Miroslav A. Rangelov

Catalytic role of vicinal OH in ester aminolysis: proton shuttle versus hydrogen bond stabilization.

This computational study provoked by the process of peptide bond formation in the ribosome investigates the influence of the vicinal OH group in monoacylated diols on the elementary acts of ester aminolysis. Two alternative approaches for this influence on ester ammonolysis were considered: stabilization of the transition states by hydrogen bonds and participation of the vicinal hydroxyl in proton transfer (proton shuttle). The activation due to hydrogen bonds of the vicinal hydroxyl via tetragonal transition states was rather modest; the free energy of activation was reduced by only 5.2 kcal/mol compared to the noncatalyzed reaction. The catalytic activation via the proton shuttle mechanism with participation of the vicinal OH in the proton transfer via hexagonal transition states resulted in considerable reduction of the free energy of activation to 33.5 kcal/mol, i.e., 16.0 kcal/mol lower than in the referent process. Accounting for the influence of the environment on the reaction center by a continuum model (for ε from 5 to 80) resulted in further stabilization of the rate-determining transition state by 4-5 kcal/mol. The overall reduction of the reaction barrier by about 16 kcal/mol as compared to the noncatalyzed process corresponds to about 10(9)-fold acceleration of the reaction, in agreement with the experimental estimate for acceleration of this process in the ribosome.

Two 6-(propan-2-yl)-4-methyl-morpholine-2,5-diones as new non-purine xanthine oxidase inhibitors and anti-inflammatory agents

Two cyclodidepsipeptides, 3-(2-methylpropyl)-6-(propan-2-yl)-4-methyl-morpholine-2,5-dione (1) and 3,6-di(propan-2-yl)-4-methyl-morpholine-2,5-dione (2), were evaluated for inhibitory activity against commercial enzyme xanthine oxidase (XO) in vitro and XO in rat liver homogenate as well as for anti-inflammatory response on human peripheral blood mononuclear cells (PBMCs). Both of cyclodidepsipeptides were excellent inhibitors of XO and significantly suppressed the nuclear factor of κB (NF-κB) activation. Allopurinol, a widely used XO inhibitor and drug to treat gout, relevated stronger inhibitory effect on rat liver XO activity than those of compounds 1 and 2. Molecular docking studies were performed to gain an insight into their binding modes with XO. The studied morpholine-diones derivatives exerting XO inhibition and anti-inflammatory effect may give a promise to be used in the treatment of gout and other excessive uric acid production or inflammatory conditions.

Ab Initio Molecular Dynamics of Na+ and Mg2+ Countercations at the Backbone of RNA in Water Solution

The interactions between sodium or magnesium ions and phosphate groups of the RNA backbone represented as dinucleotide fragments in water solution have been studied using ab initio Born-Oppenheimer molecular dynamics. All systems have been simulated at 300 and 320 K. Sodium ions have mobility higher than that of the magnesium ions and readily change their position with respect to the phosphate groups, from directly bonded to completely solvated state, with a rough estimate of the lifetime of bonded Na(+) of about 20-30 ps. The coordination number of the sodium ions frequently changes in irregular intervals ranging from several femtoseconds to about 10 ps with the most frequently encountered coordination number five, followed by six. The magnesium ion is stable both as directly bonded to an oxygen atom from the phosphate group and completely solvated by water. In both states the Mg(2+) ion has exactly six oxygen atoms in the first coordination shell; moreover, during the whole simulation of more than 100 ps no exchange of ligand in the first coordination shells has been observed. Solvation of the terminal phosphate oxygen atoms by water molecules forming hydrogen bonds in different locations of the ions is also discussed. The stability of the system containing sodium ions essentially does not depend on the position of the ions with respect to the phosphate groups.

Hierarchical approach to conformational search and selection of computational method in modeling the mechanism of ester ammonolysis

We describe automated procedures for the first stages of a systematic computational investigation of reaction mechanisms. They include (i) selection of computational method and basis set based on statistical analysis of structural and energy data relating to experimental values, (ii) determination of all distinct conformations of transition states with large conformational freedom, and (iii) generation of unknown geometry of the transition states, based on pre-defined connectivity of the atoms involved in the reaction. For the conformational search we employed an efficient procedure for exploration of various possible conformations of the transition states and elimination of the equivalent structures in several steps using molecular-mechanical and quantum-mechanical methods. The procedure was applied to the determination of the structures of transition states and intermediates in the ammonolysis of monoformylated 1,2-ethanediol, which were subsequently used for identification of the lowest energy reaction paths. For the same reaction system we also used the approach for generation of the initial structures of transition states with unknown geometry. The reported procedures are implemented in the MolRan program suite.

Determination of the optimal position of adjacent proton-donor centers for the activation or inhibition of peptide bond formation – A computational model study

The study reports a computational analysis of the influence of proton donor group adjacent to the reaction center during ester ammonolysis of an acylated diol as a model reaction for peptide bond formation. This analysis was performed using catalytic maps constructed after a detailed scanning of the available space around the reaction centers in different transition states, a water molecule acting as a typical proton donor. The calculations suggest that an adjacent proton donor center can reduce the activation barrier of the rate determining transition states by up to 7.2 kcal/mol, while no inhibition of the reaction can be achieved by such a group.