GABA transporters and GABA-transaminase as drug targets.

The fine-tuning and homeostatic balance of the GABAergic inhibitory tone in the central nervous system (CNS) is a prerequisite for controlling the excitatory neurotransmission. This principal mechanism for controlling excitation is inhibition which has been the topic of intensive research covering all known functional entities of the GABAergic synapse. The therapeutical scope for targeting the GABA system covers a large number of neurological and psychiatric disorders. This review focuses on the major inactivation systems for GABAergic neurotransmission, the GABA transporters (GATs) and the GABA catabolic enzyme GABA -transaminase (GABA-T) as drug targets. Tiagabin and Vigabatrin, two anti-epileptic drugs on the market today, specifically inhibit GABA transport and metabolism, respectively. However, previous and recent evidence has clearly demonstrated the importance and differential functional roles of glial and neuronal GABA uptake and the metabolic fate of the sequestered neurotransmitter GABA in these cells. Moreover, the diverse expression patterns of the GABA transporters, in combination with development of GAT inhibitors with novel pharmacological profiles may initiate a renaissance for these inactivation systems as drugs targets. In particular, further research to elucidate the specialized physiological function of the GATs combined with their differential spatial expression could be of fundamental importance for the understanding of concerted action with regard to the fine-tuning of the GABAergic inhibitory tone. As such, selective targeting and modulation of GABA transporter subtypes and cell-specific GABA uptake and metabolism is of therapeutical interest in GABA-related CNS disorders, including epilepsy.

Effects of 3-hydroxy-4-amino-4,5,6,7-tetrahydro-1,2-benzisoxazol (exo-THPO) and its N-substituted analogs on GABA transport in cultured neurons and astrocytes and by the four cloned mouse GABA transporters.

The system of GABA transporters in neural cells constitutes an efficient mechanism for terminating inhibitory GABAergic neurotransmission. As such these transporter are important therapeutical targets in epilepsy and potentially other neurological diseases related to the GABA system. In this study a number of analogs of 3-hydroxy-4-amino-4,5,6,7-tetrahydro-1,2-benzisoxazol (exo-THPO), a promising lead structure for inhibitors of GABA uptake were investigated. It was found that the selectivity of N-acetyloxyethyl-exo-THPO for inhibition of the astroglial GABA uptake system was 10-fold as compared to inhibition of the neuronal GABA uptake system. Selectivity in this magnitude may provide potent anti-convulsant activity as has recently been demonstrated with the likewise glia-selective GABA uptake inhibitor, N-methyl-exo-THPO. In contrast to the competitive inhibition of GABA uptake exhibited by N-substituted analogs of 4,5,6,7-tetrahydroisoxazolo[4,5-c]pyridin-3-ol (THPO), nipecotic acid, and guvacine, N-4,4-diphenyl-3-butenyl(DPB)-N-methyl-exo-THPO and 4-phenylbutyl-exo-THPO exhibited non-competitive type inhibition kinetics. The lipophilic character of a number of GABA analogs was concluded by far to constitute the determining factor for the potency of these compounds as inhibitors of GAT1-mediated uptake of GABA. This finding underscores the complexity of the pharmacology of the GABA transport system, since these non-competitive inhibitors are structurally very similar to some competitive GABA uptake inhibitors. Whether these structure-activity relationships for inhibition of GABA uptake may provide sufficient information for the development of new structural leads and to what extent these compounds may be efficient as therapeutical anti-convulsant agents remain to be elucidated.