A metabonomic study of inhibition of GABA uptake in the cerebral cortex

GABAergic activity is regulated by rapid, high affinity uptake of GABA from the synapse. Perturbation of GABA reuptake has been implicated in neurological disease and inhibitors of GABA transporters (GAT) have been used therapeutically but little detail is known about the ramifications of GAT inhibition on brain neurochemistry. Here, we incubated Guinea pig cortical tissue slices with [3-¹³C]pyruvate and major, currently available GABA uptake inhibitors. Metabolic fingerprints were generated from these experiments using ¹³C/¹H NMR spectroscopy. These fingerprints were analyzed using multivariate statistical approaches and compared with an existing library of fingerprints of activity at GABA receptors. This approach identified five distinct clusters of metabolic activity induced by blocking GABA uptake. Inhibition of GABA uptake via GAT1 produced patterns similar to activity at mainstream GABAergic synapses in particular those containing α1-subunits but still statistically separable. This indicated that inhibition of GABA uptake, an indirect method of activating GABA receptors, produces different effects to direct receptor activation or to exogenous GABA. The mechanism of inhibitor function also produced different outcomes, with the channel blocker SKF 89976A yielding a unique metabolic response. Blocking GAT1 and GAT3 simultaneously induces a large metabolic response consistent with induction of tonic inhibition via high affinity GABA receptors. Blocking BGT produces patterns similar to activity at less common receptors such as those containing α5 subunits. This approach is useful for determining where in the spectrum of GABAergic responses a particular GABA transport inhibitor is effective.