Selkirk Julie V, Nottebaum Lisa M, Vana Alicia M, Verge Gail M, Mackay Kenneth B, Stiefel Theodore H, Naeve Greg S, Pomeroy Jordan E, Petroski Robert E, Moyer John, Dunlop John, Foster Alan C
Neurosciences Department, Neurocrine Biosciences Inc., 12970 El Camino Real, San Diego, CA 92130, USA.
Eur J Neurosci. 2005 Jun;21(12):3217-28. doi: 10.1111/j.1460-9568.2005.04162.x.
Glutamate is the major excitatory neurotransmitter in the central nervous system and is tightly regulated by cell surface transporters to avoid increases in concentration and associated neurotoxicity. Selective blockers of glutamate transporter subtypes are sparse and so knock-out animals and antisense techniques have been used to study their specific roles. Here we used WAY-855, a GLT-1-preferring blocker, to assess the role of GLT-1 in rat hippocampus. GLT-1 was the most abundant transporter in the hippocampus at the mRNA level. According to [(3)H]-l-glutamate uptake data, GLT-1 was responsible for approximately 80% of the GLAST-, GLT-1-, and EAAC1-mediated uptake that occurs within dissociated hippocampal tissue, yet when this transporter was preferentially blocked for 120 h with WAY-855 (100 microm), no significant neurotoxicity was observed in hippocampal slices. This is in stark contrast to results obtained with TBOA, a broad-spectrum transport blocker, which, at concentrations that caused a similar inhibition of glutamate uptake (10 and 30 microm), caused substantial neuronal death when exposed to the slices for 24 h or longer. Likewise, WAY-855, did not significantly exacerbate neurotoxicity associated with simulated ischemia, whereas TBOA did. Finally, intrahippocampal microinjection of WAY-855 (200 and 300 nmol) in vivo resulted in marginal damage compared with TBOA (20 and 200 nmol), which killed the majority of both CA1-4 pyramidal cells and dentate gyrus granule cells. These results indicate that selective inhibition of GLT-1 is insufficient to provoke glutamate build-up, leading to NMDA receptor-mediated neurotoxic effects, and suggest a prominent role of GLAST and/or EAAC1 in extracellular glutamate maintenance.
谷氨酸是中枢神经系统中主要的兴奋性神经递质,受细胞表面转运体的严格调控,以避免其浓度升高及相关的神经毒性。谷氨酸转运体亚型的选择性阻滞剂稀少,因此已利用基因敲除动物和反义技术来研究它们的特定作用。在此,我们使用了一种优先作用于GLT-1的阻滞剂WAY-855来评估GLT-1在大鼠海马体中的作用。在mRNA水平上,GLT-1是海马体中最丰富的转运体。根据[³H]-L-谷氨酸摄取数据,GLT-1介导了游离海马组织中约80%的由GLAST、GLT-1和EAAC1介导的摄取,但当用WAY-855(100 μmol)优先阻断该转运体120小时时,在海马切片中未观察到明显的神经毒性。这与广谱转运阻滞剂TBOA的结果形成鲜明对比,TBOA在导致类似程度的谷氨酸摄取抑制的浓度(10和30 μmol)下,当与切片接触24小时或更长时间时会导致大量神经元死亡。同样,WAY-855不会显著加剧与模拟缺血相关的神经毒性,而TBOA会。最后,与TBOA(20和200 nmol)相比,体内海马内微量注射WAY-855(200和300 nmol)导致的损伤较小,TBOA杀死了大部分CA1-4锥体细胞和齿状回颗粒细胞。这些结果表明,选择性抑制GLT-1不足以引发谷氨酸蓄积,导致NMDA受体介导的神经毒性作用,并提示GLAST和/或EAAC1在细胞外谷氨酸维持中起重要作用。
