loreclezole and alphaxalone

When the vertebrate retina is stimulated by light, a class of amacrine or interplexiform cells release dopamine, a modulator responsible for neural adaptation to light. In the intact retina, dopamine release can be pharmacologically manipulated with agonists and antagonists at GABA(A) receptors, and dopaminergic (DA) cells receive input from GABAergic amacrines. Because there are only 450 DA cells in each mouse retina and they cannot be distinguished in the living state from other cells on the basis of their morphology, we used transgenic technology to label DA cells with human placental alkaline phosphatase, an enzyme that resides on the outer surface of the cell membrane. We could therefore identify DA cells in vitro after dissociation of the retina and investigate their activity with whole cell voltage clamp. We describe here the pharmacological properties of the GABA(A) receptors of solitary DA cells. GABA application induces a large inward current carried by chloride ions. The receptors are of the GABA(A) type because the GABA-evoked current is blocked by bicuculline. Their affinity for GABA is very high with an EC(50) value of 7.4 microM. Co-application of benzodiazepine receptor ligands causes a strong increase in the peak current induced by GABA (maximal enhancement: CL-218872 220%; flunitrazepam 214%; zolpidem 348%) proving that DA cells express a type I benzodiazepine-receptor (BZ1). GABA-evoked currents are inhibited by Zn(2+) with an IC(50) of 58.9 +/- 8.9 microM. Furthermore, these receptors are strongly potentiated by the modulator alphaxalone with an EC(50) of 340 +/- 4 nM. The allosteric modulator loreclezole increases GABA receptor currents by 43% (1 microM) and by 107% (10 microM). Using outside-out patches, we measured in single-channel recordings a main conductance (29 pS) and two subconductance (20 and 9 pS) states. We have previously shown by single-cell RT-PCR and immunocytochemistry that DA cells express seven different GABA(A) receptor subunits (alpha1, alpha3, alpha4, beta1, beta3, gamma1, gamma2(S), and gamma2(L)) and by immunocytochemistry that all subunits are expressed in the intact retina. We show here that at least alpha1, beta3 and gamma2 subunits are assembled into functional receptors.

Topics: Alkaline Phosphatase; Animals; Benzodiazepines; Bicuculline; Binding Sites; Dopamine; Dose-Response Relationship, Drug; GABA Antagonists; GABA-A Receptor Antagonists; gamma-Aminobutyric Acid; Humans; Mice; Mice, Transgenic; Neurons; Osmolar Concentration; Patch-Clamp Techniques; Picrotoxin; Pregnanediones; Protein Isoforms; Receptors, GABA-A; Retina; Sesterterpenes; Triazoles; Zinc

Human NT2 teratocarcinoma cells differentiate into neuron-like NT2-N cells when treated with retinoic acid. GABA evoked concentration-dependent whole-cell currents in NT2-N cells with an EC50 of 21.8 microM and a Hill slope of 1.2. GABAA receptor (GABAR) currents reversed at ECl- and did not display voltage-dependent rectification. GABAR single channels opened in bursts to a 23 pS main conductance level and a 19 pS subconductance level, with infrequent openings to a 27 pS conductance level. Kinetic properties of the main conductance level were similar to other native and recombinant GABAR channels. Diazepam and zolpidem enhanced GABAR currents with moderate affinity, whereas methyl-6, 7-dimethoxy-4-ethyl-beta-carboline-3-carboxylate inhibited GABAR currents. Loreclezole enhanced GABAR currents with high affinity, but furosemide antagonized GABAR currents with low affinity. The neurosteroids alphaxalone and pregnenolone sulfate appropriately modulated GABAR currents. Zinc blocked GABAR currents with low affinity, but lanthanum did not significantly alter NT2-N GABAR currents. Reverse transcription PCR (RT-PCR) performed on RNA from NT2-N cells clearly detected transcripts encoding human alpha2, alpha3, alpha5, beta3, gamma3, and pi subtypes. The combined pharmacological and RT-PCR results are most consistent with a single or predominant GABAR isoform composed of an alpha2 and/or alpha3 subtype combined with the beta3 and gamma3 subtypes. The data do not rule out receptors containing combinations of alpha2 and/or alpha3 subtypes with the alpha5 subtype or receptors with both beta1 and beta3 subtypes. The presence or absence or the pi subunit in functionally expressed receptors could not be determined.

Topics: Anticonvulsants; Bicuculline; Carbolines; Convulsants; Diazepam; Diuretics; DNA Primers; Furosemide; GABA Modulators; GABA-A Receptor Agonists; GABA-A Receptor Antagonists; gamma-Aminobutyric Acid; Humans; Hypnotics and Sedatives; Lanthanum; Neurons; Patch-Clamp Techniques; Pentobarbital; Phenobarbital; Picrotoxin; Polymerase Chain Reaction; Pregnanediones; Pregnenolone; Pyridines; Receptors, GABA-A; RNA, Messenger; Teratocarcinoma; Triazoles; Tumor Cells, Cultured; Zinc; Zolpidem

The effects of loreclezole on the function of the gamma-aminobutyric acid type A (GABAA) receptor complex in rat cerebral cortical membrane preparations were compared with those of propofol and diazepam. Loreclezole and propofol modulated [3H]muscimol binding and t-[35S]butylbicyclophosphorothionate ([35S]TBPS) binding to washed and unwashed membranes with potencies and efficacies greater than those of diazepam. Loreclezole and propofol enhanced [3H]flunitrazepam binding to washed membranes with efficacies lower than those of GABA and muscimol. Both loreclezole and propofol showed biphasic effects on [35S]TBPS binding to washed membranes: at low concentrations (5 to 10 microM), both drugs, with different efficacies, enhanced [35S]TBPS binding whereas, at higher concentrations (30 to 100 microM), they inhibited this biochemical parameter. In contrast, diazepam enhanced [35S]TBPS binding to washed membranes at all concentrations tested. The combination of loreclezole with GABA, at a concentration (0.3 microM) that only slightly increased [35S]TBPS binding to washed membranes, reversed the increase in binding elicited by loreclezole (5 to 10 microM) and significantly potentiated the inhibitory effect exerted by higher concentrations (30 to 100 microM) of this drug. Similar effects were observed with the combination of GABA and propofol. However, GABA had no effect on the enhancement of [35S]TBPS binding induced by diazepam. The ability of GABA to reverse and potentiate the effects of loreclezole and propofol on [35S]TBPS binding to washed membranes was shared by pentobarbital (200 microM) and alphaxalone (3 microM). These anesthetics showed greater efficacies in combination with pentobarbital (200 microM) and alphaxalone (3 microM). These anesthetics showed greater efficacies in combination with propofol than with loreclezole. These results suggest that, unlike diazepam, loreclezole and propofol may activate the receptor-associated Cl- channel in the absence of GABA. Furthermore, the difference in the pharmacological profiles of loreclezole and propofol may result from their different effectiveness in activating the receptor Cl- channel directly.

Topics: Anesthetics; Animals; Anticonvulsants; Brain; Bridged Bicyclo Compounds, Heterocyclic; Diazepam; Flunitrazepam; GABA Modulators; gamma-Aminobutyric Acid; Hypnotics and Sedatives; In Vitro Techniques; Male; Muscimol; Pentobarbital; Pregnanediones; Propofol; Rats; Rats, Sprague-Dawley; Receptors, GABA-A; Sulfur Radioisotopes; Triazoles; Tritium