Enhancing the function of alpha5-subunit-containing GABAA receptors promotes action potential firing of neocortical neurons during up-states.

Neocortical neurons mediate the sedative and anticonvulsant properties of benzodiazepines. These agents enhance synaptic inhibition via positive modulation of γ-aminobutyric acid (GABAA) receptors harboring α1-, α2-, α3- or α5-protein subunits. Benzodiazepine-sensitive GABAA receptors containing the α5-subunit are abundant in the neocortex, but their impact in controlling neuronal firing patterns is unknown. Here we studied how the discharge rates of cortical neurons are modified by a positive (SH-053-2'F-R-CH3) and a negative (L 655,708) α5-subunit-preferring allosteric modulator in comparison to diazepam, the classical non-selective benzodiazepine. Drug actions were characterized in slice cultures from wild-type and α5(H105R) knock-in mice by performing extracellular multi-unit-recordings. In knock-in mice, receptors containing the α5 subunit are insensitive to benzodiazepines. The non-selective positive allosteric modulator diazepam decreased the discharge rates of neocortical neurons during episodes of ongoing neuronal activity (up states). In contrast to diazepam, the α5-preferring positive modulator SH-053-2'F-R-CH3 accelerated action potential firing during up states. This promoting action was absent in slices from α5(H105R) mice, confirming that it is mediated by the α5-subunit. Consistent with these observations, the negative α5-selective modulator L 655,708 inhibited up state action potential activity in slices from wild-type mice. The opposing actions of diazepam and SH-053-2'F-R-CH3, which both enhance GABAA receptor function but differ in subtype-selectivity, uncovers contrasting roles of GABAA receptor subtypes in controlling the firing rates of cortical neurons. These findings may have important implications for the design of novel anaesthetic and anticonvulsant benzodiazepines displaying an improved efficacy and fewer side effects.

Anaesthetic potency of diazepam is resistant to cholinergic overstimulation.

Patients suffering from organophosphorus intoxication are compromised by generalised seizures and respiratory insufficiency, either being potentially lethal. In these patients induction of general anaesthesia to allow artificial ventilation is an important therapeutic option. Previously, it has been demonstrated that cholinergic overstimulation impaired network depressing effects of etomidate and sevoflurane. In this study we tested the impact of cholinergic overstimulation on inhibitory effects of diazepam in organotypic slice cultures of cerebrocortical neurons. Effects of clinically relevant concentrations of diazepam on spontaneous action potential activity were assessed by extracellular action potential recordings under basal cholinergic tone as well as in the presence of acetylcholine (1 µM). Diazepam at anaesthetic concentrations (25-500 µM) impeded spontaneous network activity in a concentration dependent manner (EC50 80.5±8.0 µM). In the presence of 1 µM acetylcholine the potency of diazepam was not significantly altered (EC50 83.6±8.4 µM). The results demonstrate that the potency of diazepam to depress neocortical network-excitability is not significantly impaired by cholinergic overstimulation. Diazepam thereby differs from other anaesthetics like etomidate or sevoflurane whose potencies and efficacies were severely attenuated. Hence diazepam might be preferable for induction and maintenance of general anaesthesia in patients suffering from nerve agent intoxication.

Diazepam decreases action potential firing of neocortical neurons via two distinct mechanisms.

BACKGROUND: Benzodiazepines are widely used in clinical anesthesia as premedication, but also to induce general anesthesia. Recent in vitro studies suggest that γ-aminobutyric acid type A receptors, harboring a classical high-affinity benzodiazepine binding site, possess another "nonclassical" binding site for benzodiazepines. At present, it is unclear if, and to what extent, this novel nonclassical binding site is of relevance for the actions of benzodiazepines in the central nervous system. METHODS: Because neocortex is involved in mediating the sedative and hypnotic properties of general anesthetics, we quantified the actions of diazepam over a wide range of concentrations (from 10 nM up to 100 µM) in organotypic slice cultures using extracellular multiunit recordings of spontaneous action potential activity. RESULTS: Up to a concentration of 6.25 µM, diazepam reduced the activity of neocortical neurons, approaching a maximum of approximately 20%. This action was nullified by the benzodiazepine antagonist flumazenil. At concentrations >12.5 µM, diazepam evoked a second concentration-dependent dampening of network activity. Unlike the low concentration effect, this high concentration component was resistant to flumazenil. CONCLUSIONS: Diazepam induced a biphasic attenuation of spontaneous action potential firing of neocortical neurons. Low to moderate concentrations caused a monotonic, mild depression that is mediated via the classical binding site as it is antagonized by flumazenil. However, the effects of diazepam observed at high concentrations were not affected by flumazenil. Hence, these findings support the concept of at least 2 different binding sites for benzodiazepines on γ-aminobutyric acid type A receptors. Furthermore, our results are consistent with the hypothesis that the classical high-affinity binding site mediates low-dose diazepam actions, such as amnesia, anxiolysis, and sedation, while a second, nonclassical and independent site contributes to the anesthetic effects of diazepam, such as hypnosis and immobility.