Gluck M R, Youngster S K, Ramsay R R, Singer T P, Nicklas W J
Department of Neurology, University of Medicine and Dentistry of New Jersey-Robert Wood Johnson Medical School, Piscataway 08854.
J Neurochem. 1994 Aug;63(2):655-61. doi: 10.1046/j.1471-4159.1994.63020655.x.
1-Methyl-4-phenylpyridinium (MPP+), the toxic agent in MPTP-induced dopaminergic neurotoxicity, is thought to act by inhibiting mitochondrial electron transport at complex I. This study examined this latter action further with a series of 4'-alkylated analogues of MPP+. These derivatives had IC50 values that ranged from 0.5 to 110 microM and from 1.6 to 3,300 microM in mitochondria and electron transport particles (ETPs), respectively. The IC50 values of corresponding 4'-alkylated phenylpyridine derivatives to inhibit NADH-linked oxidation ranged from 10 to 205 microM in mitochondria and from 1.7 to 142 microM in ETPs. The potencies of both classes of inhibitors directly correlated with their ability to partition between 1-octanol and water. In mitochondria, increased hydrophobicity resulted in greater inhibition of NADH dehydrogenase but a smaller dependence on the transmembrane electrochemical gradient for accumulation of the pyridiniums as evidenced by an approximately 600-fold, versus only a 36-fold, increase in the IC50 of MPP+ versus 4'-pentyl-MPP+, respectively, in the presence of uncoupler. In ETPs, the analogous increase in potencies of the more hydrophobic analogues was also consistent with an inhibitory mechanism that relied on differential partitioning into the lipid environment surrounding NADH dehydrogenase. However, the pyridinium charge must play a major role in explaining the inhibitory mechanism of the pyridiniums because their potencies are much greater than would be predicted based solely on hydrophobicity. For example, in ETPs, 4'-decyl-MPP+ was nearly 80-fold more potent than phenylpyridine although the latter compound partitions twice as much into 1-octanol.(ABSTRACT TRUNCATED AT 250 WORDS)
1-甲基-4-苯基吡啶离子(MPP+)是1-甲基-4-苯基-1,2,3,6-四氢吡啶(MPTP)诱导的多巴胺能神经毒性中的有毒物质,被认为是通过抑制复合体I处的线粒体电子传递来发挥作用。本研究用一系列MPP+的4'-烷基化类似物进一步研究了后者的作用。这些衍生物在线粒体和电子传递颗粒(ETP)中的半数抑制浓度(IC50)值分别为0.5至110微摩尔和1.6至3300微摩尔。相应的4'-烷基化苯基吡啶衍生物抑制NADH偶联氧化的IC50值在线粒体中为10至205微摩尔,在ETP中为1.7至142微摩尔。这两类抑制剂的效力都与其在1-辛醇和水之间的分配能力直接相关。在线粒体中,疏水性增加导致对NADH脱氢酶的抑制作用增强,但对吡啶离子积累的跨膜电化学梯度的依赖性减小,这一点可通过在解偶联剂存在下MPP+的IC50增加约600倍,而4'-戊基-MPP+仅增加36倍来证明。在ETP中,疏水性更强的类似物效力的类似增加也与一种依赖于向NADH脱氢酶周围脂质环境中差异性分配的抑制机制一致。然而,吡啶离子电荷在解释吡啶离子的抑制机制中一定起着主要作用,因为它们的效力远大于仅基于疏水性所预测的效力。例如,在ETP中,4'-癸基-MPP+的效力比苯基吡啶高近80倍,尽管后者化合物在1-辛醇中的分配量是前者的两倍。(摘要截短于250字)
