THE ROLE OF CYTOCHROME P450 ISOFORMS OF HEPATOCYTE ENDOPLASMIC RETICULUM IN ETHANOL METABOLISM

Background. Three metabolic pathways that can function simultaneously are known to be involved in ethanol oxidation in the liver: alcohol dehydrogenase pathway, microsomal ethanol-oxidizing system, and catalase pathway. Though the cytochrome P450-dependent microsomal ethanol-oxidizing system plays an insignificant role in metabolism of small amounts of ethanol, it is induced in case of ethanol excess and becomes essential when ethanol is abused. The main components of this system are cytochrome P450 (CYP) isoforms of smooth endoplasmic reticulum. Objective. To characterize the role of the key isoforms of cytochrome P450 in ethanol oxidation. Material and methods. We carried out an analysis of modern literature data on the role of the main isoforms of cytochrome P450 in liver metabolism of ethanol. Results. Data on the primary role of cytochrome CYP2E1 in ethanol metabolism, as well as on the contribution of isoforms CYP1A2, CYP2B1/2, CYP2C, CYP3A4, CYP4B1 to ethanol oxidation are presented. Conclusions. Ethanol is metabolized by many CYPs of endoplasmic reticulum of hepatocytes. The importance of CYP in biotransformation processes in the liver necessitates the study of the role of individual CYP isoforms in ethanol metabolism for predicting changes in the pharmacokinetics of drugs and metabolism of endogenous compounds under the influence of ethanol.

Biosynthesis of lactones from diols mediated by an artificial flavin

Background Lactones are important compounds in the field of medicine, material and chemical industry. One of the promising accesses to these flexible scaffolds is NAD(P)+-dependent alcohol dehydrogenases-catalyzed oxidative lactonization of diols, which relies on the construction of an efficient NAD(P)+ regeneration system. Results In this study, a novel system combining horse liver alcohol dehydrogenase (HLADH) with the synthetic bridged flavin cofactor was established for biosynthesis of lactones. The reaction conditions of this system were optimized and a variety of lactones including chiral lactones were efficiently obtained from various diols. Compared to the previously reported NAD(P)+-regeneration systems, this system showed better regeneration efficiency and product yield. A two-phase system was further applied to solve the problem of product inhibition, and 80% yield was obtained at the condition of 300 mM substrate. Conclusions This study provides an efficient method to synthesis of lactones from diols under mild conditions. We believe this system will be a promising alternative to promote the synthesis of other valuable compounds. Graphic abstract

Electric field orientations in solution and enzyme active site revealed by a two-directional vibrational probe

The catalytic power of an electric field depends on its magnitude and orientation with respect to the reactive chemical species. Understanding and designing new catalysts for electrostatic catalysis thus requires methods to measure the electric field orientation and magnitude at the molecular scale. We demonstrate that electric field orientations can be extracted using a two-directional vibrational probe by exploiting the vibrational Stark effect of both the C=O and C-D stretches of a deuterated aldehyde. Combining spectroscopy with molecular dynamics and electronic structure partitioning methods, we demonstrate that despite distinct polarities, solvents act similarly in their preference for electrostatically stabilizing large bond dipoles at the expense of destabilizing small ones. In contrast, we find that for an active site aldehyde inhibitor of liver alcohol dehydrogenase, the electric field orientation deviates markedly from that found in solvents, providing direct evidence for the fundamental difference between the electrostatic environments of solvents and a preorganized enzyme active site.

Biosynthesis of Lactones From Diols Mediated by an Artificial Flavin

Background: Lactones are important compounds in the field of medicine, material and chemical industry. One of the promising accesses to these flexible scaffolds is NAD(P)+-dependent alcohol dehydrogenases-catalyzed oxidative lactonization of diols, which relies on the construction of an efficient NAD(P)+ regeneration system. Results: In this study, a novel system combining horse liver alcohol dehydrogenase (HLADH) with the synthetic bridged flavin cofactor was established for biosynthesis of lactones. The reaction conditions of this system were optimized and a variety of lactones including chiral lactones were efficiently obtained from various diols. Compared to the previously reported NAD(P)+-regeneration systems, this system showed better regeneration efficiency and product yield. A two-phase system was further applied to solve the problem of product inhibition, and 80% yield was obtained at the condition of 300 mM substrate.Conclusions: This study provides an efficient method to synthesis of lactones from diols under mild conditions. We believe this system will be a promising alternative to promote the synthesis of other valuable compounds.

1,4-NADH Biomimetic Co-Factors with Horse Liver Alcohol Dehydrogenase (HLADH), Utilizing [Cp*Rh(bpy)H](OTf) for Co-factor Regeneration, Do in Fact, Produce Chiral Alcohols from Reactions with Achiral Ketones

In this Catalysts Comment Article, we will present our latest published results [...]

An effective hybrid strategy for converting rice straw to furoic acid by tandem catalysis via Sn-sepiolite combined with recombinant E. coli whole cells harboring horse liver alcohol dehydrogenase

The upgrading of biomass-derived furfural into high-value bio-based chemicals has attracted interest.