Does Metabolism of (S)-N-[1-(3-Morpholin-4-ylphenyl)ethyl]-3-phenylacrylamide Occur at the Morpholine Ring? Quantum Mechanical and Molecular Dynamics Studies

The mechanism of Cytochrome P450 3A4 mediated metabolism of (S)-N- [1-(3-morpholin-4ylphenyl)ethyl]-3-phenylacrylamide and its difluoro analogue have been investigated by density functional QM calculations aided with molecular mechanics/molecular dynamics simulations. In this article, we mainly focus on the metabolism of the morpholine ring of substrates 1 and 2. The reaction proceeds via a hydrogen atom abstraction from the morpholine ring by Compound I on a doublet potential energy surface. A transition state was observed at an O-H distance of 1.46 Å for 1 while 1.38 Å for 2. Transition state for the rebound mechanism was not observed. The energy barrier for the hydrogen atom abstraction from 1 was found to be 7.01 kcal/mol in gas phase while 19.53 kcal/mol when the protein environment was emulated by COSMO. Similarly the energy barrier for substrate 2 was found to be 11.07 kcal/mol in gas phase while it was reduced to 12.99 kcal/mol in protein environment. Our previous study reported energy barriers for phenyl hydroxylation of 7.4 kcal/mol. Large energy barriers for morpholine hydroxylation indicates that hydroxylation at the phenyl ring may be preferred over morpholine. MD simulations in protein environment indicated that hydrogen atom at C4 position of phenyl ring remains in closer proximity to oxyferryl oxygen of the heme moiety as compared to morpholine hydrogen and hence greater chance to metabolize at phenyl ring

HT2005-72132 LARGE-SCALE QUANTUM CHEMICAL MOLECULAR DYNAMICS SIMULATIONS ON THE FORMATION DYNAMICS OF HYDROGEN BY THE CHEMICAL REACTIONS OF WATER

ABSTRACT We have successfully simulated the chemical reaction dynamics of water molecules on various Si surfaces by using our new tight-binding quantum chemical molecular dynamics method. The formation dynamics of hydrogen molecules from water molecules on Si nano-particle was observed at 300 K. Especially, we found that the surface termination of Si nanoparticle strongly influences the chemical reactions of water molecules and the non-terminated Si surface is the active site for the hydrogen generation. Moreover, we suggest that nanospace of the SiO 2 /Si interface is more active site for the hydrogen generation. INTRODUCTION Hydrogen is expected to be next-generation energy resources because it does not emit any pollutant exhaust gas. Therefore, efficient technology to produce hydrogen from water is strongly demanded in order to realize the sustainable society. A lot of experimental works for the above purpose have been carried out previously. For example, metal oxide photocatalyst such as TiO 2 semiconductor is one of the candidates for the efficient generation of hydrogen from water and many researchers investigated the photocatalytic activity of metal oxide semiconductor

Nature of Copper Active Sites in CuZSM-5: Theory and Experiment

Abstract: We report here a concise resume reporting the way of constructing the model of an active site composed of transition metal cation exchanged in zeolites. The main goal was to devise the model of CuZSM-5 capable of describing geometrical and electronic properties of metal sites and adsorption complexes with small molecules. The models were built up starting from simple ring structures encountered in ZSM-5 framework to fused rings’ model selected as the representative of α position for hosting the exchanged cation. Geometrical and electronic properties of the basal model, composed of the extended framework cluster with Cu+ or Cu2+ cation, and adsorption complexes with diatomic molecules were extracted from DFT calculations. The stress was put here on direct confirmation of structural changes on copper reduction/oxidation and adsorption. Electron donor/acceptor properties of the sites combined with electronic properties of adsorbed molecules led to the proposal for the mechanism of NO activation by Cu+ZSM-5: transfer of electrons from copper d orbitals to antibonding states of NO should cause large weakening of the bond, which was evidenced also by IR measurements

Epimerization and desaturation by carbapenem synthase (CarC). A hybrid DFT study.

The mechanism of the unusual epimerization and desaturation reactions catalyzed by carbapenem synthase was investigated using the hybrid density functional method B3LYP. Several different models have been used in the calculations to study five component reactions. Both protonated and deprotonated models for the substrate have been explored so that the effects of hydrogen bonds could be characterized. Besides the iron site, it is proposed that a some tyrosine residue, possibly Tyr67, is involved in the hydrogen abstraction step. The calculated energetics and barrier heights support this hypothesis, and are consistent with the known experimental data concerning CarC and other 2-oxoglutarate dependent dioxygenases