Oxygen activation by the noncoupled binuclear copper site in peptidylglycine alpha-hydroxylating monooxygenase. Reaction mechanism and role of the noncoupled nature of the active site

Reaction thermodynamics and potential energy surfaces are calculated using density functional methods to investigate possible reactive Cu/O(2) species for H-atom abstraction in peptidylglycine alpha-hydroxylating monooxygenase (PHM), which has a noncoupled binuclear Cu active site. Two possible mononuclear Cu/O(2) species have been evaluated, the 2-electron reduced Cu(II)(M)-OOH intermediate and the 1-electron reduced side-on Cu(II)(M)-superoxo intermediate, which could form with comparable thermodynamics at the catalytic Cu(M) site. The substrate H-atom abstraction reaction by the Cu(II)(M)-OOH intermediate is found to be thermodynamically accessible due to the contribution of the methionine ligand, but with a high activation barrier ( approximately 37 kcal/mol, at a 3.0-A active site/substrate distance), arguing against the Cu(II)(M)-OOH species as the reactive Cu/O(2) intermediate in PHM. In contrast, H-atom abstraction from substrate by the side-on Cu(II)(M)-superoxo intermediate is a nearly isoenergetic process with a low reaction barrier at a comparable active site/substrate distance ( approximately 14 kcal/mol), suggesting that side-on Cu(II)(M)-superoxo is the reactive species in PHM. The differential reactivities of the Cu(II)(M)-OOH and Cu(II)(M)-superoxo species correlate to their different frontier molecular orbitals involved in the H-atom abstraction reaction. After the H-atom abstraction, a reasonable pathway for substrate hydroxylation involves a "water-assisted" direct OH transfer to the substrate radical, which generates a high-energy Cu(II)(M)-oxyl species. This provides the necessary driving force for intramolecular electron transfer from the Cu(H) site to complete the reaction in PHM. The differential reactivity pattern between the Cu(II)(M)-OOH and Cu(II)(M)-superoxo intermediates provides insight into the role of the noncoupled nature of PHM and dopamine beta-monooxygenase active sites, as compared to the coupled binuclear Cu active sites in hemocyanin, tyrosinase, and catechol oxidase, in O(2) activation.     

Relationship of the three dimensional structure of carboxypeptidase A to catalysis : Possible intermediates and pH effects

A brief discussion is presented of activity, conformational changes, possible mechanisms, intermediates, and pH effects in the peptidase activity of the hydrolytic enzyme, carboxypeptidase A.     

PreSSAPro: a software for the prediction of secondary structure by amino acid properties

PreSSAPro is a software, available to the scientific community as a free web service designed to provide predictions of secondary structures starting from the amino acid sequence of a given protein. Predictions are based on our recently published work on the amino acid propensities for secondary structures in either large but not homogeneous protein data sets, as well as in smaller but homogeneous data sets corresponding to protein structural classes, i.e. all-alpha, all-beta, or alpha–beta proteins. Predictions result improved by the use of propensities evaluated for the right protein class. PreSSAPro predicts the secondary structure according to the right protein class, if known, or gives a multiple prediction with reference to the different structural classes. The comparison of these predictions represents a novel tool to evaluate what sequence regions can assume different secondary structures depending on the structural class assignment, in the perspective of identifying proteins able to fold in different conformations. The service is available at the URL http://bioinformatica.isa.cnr.it/PRESSAPRO/.     

Localization of electrochemically generated radicals as a function of their structure and the nature of the solvent

The electrooxidation of different perfluorocarboxylic acids has been investigated in the presence of ethylene, on electrodes with different adsorbing power [platinum and glassy carbon (GC)] in different solvents. It has been shown that the reaction zone of the ECG radicals is determined by their solubility; depending on this, it can be limited to the electrode surface or encompass the entire volume of the solution. The concept of the solubility of the ECG radicals made it possible to establish some regularities in the formation of cross combination products in the Kolbe electrosynthesis of different perfluorocarboxylic acids.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 5, pp. 1134–1141, May, 1991.     

On the role of Ti(IV) as a Lewis acid in the chemistry of titanium zeolites: Formation, structure, reactivity, and aging of Ti-peroxo oxidizing intermediates. A first principles study

The ethylene epoxidation cycle in a H2O2/H2O-loaded Ti zeolite has been simulated by a Car-Parrinello approach. Results indicate a process where the zeolitic framework is the active oxygen mediator. The dissociative chemisorption of H2O2 leads, via a transient Ti-hydroperoxo species, to H2O and a Ti-peroxo zeolite intermediate. Transfer of active oxygen to ethylene follows, giving the epoxide and recovering the catalyst. A thorough theoretical characterization indicates that the active oxidizing species is an asymmetric eta2-Ti-peroxo, absorbing in the visible range. The lability of the intermediate is found related to eta2 <--> eta1 interconversions of the Ti-peroxo structure. The interconversions, triggered by water molecules, could account for the experimentally found reduced catalytic activity in aged TS-1 catalysts. The results provide a microscopic picture of the reactivity and dehydration/aging processes of the catalyst fully consistent with experiments and highlight the fundamental role of the Lewis acid character of Ti in the formation, reactivity, and degradation of the active oxidizing species.     

Reaction mechanism of oxidation, hydroxylation, and epoxidation by hypofluorous acid: a theoretical study of unusual H-bond-assisted catalysis

The oxidation of organic molecules by hypofluorous acid (HOF) was studied extensively and systematically by Rozen et al. Therefore, it seems appropriate to refer to the process as Rozen oxidation. An entire set of model molecules was selected for quantum chemical investigation of the oxidation mechanism: a C=C double bond in ethylene, sulfur and selenium in dimethyl derivatives, nitrogen and phosphorus in trimethyl derivatives, as well as methyl azides. In the gas phase, van der Waals complexes between HOF and the previously mentioned species easily are formed, but these complexes are reluctant to undergo oxidation. The addition of another HOF molecule connected with the formation of a cyclic complex (i.e., substrate and two molecules of HOF) seems to be decisive for the oxidation process. The attempt to substitute the second HOF molecule with H2O demonstrated the superiority of HOF. Complexes of this kind decompose along the reaction path smoothly (i.e., with a low activation energy) to the respective oxidation product. A potential role of the hydroxyl cation (HO+) in the oxidation step is mentioned. Besides an oxidation product, one HOF molecule is released (an essential feature of catalysis), and furthermore, hydrogen fluoride is formed. It was suggested by Sertchook et al. (J. Phys. Chem. A 2006, 110, 8275) that the interaction between the substrate to be oxidized and HOF is catalytically influenced by the HF molecule. The mechanism suggested here is more feasible and, particularly at the early stages of the oxidation process, decisive. Also, the role of acetonitrile, used as a solvent by Rozen et al., is discussed in terms of a continuum model. Moreover, passing from potential energies to Gibbs energies is considered.     

Geometrical control of the active site electronic structure of pyranopterin enzymes by metal-dithiolate folding: aldehyde oxidase

Density functional calculations on geometry-optimized oxidized (Mo(VI)) and reduced (Mo(IV)) analogues of the isolated active site of aldehyde oxidase (MOP), a member of the xanthine oxidase family of pyranopterindithiolate enzymes, show that fold angle changes of the dithiolate ligand modulate the relative metal and dithiolate contributions to the frontier redox orbitals. Proton abstraction from the equatorial aqua ligand of the oxidized Mo(VI) site also flattens the metal dithiolate fold angle. It is proposed that static and/or dynamic changes in the structure of the protein surrounding the active site can induce changes in the dithiolate fold angle and thereby provide a mechanism for electronic buffering of the redox orbital, for fine-tuning the nucleophilicity of the equatorial aqua/hydroxide ligand, and for modulating the electron-transfer regeneration of the active sites of molybdenum and tungsten enzymes via a "dithiolate folding effect".     

On the activation of molecular hydrogen by gold: a theoretical approximation to the nature of potential active sites

The study of adsorption and dissociation of molecular hydrogen on single crystal Au(111) and Au(001) surfaces, monoatomic rows in an extended line defect and different Au nanoparticles by means of DF calculations allows us to firmly conclude that the necessary and sufficient condition for H2 dissociation is the existence of low coordinated Au atoms, regardless if they are in nanoparticles or at extended line defects.     

Protease catalysis mediated by a substrate mimetic: a novel enzymatic approach to the synthesis of carboxylic acid amides

We present a protease-based method for the coupling of non-coded and non-amino-acid-derived amines with carboxy components. The key feature of this approach is the combination of the substrate-mimetic strategy with the ability of the cysteine protease clostripain to accept a wide spectrum of amines. Firstly, we tested the use of the 4-guanidinophenyl ester leaving group to mediate acceptance of non-coded and non-amino-acid-derived acyl residues. This employed beta-amino acid and simple carboxylic acid moieties as acyl donors, and several amino acid and peptide units as acyl acceptors. The study was completed by the use of non-amino-acid-derived acyl acceptors comprising simple amines, amino alcohols, and diamines. The results indicate that the approach presented is a useful strategy for the synthesis of peptide isosteres, peptide analogues, and organic amides. These last open a new range of synthetic applications of proteases completely beyond peptide synthesis, achieving efficient and selective acylations of non-amino-acid-derived amines under extraordinarily mild reaction conditions.     

Structures and energetics of models for the active site of acetyl-coenzyme a synthase: role of distal and proximal metals in catalysis

Acetyl-coenzyme A (CoA) synthase/carbon monoxide dehydrogenase (ACS/CODH) is a bifunctional enzyme that generates CO from carbon dioxide in the C-cluster of the beta subunit and synthesizes acetyl-CoA from carbon monoxide (CO), CoA, and CH3+ at the active site of the A-cluster in the alpha subunit. On the basis of density functional calculations, we predict that methylation of Nip occurs first, and CO then adds to the NipII-CH3 species to form the intermediate, NipII(CO)(CH3), in which Nip deligates one of its SNid bonds. The CO-insertion/CH3-migration occurs on one metal, the proximal Ni, forming the trigonal planar NipII-acetyl intermediate. The thiolate can bind to NipII and reductively eliminate the thioester. Our calculations disfavor the unprecedented bimetallic CO-insertion/CH3-migration. Ni in the proximal site produces a better catalyst than does Cu.     

Reaction mechanism of uracil bromination by HBrO: a new way to generate the enol-keto form of 5-bromouracil

Knowledge on the uracil bromination reaction is helpful for understanding the origin of the mutagenicity of 5-bromouracil (BrU). To get more details about this reaction, we explore the corresponding reaction mechanism by theoretical method. A total of seven pathways were studied for this purpose. The diketo form of BrU is observed as the main product in these pathways, which agrees well with experimental results. The most energy-favorable reaction pathway is found to be that Br and OH attacked the opposite sides of uracil. The reaction intermediate reported in the experiment is predicted to be reasonably stable. In the following step, a dehydration process occurs between H11 and O13-H14 when there are no explicit H(2)O taking part. However, when there are explicit water molecules in the environment, explicit H(2)O will lower the reaction barrier in the formation of reaction intermediates and the final product BrU. A proton-transfer process from C5 to O10 is facilitated by explicit H(2)O, which results in enol-keto form intermediate of this modified base (defined as BrU*). These results indicate a new way to generate the enol-keto form of BrU.     

Statistical representation of atomic systems structure. I. Total binding energy as a function of the relative information content

A nonorbital representation of the many-electron atomic systems is proposed. It is obtained by considering a certain equivalence class of mappings ?: ? → Π from the set ? of N electrons into the set Π of Z protons. Total binding energy of the systems (Z = 3,4,…, 18; Z ? N = k = 0, 1,…, 8) arranged according to the Periodic Table criterion, turns out to be the linear function of ZI_r, where I_r is an information functional related to our representation.