Neurochemical changes in the spinal cord in degenerative motor neuron diseases.

Y Nagata, K Fujita, M Yamauchi, T Kato, M Ando, M Honda
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引用次数: 9

Abstract

Human amyotrophic lateral sclerosis (ALS), a typical motor neuron disease, is characterized pathologically by selective degenerative loss of motoneurons in the CNS. We have demonstrated significant reductions of neurotransmitter-related factors, such as acetylcholine-(ACh)-synthesizing enzyme activity and glutamate and aspartate contents in the ALS, compared to the non-ALS spinal cord obtained at autopsy. We have also shown considerable reductions in activities of cytochrome-c oxidase (CO), an enzyme contributing to aerobic energy production, and transglutaminase (TG), a Ca(2+)-dependent marker enzyme for tissue degeneration, in the ALS spinal cord. We found marked increases in fragmented glial fibrillary acidic protein (GFAP), a filamentous protein specifically associated with reactive astrocytes, in the ALS spinal cord relative to non-ALS tissue. These biochemical results corresponded well to pathomor-phological neuronal degenerative loss and reactive proliferation of astroglial components in the ALS spinal cord tissue. However, these results only indicate the final pathological and biochemical outcomes of ALS, and it is difficult to follow up cause and process in the ALS spinal cord during progression of the disease. Therefore, we used an animal model closely resembling human ALS, motor neuron degeneration (Mnd) mutant mice, a subline of C57BL/6 that shows late-onset progressive degeneration of lower motor neurons with paralytic gait beginning around 6.5 mo of age, to follow the biochemical and pathological alterations during postnatal development. We detected significant decreases in CO activity during early development and in activity of superoxide dismutase (SOD), an antioxidant enzyme, in later stages in Mnd mutant spinal cord tissue. TG activity in the Mnd spinal cord showed gradual increases during early development reaching a maximum at 5 mo, and then tending to decrease thereafter. Amounts of fragmented GFAPs increased continuously during postnatal development in Mnd spinal cord. These biochemical changes were observed prior to the appearance of clinical motor dysfunctions in the Mnd mutant mice. Such biochemical analyses using appropriate animal models will be useful for inferring the origin and progression of human ALS.

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退行性运动神经元疾病中脊髓的神经化学变化。
人肌萎缩侧索硬化症(ALS)是一种典型的运动神经元疾病,其病理特征是中枢神经系统运动神经元的选择性退行性丧失。我们已经证明,与尸检获得的非ALS脊髓相比,ALS患者的神经递质相关因子,如乙酰胆碱(ACh)合成酶活性、谷氨酸和天冬氨酸含量显著降低。我们还发现,在ALS脊髓中,细胞色素c氧化酶(CO)(一种促进有氧能量产生的酶)和转谷氨酰胺酶(TG)(一种依赖Ca(2+)的组织退化标记酶)的活性显著降低。我们发现,与非ALS组织相比,ALS脊髓中碎片化胶质纤维酸性蛋白(GFAP)显著增加,GFAP是一种与反应性星形胶质细胞特异性相关的丝状蛋白。这些生化结果与ALS脊髓组织中病理-生理神经元退行性丧失和星形胶质成分的反应性增殖相吻合。然而,这些结果仅表明ALS的最终病理和生化结果,难以追踪疾病进展过程中ALS脊髓的病因和过程。因此,我们使用了一种与人类ALS非常相似的动物模型,运动神经元变性(Mnd)突变小鼠,C57BL/6亚系,表现出6.5月龄左右开始的下肢运动神经元迟发性进行性变性和瘫痪步态,以跟踪出生后发育过程中的生化和病理改变。我们发现在早期发育过程中CO活性显著降低,在后期阶段,Mnd突变脊髓组织中超氧化物歧化酶(SOD)(一种抗氧化酶)活性显著降低。脑脊髓TG活性在发育早期逐渐升高,在5月龄时达到最大值,之后趋于下降。脑脊髓在出生后发育过程中碎片化gfap的数量持续增加。这些生化变化是在Mnd突变小鼠出现临床运动功能障碍之前观察到的。使用适当的动物模型进行这种生化分析将有助于推断人类ALS的起源和进展。
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