[Glycolytic enzyme defects and neurodegeneration].

S Hollán, L Vécsei, E Karg, I Németh, M Horanyi, M Inselt-Kovács, T Farkas
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Abstract

This study was devoted to the continued search for an explanation of the neurodegeneration found in a severely TPI deficient Hungarian patient whose brother with genomically completely identical TPI defect was completely free of neurological disorders. The changes found in the molecular species composition of the major PL subclasses and the decrease in PE plasmalogens explain the earlier round increase in membrane fluidity interfering thereby with the physiological function of membrane enzymes, receptors, signal transduction, protein-protein interactions and vesicle fusion. Plasmalogens have also the capacity to protect against oxidative stress, that is deemed to contribute to neurodegenerative processes. The presence of chronic oxidative stress was well reflected in the decreased levels of GSH and alpha-tocopherol in the affected brothers. Decrease in plasmalogens have been described recently in Zellweger's syndrome, in other peroxisomal neurodegenerative disorders, in demyelinating processes and in Alzheimer's disease. The brain in normal individuals is highly enriched in plasmalogens. The pathological decrease found in TPI deficient lymphocytes will presumably be more pronounced in excitatory tissues. The recently described role of expanding nucleotide triplets in the development of neurodegeneration is suggested to result through the selective binding via their polyglutamine repeats to GAPDH. The role of GAPDH in TPI deficiency may be of crucial help in the elucidation of the development of neurodegeneration, since the enzymatic defect of TPI can be partially bypassed by means of the HMP shunt which generates GAP via GAPDH without the participation of TPI. Considering the results found in TPI deficiency in comparison to the new literary findings in different neurodegenerative diseases the following pathomechanism may be proposed. The protein products of the defective genes due to their abnormal steric structure bind GAPDH in a different manner or in differing quantity than their normal counterparts. The PL composition and the resulting differences in the biophysical properties of the cell membranes have crucial impact on these protein-protein interactions and on the activity of enzymes and membrane transport functions. The plasmalogen decrease impairs the protection against oxidative stress with consecutive worsening of the neurodegenerative process. The final common pathway to neuronal death leads through destabilization of intracellular Ca2+ homeostasis via elevation of intracellular Ca2+ to apoptosis. The most important conclusion is that lipids are not an inert environment of membrane proteins. Unravelling of the pathogenesis of neurodegeneration needs more concerted investigation of the interactions between genetic changes with biophysical and biochemical cell membrane lipid alterations.

[糖酵解酶缺陷和神经变性]。
这项研究致力于继续寻找解释在一个严重TPI缺陷的匈牙利患者中发现的神经退行性变,他的兄弟基因组完全相同的TPI缺陷完全没有神经系统疾病。主要PL亚类分子种类组成的变化和PE缩醛原的减少解释了早期膜流动性的增加,从而干扰了膜酶、受体、信号转导、蛋白-蛋白相互作用和囊泡融合的生理功能。缩醛缩原还具有防止氧化应激的能力,氧化应激被认为是导致神经退行性过程的原因。慢性氧化应激的存在很好地反映在受影响兄弟体内GSH和α -生育酚水平的下降。最近在齐薇格氏综合征、其他过氧化物酶体神经退行性疾病、脱髓鞘过程和阿尔茨海默病中都发现了磷脂原减少的情况。正常人的大脑富含缩醛原。在TPI缺陷淋巴细胞中发现的病理性减少可能在兴奋性组织中更为明显。最近描述的扩大核苷酸三联体在神经退行性疾病发展中的作用被认为是通过其聚谷氨酰胺重复序列与GAPDH的选择性结合而产生的。GAPDH在TPI缺乏症中的作用可能对阐明神经退行性变的发展有重要帮助,因为TPI的酶缺陷可以通过HMP分流部分绕过,HMP分流通过GAPDH在没有TPI参与的情况下产生GAP。将TPI缺乏的结果与不同神经退行性疾病的新文献发现进行比较,可以提出以下病理机制。由于其异常的立体结构,缺陷基因的蛋白质产物以不同的方式结合GAPDH,或与正常基因结合的数量不同。PL的组成和由此产生的细胞膜生物物理性质的差异对这些蛋白质-蛋白质相互作用以及酶的活性和膜运输功能有着至关重要的影响。随着神经退行性过程的持续恶化,浆磷脂原的减少削弱了对氧化应激的保护作用。神经元死亡的最后一个共同途径是通过细胞内Ca2+的升高导致细胞内Ca2+稳态的不稳定而导致细胞凋亡。最重要的结论是脂质不是膜蛋白的惰性环境。神经退行性疾病的发病机制需要对遗传变化与生物物理和生化细胞膜脂质改变之间的相互作用进行更协调的研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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