Synaptic inputs to GABAA and GABAB receptors originate from discrete afferent neurons

Membrane properties and synaptic potentials of three types of neurone in rat lateral amygdala

1. Intracellular recordings were made from the lateral nucleus of the amygdala in tissue slices cut from rat brain and maintained in vitro. 2. Three types of neurones were distinguished according to the after-potential that followed an action potential. Type 1 cells (44%, n = 225) had depolarizing after-potentials, resulting from a calcium-dependent chloride conductance. Type 2 cells (48%) had long-lasting (> 250 ms) hyperpolarizing after-potentials and type 3 cells (8%) had shorter hyperpolarizing after-potentials. The average resting potentials of the three cell types were -78, -69 and -62 mV respectively. Intracellular labelling with biocytin showed that type 1 cells were pyramidal neurones; type 2 and type 3 cells were non-pyramidal. 3. Experiments with receptor antagonists identified synaptic potentials mediated by excitatory amino acids and by GABA (acting at GABAA receptors) in all three cell types. A longer duration inhibitory synaptic potential resulting from activation of GABAB receptors was present in type 1 (pyramidal) and type 2 cells. 4. Cholecystokinin (100 nM to 1 microM) depolarized type 2 and type 3 cells but had no effect on type 1 (pyramidal) cells. Baclofen (1-3 microM) hyperpolarized type 1 and type 2, but not type 3 cells. [Met5]enkephalin (1-10 microM) hyperpolarized only type 2 cells. 5. It is concluded that the lateral nucleus of the amygdala contains pyramidal neurones and two types of non-pyramidal neurone; these can be differentiated by membrane properties, synaptic inputs and sensitivities to transmitters.

Postsynaptic action of endogenous GABA released by nipecotic acid in the hippocampus

Intracellular and whole-cell recording from CA1 pyramidal cells and dentate granule cells was used to study the release of endogenous GABA by nipecotic acid. Local application of nipecotic acid produced responses that could be entirely blocked by a combination of the GABAA receptor antagonist picrotoxin and the GABAB receptor antagonist CGP 35348. These responses were due to the heteroexchange release of endogenous GABA because they were blocked by low Na+ which blocks the GABA transporter and by SKF 89976 which is a competitive antagonist of the GABA transporter. Local application of nipecotic acid could, depending on the location, evoke pure GABAA or pure GABAB responses supporting proposals that GABAA and GABAB receptors can be segregated at separate inhibitory synapses.

GABAB Receptors in the Parallel Fibre Pathway of Rat Cerebellum

Binding studies indicate that the molecular layer of the cerebellum has a high concentration of gamma-aminobutyric acid type B (GABAB) receptors. In order to elucidate the function of these receptors we have recorded from Purkinje cells in biplanar slices of immature (14-day-old) and adult rat cerebellum using a low-noise, non-invasive, gap technique. The responses of Purkinje cells to parallel fibre stimulation in slices from both immature and adult rats contained a wave that could be inhibited by the GABAA antagonist, bicuculline. In slices from immature animals, application of 30 - 50 microM bicuculline revealed a slow (400 ms to peak) and very long-lasting (up to 1 s) hyperpolarizing wave which was inhibited by GABAB antagonists. Activation of GABAB receptors on Purkinje cells with an exogenous agonist, baclofen, also generated a hyperpolarization. Baclofen additionally inhibited the synaptic potentials generated in Purkinje cells on stimulating parallel fibres, an effect which could be reversed by GABAB antagonists. The potency of baclofen in this respect was similar in adult and immature tissue but another excitatory pathway in the cerebellar cortex, the mossy fibre to granule cell synapse, proved to be much less sensitive. We conclude that, at least in the immature rat, there are GABAB receptors on Purkinje cell dendrites and that these receptors can be activated following parallel fibre stimulation; there are also GABAB receptors on presynaptic terminals within the molecular layer of immature and adult cerebellum that, when stimulated, inhibit transmitter release.