印防己毒素对大鼠海马神经元中γ-氨基丁酸诱导电流的多种阻断机制。
Multiple mechanisms of picrotoxin block of GABA-induced currents in rat hippocampal neurons.
作者信息
Yoon K W, Covey D F, Rothman S M
机构信息
Department of Anatomy and Neurobiology, Washington University School of Medicine, St Louis, MO 63110.
出版信息
J Physiol. 1993 May;464:423-39. doi: 10.1113/jphysiol.1993.sp019643.
Abstract
- We have examined the effect of picrotoxin on GABA-induced currents in dissociated rat hippocampal neurons. In addition, we used the putative picrotoxin receptor antagonist, alpha-isopropyl-alpha-methyl-gamma-butyrolactone (alpha IMGBL), and the picrotoxin agonist, beta-ethyl-beta-methyl-gamma-butyrolactone (beta EMGBL) to explore the mechanisms of picrotoxin's interaction with the GABA-Cl- receptor-ionophore complex. 2. The picrotoxin block of GABA current was use dependent, suggesting that the site of picrotoxin block is exposed by the conformational change initiated by GABA binding to the receptor. 3. The alkyl-substituted butyrolactone antagonist, alpha IMGBL, selectively blocked the use-dependent mechanism of picrotoxin effect. After the apparent complete inhibition of the use-dependent effect, there was a residual picrotoxin effect that was independent of the time or concentration of GABA application. This indicates that the picrotoxin block of the GABA current is mediated by two different mechanisms. alpha IMGBL influences just one of these mechanisms. 4. The picrotoxin receptor agonist, beta EMGBL, exclusively blocked the GABA current in a use-dependent manner. Consistent with a use-dependent mechanism, the rate of onset of block increased with GABA concentration. Surprisingly, the fraction of GABA current block decreased with increasing GABA concentration. 5. These results suggest that the relationship of picrotoxin and gamma-butyrolactones with the GABA-Cl- receptor-ionophore is quite complex. They are consistent with at least two possible models of agonist-antagonist interactions. Both cases require different antagonist affinities for the various kinetic states of the GABA-Cl- receptor-ionophore. However, there is no need to require that either picrotoxin or beta EMGBL acts as an open channel blocker.
摘要
- 我们研究了印防己毒素对离体大鼠海马神经元中γ-氨基丁酸(GABA)诱导电流的影响。此外,我们使用了假定的印防己毒素受体拮抗剂α-异丙基-α-甲基-γ-丁内酯(α-IMGBL)和印防己毒素激动剂β-乙基-β-甲基-γ-丁内酯(β-EMGBL)来探究印防己毒素与GABA-Cl-受体离子通道复合物相互作用的机制。2. 印防己毒素对GABA电流的阻断具有使用依赖性,这表明印防己毒素的阻断位点是由GABA与受体结合引发的构象变化所暴露的。3. 烷基取代的丁内酯拮抗剂α-IMGBL选择性地阻断了印防己毒素作用的使用依赖性机制。在明显完全抑制使用依赖性效应后,存在一种与GABA应用时间或浓度无关的印防己毒素残余效应。这表明印防己毒素对GABA电流的阻断是由两种不同机制介导的。α-IMGBL仅影响其中一种机制。4. 印防己毒素受体激动剂β-EMGBL仅以使用依赖性方式阻断GABA电流。与使用依赖性机制一致,阻断的起始速率随GABA浓度增加而增加。令人惊讶的是,GABA电流阻断的比例随GABA浓度增加而降低。5. 这些结果表明印防己毒素和γ-丁内酯与GABA-Cl-受体离子通道的关系相当复杂。它们与激动剂-拮抗剂相互作用的至少两种可能模型一致。两种情况都需要对GABA-Cl-受体离子通道的各种动力学状态有不同的拮抗剂亲和力。然而,无需要求印防己毒素或β-EMGBL作为开放通道阻断剂。
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