Tereza Filipi, Jana Tureckova, Ondrej Vanatko, Martina Chmelova, Monika Kubiskova, Natalia Sirotova, Stanislava Matejkova, Lydia Vargova, Miroslava Anderova
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We then compared the results with alterations of extracellular space (ECS) diffusion parameters, morphological changes, expression of the Kir4.1 channel and the potassium concentration measured in the cerebrospinal fluid, to further disclose the link between potassium and astrocytes in the ALS-like pathology. Morphological analysis revealed astrogliosis in both the motor cortex and the ventral horns of the SOD1 spinal cord. The activated morphology of SOD1 spinal astrocytes was associated with the results from volume measurements, which showed decreased swelling of these cells during hyperkalemia. Furthermore, we observed lower shrinkage of ECS in the SOD1 spinal ventral horns. Immunohistochemical analysis then confirmed decreased expression of the Kir4.1 channel in the SOD1 spinal cord, which corresponded with the diminished volume regulation. Despite astrogliosis, cortical astrocytes in SOD1 mice did not show alterations in swelling nor changes in Kir4.1 expression, and we did not identify significant changes in ECS parameters. Moreover, the potassium level in the cerebrospinal fluid did not deviate from the physiological concentration. 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引用次数: 0
摘要
星形胶质细胞对神经系统的运作至关重要,因为它们通过体积调节维持离子平衡。病理状态(如肌萎缩性脊髓侧索硬化症(ALS))会影响星形胶质细胞,甚至可能导致其丧失上述功能。在这项研究中,我们检测了 SOD1 动物模型大脑和脊髓中星形胶质细胞的肿胀/体积恢复情况,以确定 ALS 类病变对它们的损害程度。我们测量了急性脑或脊髓切片在暴露于高钾血症期间和之后的星形胶质细胞体积变化。然后,我们将结果与细胞外空间(ECS)扩散参数的变化、形态学变化、Kir4.1通道的表达以及脑脊液中测得的钾浓度进行了比较,以进一步揭示钾与星形胶质细胞在ALS样病理中的联系。形态学分析显示,SOD1 运动皮层和脊髓腹侧角都出现了星形胶质细胞增生。SOD1 脊髓星形胶质细胞的活化形态与体积测量结果有关,后者显示这些细胞在高钾血症期间的肿胀程度降低。此外,我们还观察到SOD1脊髓腹角的ECS收缩程度较低。免疫组化分析随后证实,SOD1脊髓中Kir4.1通道的表达减少,这与体积调节的减弱相吻合。尽管发生了星形胶质细胞增生,但 SOD1 小鼠的皮质星形胶质细胞并没有出现肿胀或 Kir4.1 表达的变化,我们也没有发现 ECS 参数的显著变化。此外,脑脊液中的钾含量也没有偏离生理浓度。因此,我们获得的结果表明,类似 ALS 的病理变化会导致脊髓星形胶质细胞中与 Kir4.1 下调相关的钾摄取受损,但根据我们从大脑皮层获得的数据,功能受损似乎与形态状态无关。
ALS-like pathology diminishes swelling of spinal astrocytes in the SOD1 animal model.
Astrocytes are crucial for the functioning of the nervous system as they maintain the ion homeostasis via volume regulation. Pathological states, such as amyotrophic lateral sclerosis (ALS), affect astrocytes and might even cause a loss of such functions. In this study, we examined astrocytic swelling/volume recovery in both the brain and spinal cord of the SOD1 animal model to determine the level of their impairment caused by the ALS-like pathology. Astrocyte volume changes were measured in acute brain or spinal cord slices during and after exposure to hyperkalemia. We then compared the results with alterations of extracellular space (ECS) diffusion parameters, morphological changes, expression of the Kir4.1 channel and the potassium concentration measured in the cerebrospinal fluid, to further disclose the link between potassium and astrocytes in the ALS-like pathology. Morphological analysis revealed astrogliosis in both the motor cortex and the ventral horns of the SOD1 spinal cord. The activated morphology of SOD1 spinal astrocytes was associated with the results from volume measurements, which showed decreased swelling of these cells during hyperkalemia. Furthermore, we observed lower shrinkage of ECS in the SOD1 spinal ventral horns. Immunohistochemical analysis then confirmed decreased expression of the Kir4.1 channel in the SOD1 spinal cord, which corresponded with the diminished volume regulation. Despite astrogliosis, cortical astrocytes in SOD1 mice did not show alterations in swelling nor changes in Kir4.1 expression, and we did not identify significant changes in ECS parameters. Moreover, the potassium level in the cerebrospinal fluid did not deviate from the physiological concentration. The results we obtained thus suggest that ALS-like pathology causes impaired potassium uptake associated with Kir4.1 downregulation in the spinal astrocytes, but based on our data from the cortex, the functional impairment seems to be independent of the morphological state.
期刊介绍:
Frontiers in Cellular Neuroscience is a leading journal in its field, publishing rigorously peer-reviewed research that advances our understanding of the cellular mechanisms underlying cell function in the nervous system across all species. Specialty Chief Editors Egidio D‘Angelo at the University of Pavia and Christian Hansel at the University of Chicago are supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide.
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