Profiling of GABAA and GABAB receptor expression in the myometrium of the human uterus.

AIMS: γ-aminobutyric acid (GABA) mediates its physiological effects through the GABAA and GABAB receptors. In this study the putative expression of GABAAR and GABABR subunits in human myometrium tissue was investigated. MAIN METHODS: The expression levels of the 19 GABAAR subunits (α1-α6, ß1-ß3, γ1-γ3, δ, ε, π, θ, ρ1-ρ3) and the three GABABR subunits (GABAB1a, GABAB1b, GABAB2) were characterized by RT-qPCR analysis on two commercial samples and six samples derived from surgically removed myometrial tissues from different women. We probed for functional GABAAR expression in primary human myometrial smooth muscle cells (HMSMCs) by whole-cell patch-clamp electrophysiology. KEY FINDINGS: The absolute mRNA levels of the 22 GABAAR and GABABR genes varied considerably across the eight samples, but a pronounced overlap existed between the specific subunits detected in the samples, with α2, ß2, ß3, ε, π, θ, GABAB1a and GABAB1b mRNAs being detected in most samples. The expression profile of GABAAR and GABABR subunit mRNAs in HMSMCs correlated with that observed in the eight tissue samples, albeit the subunit transcripts were detected at lower relative levels. Neither muscimol nor GABA evoked significant currents in these cells in the patch-clamp recordings. SIGNIFICANCE: While the expression of the GABAB1 subunits on their own is unlikely to give rise to functional GABABR expression, the GABAAR subunits identified at mRNA level would be able to form functional receptors in the human myometrial tissue. Although GABAAR-mediated currents could not be recorded from HMSMCs in this study, this suggests a role for GABAergic transmission in the human myometrium.

Probing the molecular basis for affinity/potency- and efficacy-based subtype-selectivity exhibited by benzodiazepine-site modulators at GABAA receptors.

The extracellular α(+)/γ2(-) interface in the α1,2,3,5ßγ2 GABAA receptor harbours the allosteric binding site targeted by benzodiazepines and newer generations of subtype-selective modulators. We have probed the molecular determinants for the affinity/potency-based α1-preference exhibited by the hypnotic zolpidem (Ambien®, Stilnox®) and the efficacy-based α3-over-α1 selectivity displayed by the analgesic NS11394. Binding affinities and functional properties of the modulators were characterized at wild-type, concatenated, mutant and chimeric α1,3ß2γ2S receptors expressed in tsA201 cells and Xenopus oocytes by [3H]flumazenil binding and two-electrode voltage clamp electrophysiology. Substitution of Gly201 in α1 with the corresponding Glu in α3 completely eliminated the α1-over-α3 preference exhibited by zolpidem. In contrast, the reverse α3-E225G mutation did not yield corresponding increases in the binding affinity or modulatory potency of zolpidem at α3ß2γ2S, and two additional molecular elements in the extracellular domain of the α-subunit were found also to contribute to its α1-preference. Interestingly, the α1-Gly201/α3-Glu225 residue was also a key determinant of the efficacy-based α3-over-α1 selectivity exhibited by NS11394, and a pronounced correlation existed between the side-chain bulkiness of this residue and the modulatory efficacy of NS11394 at the receptor. The subtype-selectivity determinants identified for zolpidem and NS11394 were found also to apply in different degrees to the α1-preferring modulator indiplon and the α3-over-α1 selective modulator L-838,417, respectively. In conclusion, the molecular origins of subtype-selectivity exhibited by benzodiazepine-site modulators at the α1,2,3,5ßγ2 GABAA receptor seem more complex than previously appreciated, and the importance of the α1-Gly201/α3-Glu225 residue for both potency- and efficacy-based subtype-selective modulation through this site is likely to be rooted in different molecular mechanisms.

Delineation of the functional properties and the mechanism of action of AA29504, an allosteric agonist and positive allosteric modulator of GABAA receptors.

The retigabine analog 2-amino-4-[(2,4,6-trimethylbenzylamino)-phenyl]-carbamic acid ethyl ester (AA29504) is a positive allosteric modulator (PAM) of γ-aminobutyric acidA receptors (GABAARs), and the modulator has been used in ex vivo/in vivo studies to probe the physiological roles of native δ-containing GABAARs. In this study, the functional properties and mode of action of AA29504 were investigated at human GABAARs expressed in Xenopus oocytes by two-electrode voltage clamp electrophysiology. AA29504 was found to be an allosteric GABAAR agonist displaying low intrinsic activities at 3-30 µM. AA29504 was essentially equipotent as a PAM at the 13 GABAAR subtypes tested (EC50: 0.45-5.2 µM), however GABA EC5-evoked currents through αßδ subtypes were modulated to substantially higher levels than those through αßγ2S subtypes (relative to GABA Imax). While the δ/γ2S-difference clearly was key for this differential GABA efficacy modulation, studies of the AA29504-mediated modulation of different α4,5,6-containing αß, αßγ2S and αßδ GABAARs revealed the α-subunit identity to be another important determinant. Based on its functional properties at numerous mutant GABAARs and on in silico analysis of its low-energy conformations, AA29504 is proposed to act through an allosteric site in the transmembrane ß(+)/α(-) interface in the GABAAR also targeted by etomidate and several other modulators. In contrast to these modulators, however, AA29504 did not display substantial ß2/ß3-over-ß1 GABAAR preference, which challenges the notion of ligands targeting this site always possessing this subtype-selectivity profile. Hence, the detailed pharmacological profiling of AA29504 both highlights the complexity of allosteric GABAAR modulation and provides valuable information about this modulator as a pharmacological tool.

Functional properties and mechanism of action of PPTQ, an allosteric agonist and low nanomolar positive allosteric modulator at GABAA receptors.

The former sedative-hypnotic and recreational drug methaqualone (Quaalude) is a moderately potent, non-selective positive allosteric modulator (PAM) at GABAA receptors (GABAARs) (Hammer et al., 2015). In the present study, we have identified a novel methaqualone analog, 2-phenyl-3-(p-tolyl)quinazolin-4(3H)-one (PPTQ), in a screening of 67 analogs at five αß2γ2S GABAAR subtypes and delineated its functional properties and mechanism of action at wild-type and mutant GABAARs expressed in Xenopus laevis oocytes by two-electrode voltage clamp electrophysiology. PPTQ was found to be an allosteric agonist and a PAM (ago-PAM) at human α1ß2γ2S and α4ß2δ GABAARs, exhibiting intrinsic activity at micromolar concentrations and potentiating the GABA-evoked signaling through the receptors at concentrations down to the low-nanomolar range. Whereas PPTQ exclusively increased the potency of GABA at the α1ß2γ2S receptor, it increased both GABA potency and efficacy at α4ß2δ and displayed modest potency-based preference for α4ß2δ over α1ß2γ2S. In elaborate mutagenesis and competition experiments PPTQ was found to act through the same or an overlapping site as etomidate in the transmembrane ß(+)/α(-) subunit interfaces, whereas it did not seem to target the other three transmembrane interfaces in the GABAAR. Finally, the PPTQ site was shown to be allosterically linked with sites targeted by neurosteroids and barbiturates but not with the high-affinity benzodiazepine site in the α1ß2γ2S receptor. In conclusion, the development of a highly potent, bioavailable GABAAR ago-PAM by subtle modifications to the methaqualone scaffold demonstrates that derivatization of this infamous drug from the past can lead to modulators with distinct functional characteristics at the receptors.