Developmental alteration in GABAA receptor structure and physiological properties in cultured cerebellar granule neurons.

Although we now have extensive knowledge about the GABAA receptor subunits determining benzodiazepine modulation of channel function, little is known about subunits influencing other modulatory sites on the GABAA receptor-chloride channel complex. We have identified a developmental change in subunit composition of the GABAA receptor in cultured cerebellar granule neurons that eliminates benzodiazepine-mediated enhancement of GABA responses and alters modulation by a substituted gamma-butyrolactone. Based on data from sequential PCR experiments, we mimicked the functional properties of early and mature receptors with heterologous expression of specific subunit combinations. This report describes one of the most extensive cell- and site-specific developmental changes for an ion channel seen to date.

Physiological comparison of alpha-ethyl-alpha-methyl-gamma-thiobutyrolactone with benzodiazepine and barbiturate modulators of GABAA receptors.

The GABAA receptor/chloride ionophore (GABAR) is allosterically modulated by several classes of anticonvulsant agents, including benzodiazepines and barbiturates, and some alkyl-substituted butyrolactones. To test the hypothesis that the anticonvulsant butyrolactones act at a distinct positive-modulatory site on the GABAR, we examined the physiological effects of a butyrolactone, a benzodiazepine and a barbiturate on GABA-mediated currents in voltage-clamped neurons and cells transfected with various subunit combinations. The butyrolactone, alpha-ethyl-alpha-methyl-gamma-thiobutyrolactone (alpha EMTBL), altered the EC50 for GABA and changed the apparent cooperativity of GABA responses. In contrast, the benzodiazepine chlordiazepoxide altered the EC50 for GABA with no effect on apparent cooperativity. The barbiturate phenobarbital altered both the EC50 and the amplitude of the maximal GABA response without altering apparent cooperativity. The GABA-mediated effect of the barbiturate, but not the benzodiazepine, added to the maximal effect of the butyrolactone, supporting the hypothesis that butyrolactones do not exert their effect at the barbiturate effector site. Both alpha EMTBL and phenobarbital potentiated GABA currents in transfected cells containing the alpha 1 beta 2 and alpha 1 gamma 2 subunit combinations, as well as alpha 1 subunits alone. Chlordiazepoxide had the minimum requirement of an alpha subunit and a gamma subunit. Specific GABARs lacking benzodiazepine or barbiturate modulation were tested for modulation by alpha EMTBL. The alpha 6 beta 2 gamma 2 combination was modulated by the butyrolactone but not chlordiazepoxide. However, GABARs comprising rho1 subunits were sensitive to both phenobarbital and alpha EMTBL. Although the molecular determinants for alpha EMTBL action appear similar to the barbiturates, our data support the conclusion that alpha EMTBL interacts with GABARs in a distinct manner from barbiturates and benzodiazepines.

Dual modulation of the gamma-aminobutyric acid type A receptor/ionophore by alkyl-substituted gamma-butyrolactones.

Alkyl-substituted gamma-butyrolactones (GBLs) and gamma-thiobutyrolactones exhibit convulsant or anticonvulsant activity, depending on the alkyl substituents. alpha-Substituted lactones with small alkyl substituents are anticonvulsant and potentiate gamma-aminobutyric acid (GABA)-mediated chloride currents, whereas beta-substituted compounds are usually convulsant and block GABAA currents. We have now found that this distinction is not so clear-cut, in that some compounds can both block and augment GABAA currents, but with different time courses. For example, alpha,alpha-diisopropyl-GBL (alpha-DIGBL) potentiates exogenous GABA currents in cultured rat hippocampal neurons but diminishes GABA-mediated inhibitory postsynaptic currents. A more detailed analysis demonstrates a triphasic effect of alpha-DIGBL on GABA currents, with a rapid inhibitory phase, a slower potentiating phase, and then an "off response" when the GABA/alpha-DIGBL perfusion is stopped. Thus, alpha-DIGBL can inhibit and potentiate GABA currents with kinetically different time courses. Inhibition is more rapid, but at steady state potentiation dominates. Using a simplified model of the GABAA receptor/ionophore, we have simulated our experimental observations with alpha-DIGBL. Another lactone, beta-ethyl-beta-methyl-gamma-thiobutyrolactone, also has dual actions, with inhibition predominating at low concentrations and potentiation predominating at high concentrations. We propose two distinct GBL modulatory sites on the GABAA receptor, i.e., an inhibitory "picrotoxin" site and an enhancing "lactone site." New information on the structure of the GABAA receptor/ionophore may allow the molecular dissection of these two sites.