonate, the committed step in the biosynthesis of sterols. The investigated flavonoid conjugates brutieridin and melitidin were recently quantified in the bergamot fruit extracts and identified to be structural analogues of statins, lipids concentration lowering drugs that inhibit HMGR. Computations allowed us to perform a detailed analysis of the geometrical and electronic features affecting the binding of these compounds, as well as that of the excellent simvastatin drug, to the active site of the enzyme and to give better insight into the inhibition process.

Pyranoanthocyanins: a theoretical investigation on their antioxidant activity.

The antioxidant radical scavenging capacity of pyranoanthocyanins present in aged wine and coming from the chemical transformation undergone by anthocyanins was theoretically explored by DFT/B3LYP methods. The two main working mechanisms (H atom donation and single-electron transfer) were investigated, and the O-H bond dissociation energy (BDE) and ionization potential (IP) parameters were computed in the gas phase and in water and benzene solutions. Results indicated that systems possessing the catechol functionality as well as the o-dimethoxy motif are good candidates to donate a H atom to the free radicals, inactivating them. Compounds with a higher degree of electron delocalization may work within the single-electron transfer mechanism. Results provided molecular insight into factors that influence the radical scavenging potential of anthocyanins and then the beneficial health effects of these wine pigments.

Favored reaction mechanism of calcium-dependent phospholipase A(2). Insights from density functional exploration.

The sn-2 acyl hydrolysis of phospholipids catalyzed by phospholipase A(2) (PLA(2)) was investigated at the density functional B3LYP level. The PLA(2) active site is represented by quantum-chemical models that are based on available X-ray crystal structures. The two still controversial catalytic triad and calcium-coordinated oxyanion reaction mechanisms were considered. Tetrahedral intermediate formation in the first mechanism and the cleavage of the C-O bond in the second one are the rate-determining steps. Both mechanisms, in the gas phase and in the protein-like environment, yielded potential energy profiles with low energy barriers and consequently the comparison did not indicate a clear preference for one or the other path. An alternative mechanism, based on some corrections to the previously suggested ones, provides for an optional pathway for the enzyme activity.

The inactivation of lipid peroxide radical by quercetin. A theoretical insight.

The effectiveness of naturally occurring antioxidant quercetin in the inactivation of the damaging lipid peroxide radical was investigated by means of hybrid density functional based approach, using the direct dynamics method, where the thermal rate constants were calculated using variational transition-state theory with multidimensional tunneling. H-atom abstraction in quercetin by CH(3)OO peroxide occurs preferentially at the 4'OH phenolic site, from both kinetic and thermodynamic points of view. In principle, the narrowness of the obtained adiabatic potential-energy profile makes the occurrence of a significant tunnelling contribution possible. In fact, this contribution enhances the value of the computed rate constant at 300 K from 1.94 x 10(1) to 9.63 x 10(3) M(-1) s(-1) indicating that quercetin is a potent natural antioxidant in trapping and scavenging free radicals.

Determination of the catalytic pathway of a manganese arginase enzyme through density functional investigation.

The catalytic mechanism of dimanganese-containing arginase enzyme has been investigated by DFT calculations. Two exchange-correlation functionals, B3 LYP and MPWB1 K, have been used to construct the potential energy profiles for the hydrolysis of an arginine substrate performed by an arginase active site model system. Two reaction mechanisms have been investigated, one involving a water molecule (mechanism 1) and the other involving a hydroxide ion (mechanism 2) as nucleophilic agent. Results obtained in the gas phase and in the protein environment have indicated that mechanism 1 involving a water molecule entails structural features as well as an activation energy for the rate-determining step that are inconsistent with experimental data available for the arginase enzyme. On the other hand, when a hydroxide ion is present at the Mn2 site, a lower activation energy and a structural arrangement closer to the experimental indication are obtained.

Reaction mechanism of molybdoenzyme formate dehydrogenase.

Formate dehydrogenase is a molybdoenzyme of the anaerobic formate hydrogen lyase complex of the Escherichia coli microorganism that catalyzes the oxidation of formate to carbon dioxide. The two proposed mechanisms of reaction, which differ in the occurrence of a direct coordination or not of a SeCys residue to the molybdenum metal during catalysis were analyzed at the density functional level in both vacuum and protein environments. Some DF functionals, in addition to the very popular B3LYP one, were employed to compute barrier heights. Results revealed the role played by the SeCys residue in performing the abstraction of the proton from the formate substrate. The computation of the energetic profiles for both mechanisms indicated that the reaction barriers are higher when the selenium is directly coordinated to the metal, whereas less energy is required when SeCys is not a ligand at the molybdenum site.

A comparative study of the antioxidant power of flavonoid catechin and its planar analogue.

The antioxidant ability of the flavanol catechin and its planar derivative, catechin 1 (PC1), was explored using the DF/B3LYP theoretical approach. Their potentiality in the hydrogen abstraction and electron transfer reactions, the main working mechanisms of antioxidants, was evaluated by computing the values of two key parameters, which are the OH bond dissociation energy and the ionization potential. Results indicated that the effect of a planar arrangement in the catechin molecule is small in the case of the hydrogen abstraction but greater for the electron transfer, since the in vacuo ionization potential value decreases by about 3 kcal/mol. The reaction of these molecules with the hydroperoxyl radical (*)OOH indicated that the H(*) abstraction is faster with the planar catechin.

Which one among Zn(II), Co(II), Mn(II), and Fe(II) is the most efficient ion for the methionine aminopeptidase catalyzed reaction?

The catalytic hydrolysis of a methionyl-peptide substrate by a methionine aminopeptidase active site model cluster was investigated at the DF/B3LYP level of theory, in the gas-phase and in the protein environment. Zn(II), Co(II), Mn(II), and Fe(II) transition metals were examined as the potential catalytic metals of this enzyme involved in protein maturation. Two different mechanisms in which Glu204 was present as protonated or deprotonated residue were considered. The energetic profiles show lower barriers as the protonated glutamate is involved. The rate-determining step of the hydrolysis reaction is always the nucleophilic addition of the hydroxide on substrate carbon, followed by less energetically demanding methionine-peptide C-N bond scission. The lowest activation energy is obtained in the case of zinc dication while the other metals show very high energetic barriers, so that methionine aminopeptidase can be in principle recognized as a dizinc enzyme.

The preferred reaction path for the oxidation of methanol by PQQ-containing methanol dehydrogenase: addition-elimination versus hydride-transfer mechanism.

The catalytic oxidation of methanol to formaldehyde by pyrroloquinoline quinone (PQQ)-containing methanol dehydrogenase (MDH) was investigated at density functional B3LYP level. The still controversial addition-elimination and hydride-transfer reaction mechanisms were analysed. Computations performed in the gas phase and in the protein environment indicated that both suggested reaction sequences involve very high activation barriers. In this situation, the reactions should have scarce probability to occur and the preference for one of the two paths cannot be stated. Here, we will show how some corrections to the successive steps in the addition-elimination mechanism can sensibly decrease the activation barriers height, making possible the determination of the MDH-preferred catalytic path.

Iron chelation by the powerful antioxidant flavonoid quercetin.

Chelation of the bare and hydrated iron(II) cation by quercetin has been investigated at the DF/B3LYP level in the gas phase. Several complexed species arising from neutral and anionic forms of the ligand have been taken into account. Both 1:1 and 1:2 metal/flavonoid stoichiometries have been considered. Results indicate that among the potential sites of chelation present on quercetin, the oxygen atoms belonging to the 3-hydroxy and 4-oxo, and to the 5-hydroxy and 4-oxo groups, are the preferred ones. Time-dependent density functional theory (TDDFT) calculations, used to reproduce the electronic UV-vis spectra of isolated quercetin and its complexes with Fe2+, were also performed in methanol and dimethylsulfoxide.

Gas and liquid phase acidity of natural antioxidants.

The gas phase and in solution absolute and relative acidities of nine natural systems contained in red and white wines were determined through theoretical B3LYP/6-311++G** calculations. The aim was to correlate these thermodynamic quantities to the ability that some of these compounds show in chelating metals ions to carry out an antioxidant action following a mechanism recently reported in the literature. Results indicated that both absolute and relative values are affected by molecular features such as electronic delocalization and conjugation and intramolecular hydrogen bonds. Polyphenols characterized by the ortho-dihydroxy functionality were found to be good candidates to act as metal cation chelating ligands. Some differences in absolute acidities values were encountered in going from vacuum to water solution.

Role of the metal ion in formyl-peptide bond hydrolysis by a peptide deformylase active site model.

The catalytic mechanism of peptide deformylase enzymes containing zinc, iron, cobalt, and nickel dications was explored in the gas phase and in the protein environment. The study was performed at the density functional level using three model systems to simulate the active site. The work had the aim to evaluate the effect of metal substitution on the hydrolytic properties and the possible different performances of the various catalysts. Results indicated that all of the metallic forms are active to hydrolyze the formyl-peptide bond and that the reaction pathways do not show significant peculiarities on going from a particular metal ion to another. No significant modification of the reaction paths occurs in solvent.

Mechanism of nitrate reduction by Desulfovibrio desulfuricans nitrate reductase--a theoretical investigation.

The oxidative half-reaction of oxygen atom transfer from nitrate to an Mo(IV) complex has been investigated at various levels of theory. Two models have been used to simulate the enzyme active site. In the second, more advanced model, additional amino acid residues capable of significantly affecting the catalytic efficiency of the enzyme were included. B3LYP/6-31+G*, ONIOM, and orbital-free embedding approaches have been used to construct the potential energy profile and to qualitatively compare the results of a QM/MM study with those obtained by a full quantum mechanical strategy. The study has confirmed the utility of the orbital-free embedding method in the description of enzymatic processes.