Department of Microbiology and Environmental Toxicology, University of California, Santa Cruz, CA 95064, USA.
Synapse. 2013 May;67(5):205-15. doi: 10.1002/syn.21632. Epub 2013 Feb 8.
Chronic elevated exposure to manganese (Mn) is associated with neurocognitive and fine motor deficits in children. However, relatively little is understood about cellular responses to Mn spanning the transition between physiologic to toxic levels of exposure. Here, we investigated the specificity, sensitivity, and time course of the Golgi Phosphoprotein 4 (GPP130) response to Mn exposure in AF5 GABAergic neuronal cells, and we determined the extent to which GPP130 degradation occurs in brain cells in vivo in rats subchronically exposed to Mn. Our results show that GPP130 degradation in AF5 cells was specific to Mn, and did not occur following exposure to cobalt, copper, iron, nickel, or zinc. GPP130 degradation occurred without measurable increases in intracellular Mn levels and at Mn exposures as low as 0.54 µM. GPP130 protein was detectable by immunofluorescence in only ∼15-30% of cells in striatal and cortical rat brain slices, and Mn-exposed animals exhibited a significant reduction in both the number of GPP130-positive cells, and the overall levels of GPP130 protein, demonstrating the in vivo relevance of this Mn-specific response within the primary target organ of Mn toxicity. These results provide insight into specific mechanism(s) of cellular Mn regulation and toxicity within the brain, including the selective susceptibility of cells to Mn cytotoxicity.
慢性暴露于锰(Mn)会导致儿童神经认知和精细运动能力缺陷。然而,对于暴露于生理和毒性水平之间的 Mn 时细胞的反应,人们了解甚少。在这里,我们研究了 Golgi 磷蛋白 4(GPP130)对 AF5 GABA 能神经元细胞中 Mn 暴露的反应的特异性、敏感性和时程,并确定了体内亚慢性 Mn 暴露的大鼠脑细胞中 GPP130 降解的程度。我们的结果表明,AF5 细胞中 GPP130 的降解是特异性的 Mn 反应,而不是钴、铜、铁、镍或锌暴露后的反应。GPP130 的降解没有可测量的细胞内 Mn 水平升高,而且在低至 0.54 µM 的 Mn 暴露下就会发生。GPP130 蛋白只能通过免疫荧光在纹状体和皮质大鼠脑切片中约 15-30%的细胞中检测到,而 Mn 暴露的动物中 GPP130 阳性细胞的数量以及 GPP130 蛋白的总体水平都显著降低,这表明了这种 Mn 特异性反应在 Mn 毒性的主要靶器官内的体内相关性。这些结果为脑内细胞 Mn 调节和毒性的具体机制提供了线索,包括细胞对 Mn 细胞毒性的选择性易感性。
