GABA and glycine as neurotransmitters: a brief history.

gamma-Aminobutyric acid (GABA) emerged as a potentially important brain chemical just over 50 years ago, but its significance as a neurotransmitter was not fully realized until over 16 years later. We now know that at least 40% of inhibitory synaptic processing in the mammalian brain uses GABA. Establishing its role as a transmitter was a lengthy process and it seems hard to believe with our current knowledge that there was ever any dispute about its role in the mammalian brain. The detailed information that we now have about the receptors for GABA together with the wealth of agents which facilitate or reduce GABA receptor mechanisms make the prospects for further research very exciting. The emergence of glycine as a transmitter seems relatively painless by comparison to GABA. Perhaps this is appropriate for the simplest of transmitter structures! Its discovery within the spinal cord and brainstem approximately 40 years ago was followed only 2 years later by the proposal that it be conferred with 'neurotransmitter' status. It was another 16 years before the receptor was biochemically isolated. Now it is readily accepted as a vital spinal and supraspinal inhibitory transmitter and we know many details regarding its molecular structure and trafficking around neurones. The pharmacology of these receptors has lagged behind that of GABA. There is not the rich variety of allosteric modulators that we have come to readily associate with GABA receptors and which has provided us with a virtual treasure trove of important drugs used in anxiety, insomnia, epilepsy, anaesthesia, and spasticity, all stemming from the actions of the simple neutral amino acid GABA. Nevertheless, the realization that glycine receptors are involved in motor reflexes and nociceptive pathways together with the more recent advent of drugs that exhibit some subtype selectivity make the goal of designing selective therapeutic ligands for the glycine receptor that much closer.

GABA: history and perspectives.

In 1957, factor I, a brain agent I had discovered earlier, was chemically identified as GABA in a collaboration between myself and Alva Bazemore at the Montréal Neurological Institute (MNI) in the Neurochemistry Laboratory then headed by K. A. C. Elliott. A personally biased excursion into the history of neurobiology illuminates the development of methods and concepts that led to this event, and recounts the early days at the MNI, when Hugh McLennan and I applied factor I to the exposed surface of the spinal cord and to sympathetic ganglia of cats and rabbits. It also tells of earlier studies at Graz, Naples, and elsewhere that prompted the experiments at the California Institute of Technology in which factor I was discovered as the agent in nerve extracts causing inhibition of isolated crayfish stretch receptor neurons, and in which it was found that this inhibition could be prevented by picrotoxin. There was justified doubt that GABA is indeed the transmitter substance of inhibitory neurones. Later studies, however, resolved the controversy. The functional role of GABA in brain and spinal cord and its mechanism of action are still far from being fully understood. Special problems are the extent and significance of spontaneous quantal and nonquantal release, the functional role and the mechanism of excitatory actions of GABA, its release from glial cells, and the energetics of its metabolic turnover.