The effect of a transmembrane amino acid on etomidate sensitivity of an invertebrate GABA receptor

• Published in: British journal of pharmacology Vol. 124; no. 1; pp. 13 - 20
• Main Authors: McGurk, Karen A, Pistis, Marco, Belelli, Delia, Hope, Anthony G, Lambert, Jeremy J
• Format: Journal Article
• Language: English
• Published: Oxford, UK Blackwell Publishing Ltd 01.05.1998; Nature Publishing
• Subjects: 5α‐pregnan‐3α‐ol‐20‐one; Allosteric Regulation; Amino Acid Sequence; Amino Acids - chemistry; Amino Acids - physiology; Anesthetics. Neuromuscular blocking agents; Animals; Base Sequence; Biological and medical sciences; Cell Membrane - chemistry; DNA Primers; Drosophila melanogaster; etomidate; Etomidate - chemistry; Etomidate - pharmacology; GABA; GABA Modulators - chemistry; GABA Modulators - pharmacology; GABA receptor; general anaesthetic; Humans; Medical sciences; Membrane Potentials - drug effects; Molecular Sequence Data; Mutagenesis, Site-Directed; Neuropharmacology; neurosteroid; pentobarbitone; Pharmacology. Drug treatments; Receptors, GABA-A - chemistry; Receptors, GABA-A - drug effects; Receptors, GABA-A - genetics; Stereoisomerism; Xenopus laevis; Imidazole derivatives; Insecta; Xenopus laevis; Site directed mutagenesis; Amphibia; Electrophysiology; Molecular interaction; Salientia; Gene expression; Etomidate; Voltage clamp method; Drosophilidae; Gabaergic receptor; Vertebrata; General anesthetic; Arthropoda; Aminoacid; Pentobarbital; Mutation; Invertebrata; Barbiturates; Drosophila melanogaster; Diptera; Oocyte
• ISSN: 0007-1188; 1476-5381
• DOI: 10.1038/sj.bjp.0701787

The γ‐aminobutyric acid (GABA)‐modulatory and GABA‐mimetic actions of etomidate at mammalian GABAA receptors are favoured by β2‐ or β3‐ versus β1‐subunit containing receptors, a selectivity which resides with a single transmembrane amino acid (β2 N290, β3 N289, β1 S290). Here, we have utilized the Xenopus laevis oocyte expression system in conjunction with the two‐point voltage clamp technique to determine the influence of the equivalent amino acid (M314) on the actions of this anaesthetic at an etomidate‐insensitive invertebrate GABA receptor (Rdl) of Drosophila melanogaster. Complementary RNA‐injected oocytes expressing the wild type Rdl GABA receptor and voltage‐clamped at −60 mV responded to bath applied GABA with a concentration‐dependent inward current response and a calculated EC50 for GABA of 20±0.4 μM. Receptors in which the transmembrane methionine residue (M314) had been exchanged for an asparagine (RdlM314N) or a serine (RdlM314S) also exhibited a concentration‐dependent inward current response to GABA, but in both cases with a reduced EC50 of 4.8±0.2 μM. Utilizing the appropriate GABA EC10, etomidate (300 μM) had little effect on the agonist‐evoked current of the wild type Rdl receptor. By contrast, at RdlM314N receptors, etomidate produced a clear concentration‐dependent enhancement of GABA‐evoked currents with a calculated EC50 of 64±3 μM and an Emax of 68±2% (of the maximum response to GABA). The actions of etomidate at RdlM314N receptors exhibited an enantioselectivity common to that found for mammalian receptors, with 100 μMR‐(+)‐etomidate and S‐(−)‐etomidate enhancing the current induced by GABA (EC10) to 52±6% and 12±1% of the GABA maximum respectively. The effects of this mutation were selective for etomidate as the GABA‐modulatory actions of 1 mM pentobarbitone at wild type Rdl (49±4% of the GABA maximum) and RdlM314N receptors (53±2% of the GABA maximum) were similar. Additionally, the modest potentiation of GABA produced by the anaesthetic neurosteroid 5α‐pregnan‐3α‐ol‐20‐one (Rdl=25±4% of the GABA maximum) was not altered by this mutation (RdlM314N=18±3% of the GABA maximum). Etomidate acting at β1 (S290)‐containing mammalian GABAA receptors is known to produce only a modest GABA‐modulatory effect. Similarly, etomidate acting at RdlM314S receptors produced an enhancement of GABA but the magnitude of the effect was reduced compared to RdlM314N receptors. Etomidate acting at human α6β3γ2L receptors is known to produce a large enhancement of GABA‐evoked currents and at higher concentrations this anaesthetic directly activates the GABAA receptor complex. Mutation of the human β3 subunit asparagine to methionine (β3 N289M found in the equivalent position in Rdl completely inhibited both the GABA‐modulatory and GABA‐mimetic action of etomidate (10–300 μM) acting at α6β3 N289Mγ2L receptors. It was concluded that, although invertebrate and mammalian proteins exhibit limited sequence homology, allosteric modification of their function by etomidate can be influenced in a complementary manner by a single amino acid substitution. The results are discussed in relation to whether this amino acid contributes to the anaesthetic binding site, or is essential for transduction. Furthermore, this study provides a clear example of the specificity of anaesthetic action.