Subunit-dependent interaction of propoxazepam and its metabolite with the -aminobuturic acid type A receptor

Benzodiazepines (BDZ) are widely used in clinics in the treatment of psychiatric disorders, and their main action is considered to be determined by more selective binding with α1, α2, α3 or α5 subunits of GABA receptor. The aim of this work was studying of the molecular mechanism of action of new analgesic – propoxazepam and its metabolite (3-hydroxypropoxazepam) on α1, α2, α3, α4 or α5 subunits containing GABAA channels. Materials and methods GABA ha1b3g2, ha2b3g2, ha3b3g2, ha4b3g2 and ha5b3g2 ionotropic GABAARs expressed in HEK293 were used on the automated SP384PE Patch Clamp system. In addition, Propoxazepam, 3-hydroxypropoxazepam, diazepam (positive allosteric modulator) and GABA (positive control) were administered at concentrations 0.001–300 nM to determine the EC50 and Emax for corresponding substances. Results The α subunit plays a significantl role in determining the receptor’s affinity for propoxazepam and 3-hydroxypropoxazepam. The rank order of decreasing EC50 are α1 = α5> α2 > α3 > α4 (propoxazepam) and α1> α2> α5 > α3 > α4 (3-hydroxypropoxazepam), and for Emax α3 > α2 >α5 > α1 > α4 (propoxazepam), α3 > α1 > α2> α5 > α4 (3-hydroxypropoxazepam). The data, transformed to Emax/EC50, show that propoxazepam exhibits tenfold (compared to diazepam) activity (taking into account the magnitude of the maximum effect) to the α3 subunit, which distinguishes it from 3-hydroxypropoxazepam. Conclusion Due to the determined selectivity of propoxazepam for binding with different α subunit-containing GABAA-receptors (mostly α3 and α2 types), it has the potential to provide analgesia with less sedation than non-selective BDZ.

METABOLIC PROFILE AND MECHANISMS OF GABA-TARGETED RECEPTOR PROPOXAZEPAM METABOLIZATION IN HUMAN HEPATOCYTES

The aim of this study was to identify the Propoxazepam metabolites, formed by suspension of cryopreserved human hepatocytes, using the precise method of mass LC-MS/MS analysis. Methods. A suitable chromatographic method was developed for the profiling of Propoxazepam and its metabolites. Samples were analyzed using a Waters Vion high resolution LC-MS/MS instrument, and data were examined using Waters Unifi software to determine the identity of the most abundant metabolites. Following a 4-hour incubation with human hepatocytes, intact Propoxazepam molecule accounted for 96.0% of the profile. Its most abundant metabolite was the oxidize. Results. Propoxazepam (3-hydroxyderivative), which accounted for approximately 2.5% of the total peak response in the 4-hour sample. Two minor components were also found, each accounting for < 10% of the total peak response. Glucuronic conjugates have not been found under the experimental conditions. All metabolites formed represented less than 10% of the total chromatographic peak response. Coclusion. The data obtained indicate the absence of reactive electrophilic derivatives among the metabolites of Propoxazepam.