Bowery N G, Smart T G
GlaxoSmithKline, Biology, PsyCEDD, Verona 37135, Italy.
Br J Pharmacol. 2006 Jan;147 Suppl 1(Suppl 1):S109-19. doi: 10.1038/sj.bjp.0706443.
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.
γ-氨基丁酸(GABA)在50多年前成为一种潜在的重要脑化学物质,但直到16年多后其作为神经递质的重要性才被充分认识。我们现在知道,哺乳动物大脑中至少40%的抑制性突触处理过程使用GABA。确定其作为递质的作用是一个漫长的过程,以我们目前的知识很难相信,关于其在哺乳动物大脑中的作用曾经有过任何争议。我们现在拥有的关于GABA受体的详细信息,以及大量促进或减少GABA受体机制的药物,使得进一步研究的前景非常令人兴奋。与GABA相比,甘氨酸作为递质的出现似乎相对顺利。也许这对于最简单的递质结构来说是合适的!大约40年前它在脊髓和脑干中被发现,仅仅2年后就有人提议赋予它“神经递质”的地位。又过了16年,其受体才被生化分离出来。现在它已被公认为一种重要的脊髓和脊髓上抑制性递质,我们也知道了许多关于其分子结构和在神经元周围运输的细节。这些受体的药理学研究落后于GABA。没有像我们容易与GABA受体联系在一起的丰富多样的变构调节剂,而这些变构调节剂为我们提供了用于治疗焦虑、失眠、癫痫、麻醉和痉挛的大量重要药物,所有这些都源于简单的中性氨基酸GABA的作用。然而,认识到甘氨酸受体参与运动反射和伤害感受通路,以及最近出现的具有一定亚型选择性的药物,使得设计针对甘氨酸受体的选择性治疗配体的目标更加接近。