Abstract
A number of epilepsy-causing mutations have recently been identified in the genes of the α1, β3, and γ2 subunits comprising the γ-aminobutyric acid type A (GABAA) receptor. These mutations are typically dominant, and in certain cases, such as the α1 and β3 subunits, they may lead to a mix of receptors at the cell surface that contain no mutant subunits, a single mutated subunit, or two mutated subunits. To determine the effects of mutations in a single subunit or in two subunits on receptor activation, we created a concatenated protein assembly that links all five subunits of the α1β3γ2 receptor and expresses them in the correct orientation. We created nine separate receptor variants with a single-mutant subunit and four receptors containing two subunits of the γ2R323Q, β3D120N, β3T157M, β3Y302C, and β3S254F epilepsy-causing mutations. We found that the singly mutated γ2R323Q subunit impairs GABA activation of the receptor by reducing GABA potency. A single β3D120N, β3T157M, or β3Y302C mutation also substantially impaired receptor activation, and two copies of these mutants within a receptor were catastrophic. Of note, an effect of the β3S254F mutation on GABA potency depended on the location of this mutant subunit within the receptor, possibly because of the membrane environment surrounding the transmembrane region of the receptor. Our results highlight that precise functional genomic analyses of GABAA receptor mutations using concatenated constructs can identify receptors with an intermediate phenotype that contribute to epileptic phenotypes and that are potential drug targets for precision medicine approaches.
Highlights
A number of epilepsy-causing mutations have recently been identified in the genes of the ␣1, 3, and ␥2 subunits comprising the ␥-aminobutyric acid type A (GABAA) receptor
Epileptic encephalopathies are a devastating group of severe childhood epilepsies with poor developmental outcomes that are often resistant to pharmacological treatment [1]
Many genes encoding for different subunits of the GABA type A (GABAA) receptor are present in the mammalian brain, including six ␣ (␣1– 6), three  (1–3), three ␥ (␥1–3), and a ␦, ⑀, and , and the majority of receptors are thought to contain two ␣, two , and one ␥ subunit where they are anchored at the synapse, responding to high concentrations of GABA [20]
Summary
A number of epilepsy-causing mutations have recently been identified in the genes of the ␣1, 3, and ␥2 subunits comprising the ␥-aminobutyric acid type A (GABAA) receptor. GABA binds within the –␣ interface located between adjacent extracellular domains to trigger an activation pathway through a series of conformational changes that open the channel pore. These conformational changes are transmitted through interactions at the coupling region, where loops in the extracellular domain in close proximity to the membrane interact with the pre-M1 and M2-M3 loops that connect transmembrane domains [22]. Epilepsy-causing mutations identified in the ␣1, 3, and ␥2 subunits are located at different regions throughout the protein, including amino acids throughout the activation pathway from the ligand-binding pocket and extracellular structural -sheets, through to the coupling and transmembrane M1 and M2 regions
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