小分子诱导的线粒体解偶联的自发逆转:苯胺硫醚的案例。

Roman S Kirsanov, Ljudmila S Khailova, Vladimir S Krasnov, Alexander M Firsov, Konstantin G Lyamzaev, Alisa A Panteleeva, Lyudmila B Popova, Pavel A Nazarov, Vadim N Tashlitsky, Galina A Korshunova, Elena A Kotova, Yuri N Antonenko
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引用次数: 0

摘要

组织特异性可使线粒体解偶联剂更有希望成为研制治疗严重疾病药物的主要化合物。为了寻找组织特异性解偶联剂,我们将苯胺噻吩作为谷胱甘肽-S-转移酶(GST)的可能底物。早些时候,有报道称 5-溴-N-(4-氯苯基)-3,4-二硝基-2-噻吩胺(BDCT)在离体大鼠肝线粒体(RLM)中具有 "循环 "解偶联活性。BDCT 诱导线粒体呼吸两阶段变化(先刺激后减速)的机制尚不清楚。为了澄清这一问题,我们合成了 BDCT 及其两种类似物。其中,5-溴-3,4-二硝基-N-(4-硝基苯基)-2-噻吩胺(BDNT)似乎是最有效的线粒体解偶联剂,它能在亚摩尔浓度下降低膜电位并刺激呼吸。重要的是,BDNT 对 RLM 的线粒体膜电位和呼吸速率产生了两阶段的变化,加入谷胱甘肽(GSH)会增强这种变化,但能够消耗 GSH 的化合物(如 1-氯-2,4-二硝基苯(CDNB))则会抑制这种变化。相比之下,在大鼠心脏线粒体(RHM)中没有观察到再偶联阶段。值得注意的是,BDNT 在原代人类成纤维细胞中引起线粒体去极化,但在培养的人类肝脏(HepG2)细胞中却没有引起线粒体去极化。通过检测通过平面双层脂膜的质子选择性电流,我们证明了 BDCT 和 BDNT 跨膜转移质子的能力。事实证明,BDNT 是一种 pKa 为 7.38 的阴离子质子体。通过使用 LC-MS 和毛细管电泳,我们直接发现在与 RLM(而非 RHM)孵育时,BDNT 与 GSH 形成了共轭物。因此,我们推测 GST 参与了 RLM 中苯胺硫茚解偶联活性的消失,从而确保了解偶联剂的组织特异性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Spontaneous reversal of small molecule-induced mitochondrial uncoupling: the case of anilinothiophenes.

Tissue specificity can render mitochondrial uncouplers more promising as leading compounds for creating drugs against serious diseases. In search of tissue-specific uncouplers, we address anilinothiophenes as possible glutathione-S-transferase substrates (GST). Earlier, 'cyclic' uncoupling activity was reported for 5-bromo-N-(4-chlorophenyl)-3,4-dinitro-2-thiophenamine (BDCT) in isolated rat liver mitochondria (RLM). The mechanism by which BDCT induced two-phase changes in mitochondrial respiration (stimulation followed by deceleration) was unknown. To clarify this issue, we synthesized BDCT and its two analogues. Among these, 5-bromo-3,4-dinitro-N-(4-nitrophenyl)-2-thiophenamine (BDNT) appeared to be the most effective as a mitochondrial uncoupler, decreasing membrane potential and stimulating respiration at submicromolar concentrations. Importantly, BDNT exerted two-phase changes in both mitochondrial membrane potential and respiration rate of RLM, which were enhanced by the addition of glutathione (GSH) but inhibited by the compounds capable of GSH depleting, such as 1-chloro-2,4-dinitrobenzene (CDNB). By contrast, the phase of recoupling was not observed in rat heart mitochondria (RHM). Remarkably, BDNT elicited mitochondrial depolarization in primary human fibroblasts but not in cultured human liver (HepG2) cells. By detecting proton-selective electrical current through planar bilayer lipid membranes, we demonstrated the ability of BDCT and BDNT to transfer protons across membranes. BDNT proved to be an anionic protonophore with a pKa of 7.38. By using LC-MS and capillary electrophoresis, we directly showed the formation of BDNT conjugates with GSH upon incubation with RLM but not RHM. Therefore, we hypothesize that GST is involved in the disappearance of the anilinothiophene uncoupling activity in RLM, ensuring the tissue-specific behavior of the uncoupler.

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