电压依赖性阴离子通道的电磁场和钙信号传导

V. Ullrich, H. Apell
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引用次数: 2

摘要

电磁场(emf)可以与生物组织相互作用,对细胞活力产生积极和消极的影响,但潜在的传感和信号传导机制在很大程度上是未知的。到目前为止,在可兴奋的细胞中,EMF暴露被假定为通过电压依赖性Ca通道(VDCC)引起Ca2+内流,导致细胞活化和抗氧化反应。进一步激活后,氧化应激可能导致DNA损伤或细胞死亡。在这里,我们报告了从文献中收集到的证据,即电压依赖性阴离子通道(VDAC)不仅位于微粒体外膜上,而且位于细胞质膜上,即使在不可兴奋的细胞(如红细胞)中,当施加EMF的细微变化时,也会转化为不同容量的Ca2+传导通道。因此,在这两种类型的膜中,VDAC可以被外部EMF靶向,将Ca2+释放到细胞质中。频率、脉冲调制或极化的作用还有待于在合适的细胞模型中研究。vdac与其他几种蛋白质相关,其中18 kDa转位蛋白(TSPO)是特别感兴趣的,因为它被描述为神经元中的中枢苯二氮卓受体。由于与磁感受器结构相似,我们提出TSPO可以感知EMF的磁性成分,因此与VDAC一起可以触发生理和病理细胞反应。脑电波通信网络频率范围内的脉冲电磁场可以解释电磁超敏症患者的精神障碍。人类心理学提供了一个重要的支持,即失眠、焦虑或抑郁等缺陷可以用二氮卓类药物治疗,这表明TSPO/VDAC复合物与EMF的生物体反应之间存在明显联系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Electromagnetic Fields and Calcium Signaling by the Voltage Dependent Anion Channel
Electromagnetic fields (EMFs) can interact with biological tissues exerting positive as well as negative effects on cell viability, but the underlying sensing and signaling mechanisms are largely unknown. So far in excitable cells EMF exposure was postulated to cause Ca2+ influx through voltage-dependent Ca channels (VDCC) leading to cell activation and an antioxidant response. Upon further activation oxidative stress causing DNA damage or cell death may follow. Here we report collected evidence from literature that voltage dependent anion channels (VDAC) located not only in the outer microsomal membrane but also in the cytoplasmic membrane convert to Ca2+ conducting channels of varying capacities upon subtle changes of the applied EMF even in non-excitable cells like erythrocytes. Thus, VDAC can be targeted by external EMF in both types of membranes to release Ca2+ into the cytosol. The role of frequency, pulse modulation or polarization remains to be investigated in suitable cellular models. VDACs are associated with several other proteins, among which the 18 kDa translocator (TSPO) is of specific interest since it was characterized as the central benzodiazepine receptor in neurons. Exhibiting structural similarities with magnetoreceptors we propose that TSPO could sense the magnetic component of the EMF and thus together with VDAC could trigger physiological as well as pathological cellular responses. Pulsed EMFs in the frequency range of the brain-wave communication network may explain psychic disturbances of electromagnetic hypersensitive persons. An important support is provided from human psychology that states deficits like insomnia, anxiety or depression can be treated with diazepines that indicates apparent connections between the TSPO/VDAC complex and organismic responses to EMF.
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