An Extremely Low-Frequency Vortex Magnetic Field Modifies Protein Expression, Rearranges the Cytoskeleton, and Induces Apoptosis of a Human Neuroblastoma Cell Line

IF 1.8 3区生物学 Q3 BIOLOGY

Bioelectromagnetics Pub Date : 2022-04-19 DOI:10.1002/bem.22400

Diana I. Aparicio-Bautista, Daniel Chávez-Valenzuela, Giovanni Ambriz-Álvarez, Teodoro Córdova-Fraga, Juan P. Reyes-Grajeda, Óscar Medina-Contreras, Fanny Rodríguez-Cruz, Francisco García-Sierra, Patricia Zúñiga-Sánchez, Antonio M. Gutiérrez-Gutiérrez, Jaime Arellanes-Robledo, Gustavo Basurto-Islas

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引用次数: 0

Abstract

Homogeneous extremely low-frequency electromagnetic fields (ELF-EMFs) alter biological phenomena, including the cell phenotype and proliferation rate. Heterogenous vortex magnetic fields (VMFs), a new approach of exposure to magnetic fields, induce systematic movements on charged biomolecules from target cells; however, the effect of VMFs on living systems remains uncertain. Here, we designed, constructed, and characterized an ELF-VMF-modified Rodin's coil to expose SH-SY5Y cells. Samples were analyzed by performing 2D-differential-gel electrophoresis, identified by MALDI-TOF/TOF, validated by western blotting, and characterized by confocal microscopy. A total of 106 protein spots were differentially expressed; 40 spots were downregulated and 66 were upregulated in the exposed cell proteome, compared to the control cell proteome. The identified spots are associated with cytoskeleton and cell viability proteins, and according to the protein–protein interaction network, a significant interaction among them was found. Our data revealed a decrease in cell survival associated with apoptotic cells without effects on the cell cycle, as well as evident changes in the cytoskeleton. We demonstrated that ELF-VMFs, at a specific frequency and exposure time, alter the cell proteome and structurally affect the target cells. This is the first report showing that VMF application might be a versatile system for testing different hypotheses in living systems, using appropriate exposure parameters.© 2022 Bioelectromagnetics Society.

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极低频涡旋磁场改变人神经母细胞瘤细胞系的蛋白表达、细胞骨架重排和诱导凋亡

均匀的极低频电磁场(elf - emf)改变生物现象，包括细胞表型和增殖速率。异质涡旋磁场(VMFs)是一种新的磁场暴露方法，可以诱导靶细胞上带电生物分子的系统运动。然而，VMFs对生命系统的影响仍然不确定。在这里，我们设计，构建和表征了一个elf - vmf修饰的罗丹线圈，以暴露SH-SY5Y细胞。样品采用2d凝胶电泳分析，MALDI-TOF/TOF鉴定，western blotting验证，共聚焦显微镜表征。共有106个蛋白点差异表达;与对照细胞蛋白质组相比，暴露细胞蛋白质组中有40个位点下调，66个位点上调。所鉴定的斑点与细胞骨架蛋白和细胞活力蛋白相关，根据蛋白-蛋白相互作用网络，发现它们之间存在显著的相互作用。我们的数据显示，细胞凋亡与细胞存活率的降低有关，但对细胞周期没有影响，细胞骨架也有明显的变化。我们证明，在特定的频率和暴露时间下，ELF-VMFs改变细胞蛋白质组并在结构上影响靶细胞。这是第一份报告显示VMF应用可能是一个通用的系统，用于测试不同的假设在生命系统中，使用适当的暴露参数。©2022生物电磁学学会。

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来源期刊

Bioelectromagnetics 生物-生物物理

CiteScore

4.60

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Bioelectromagnetics is published by Wiley-Liss, Inc., for the Bioelectromagnetics Society and is the official journal of the Bioelectromagnetics Society and the European Bioelectromagnetics Association. It is a peer-reviewed, internationally circulated scientific journal that specializes in reporting original data on biological effects and applications of electromagnetic fields that range in frequency from zero hertz (static fields) to the terahertz undulations and visible light. Both experimental and clinical data are of interest to the journal''s readers as are theoretical papers or reviews that offer novel insights into or criticism of contemporary concepts and theories of field-body interactions. The Bioelectromagnetics Society, which sponsors the journal, also welcomes experimental or clinical papers on the domains of sonic and ultrasonic radiation.