Medical/biological study (experimental study)

Power Frequency Magnetic Fields Affect the p38 MAPK-Mediated Regulation of NB69 Cell Proliferation Implication of Free Radicals med./bio.

By: Martinez MA, Ubeda A, Moreno J, Trillo MA

Published in: Int J Mol Sci 2016; 17 (4): 510-

Aim of study (acc. to author)

The effects of exposure of neuroblastoma cells to a 50 Hz magnetic field on the cell cycle and cell proliferation and the underlying signal pathways should be investigated.

Background/further details

Previous studies by the authors (Trillo et al. 2012, Cid et al. 2012, Martinez et al. 2012, Trillo et al. 2013) have found increased cell proliferation and MAPK-ERK-1/2 signal pathway activation in human cancer cell lines after exposure to 50 Hz magnetic fields. The present study should investigate if changes in cell cycle regulation and other signaling pathways relevant to cell proliferation might be involved in the increased cell proliferation.
Cells were treated with the p38 MAPK inhibitor SB203580 (10 µM) or the JNK inhibitor SP600125 (20 µM) to investigate the involvement of these signaling pathways. Cells were also treated with N-acetyl-L-cysteine (1 mM and 10 mM) to inhibit reactive oxygen species.
The different exposure conditions and durations for individual methods were based on results from former studies.

Endpoint

cell viability/cell division/proliferation: cell proliferation and the underlying signal pathways

Exposure

- 50 Hz
- 50/60 Hz
- magnetic field
- co-exposure

Exposure	Parameters
Exposure 1: 50 Hz Exposure duration: continuous for 15, 30, 60 or 120 minutes	magnetic flux density: 100 µT effective value
Exposure 2: 50 Hz Exposure duration: intermittent (3 h on/3 h off) for 24, 42 or 63 hours	magnetic flux density: 100 µT effective value

Exposure 1

Main characteristics

Frequency	50 Hz
Type	magnetic field
Waveform	sinusoidal
Exposure duration	continuous for 15, 30, 60 or 120 minutes
Additional info	vertically polarized

Exposure setup

Exposure source	Helmholtz coils
Chamber	one pair of Helmholtz coils was placed inside each of two chambers magnetically shielded chambers located within two CO₂ incubators
Setup	in each experimental run, petri dishes (five per experimental group) were stacked in the central region of the Helmholtz coil gap, which ensured uniformity of exposure; no increase of temperature at the sample location was observed during exposure
Sham exposure	A sham exposure was conducted.
Additional info	the setup was composed of two identical exposure systems; following a random sequence, both coil sets and incubators were alternatively used for exposure or sham exposure

Parameters

Measurand	Value	Type	Method	Mass	Remarks
magnetic flux density	100 µT	effective value	measured	-	-

Additional parameter details

the background magnetic field inside the shielded chambers was 0.04 µT ± 0.03 µT (effective value; AC field) and 0.05 µT ± 0.04 µT (effective value, DC field)

Exposure 2

Main characteristics

Frequency	50 Hz
Type	magnetic field
Waveform	sinusoidal
Exposure duration	intermittent (3 h on/3 h off) for 24, 42 or 63 hours
Additional info	vertically polarized

Exposure setup

Exposure source	same setup as exposure 1
Sham exposure	A sham exposure was conducted.

Parameters

Measurand	Value	Type	Method	Mass	Remarks
magnetic flux density	100 µT	effective value	measured	-	-

Reference articles

Martinez MA et al. (2015): Power-Frequency Magnetic Field Inhibits Adipogenic Differentiation in Human ADSC
Trillo MA et al. (2012): Influence of a 50 Hz magnetic field and of all-transretinol on the proliferation of human cancer cell lines

Exposed system:

intact cell/cell culture
NB69 cells (human neuroblastoma cells)

Methods Endpoint/measurement parameters/methodology

molecular biosynthesis: protein expression of cell cycle control proteins cyclin D1 and p27Kip1 (after 120 min of continuous exposure) and of phosphorylated p38 MAPK and JNK (after 15, 30 and 60 min of continuous exposure) (Western Blot); protein expression of phosphorylated p38 MAPK (after 15, 30, 60 and 120 min of continuous exposure with and without inhibitors) and of phosphorylated p38 MAPK and ERK-1/2 (after 30 min of continuous exposure with or without N-acetyl-L-cysteine) (immunohistochemistry, fluorescence microscopy)
cell viability/cell division/proliferation: cell cycle distribution (24, 42 and 63 h of intermittent exposure; propidium iodide stain, flow cytometry); cell viability and proliferation (after 63 h of intermittent exposure with and without inhibitors or N-acetyl-L-cysteine; trypan blue exclusion, hemocytometer, microscopy)

Investigated system:

isolated bio./chem. substance
intact cell/cell culture
cell extracts

Time of investigation:

during exposure
after exposure

Main outcome of study (acc. to author)

The cell cycle distribution showed significant changes after 24 h (increased proportion of cells in S phase) and 42 h (decreased proportion of cells in G₀ phase/G₁ phase) of exposure compared to the control group. Exposure to the magnetic field for 120 minutes significantly increased the protein expression of cyclin D1 and decreased that of p27Kip1.
As expected, cells exposed to the magnetic field for 63 hours showed a significantly increased cell proliferation. The proliferative effect of the magnetic field was blocked by the p38 MAPK inhibitor, but not by the JNK inhibitor. Moreover, the proliferative effect of the MF was blocked by 1 mM of N-acetyl-L-cysteine while a concentration of 10 mM significantly reduced cell proliferation compared to the control group with and without co-exposure to the magnetic field.
After 15 minutes and 30 minutes of exposure, the protein expression of phosphorylated p38 MAPK was significantly increased compared to the control group and this increase could be blocked by treatment with the p38 MAPK inhibitor or N-acetyl-L-cysteine. The protein expression of phosphorylated JNK was significantly increased after 15 min and significantly decreased after 60 min of exposure compared to the control group. The phosphorylated ERK-1/2 protein expression was significantly increased after 30 minutes of exposure and was not influenced by N-acetyl-L-cysteine treatment.
The authors conclude that exposure of neuroblastoma cells to a 50 Hz magnetic field might induce changes in cell cycle and increase cell proliferation. The effects are probably mediated by a radical-dependent activation of the p38 MAPK and a radical-independent activation of the ERK-1/2 signal pathways.

Study character:

medical/biological study
experimental study
full/main study
blind study

Study funded by

European Defence Agency (EDA)
European Union (EU)/European Commission
Ministerio de Defensa de Espana (Ministry of Defence, Spain)
Quality of Life and Management of Living Resources program of European Union

Martínez MA et al. (2021): Role of NADPH oxidase in MAPK signaling activation by a 50 Hz magnetic field in human neuroblastoma cells
Consales C et al. (2021): Exposure of the SH-SY5Y Human Neuroblastoma Cells to 50-Hz Magnetic Field: Comparison Between Two-Dimensional (2D) and Three-Dimensional (3D) In Vitro Cultures
Martínez MA et al. (2019): Involvement of the EGF Receptor in MAPK Signaling Activation by a 50 Hz Magnetic Field in Human Neuroblastoma Cells
Qiu L et al. (2019): S1P mediates human amniotic cells proliferation induced by a 50-Hz magnetic field exposure via ERK1/2 signaling pathway
Koziorowska A et al. (2017): Electromagnetic fields with frequencies of 5, 60 and 120 Hz affect the cell cycle and viability of human fibroblast BJ in vitro
Luukkonen J et al. (2017): Modification of p21 level and cell cycle distribution by 50 Hz magnetic fields in human SH-SY5Y neuroblastoma cells
Falone S et al. (2016): Improved Mitochondrial and Methylglyoxal-Related Metabolisms Support Hyperproliferation Induced by 50 Hz Magnetic Field in Neuroblastoma Cells
Hasanzadeh H et al. (2014): Effect of ELF-EMF Exposure on Human Neuroblastoma Cell Line: a Proteomics Analysis
Giorgi G et al. (2014): An evaluation of genotoxicity in human neuronal-type cells subjected to oxidative stress under an extremely low frequency pulsed magnetic field
Reale M et al. (2014): Neuronal cellular responses to extremely low frequency electromagnetic field exposure: implications regarding oxidative stress and neurodegeneration
Luukkonen J et al. (2014): Induction of genomic instability, oxidative processes, and mitochondrial activity by 50Hz magnetic fields in human SH-SY5Y neuroblastoma cells
Trillo MA et al. (2013): Retinoic acid inhibits the cytoproliferative response to weak 50Hz magnetic fields in neuroblastoma cells
Cid MA et al. (2012): Antagonistic effects of a 50 Hz magnetic field and melatonin in the proliferation and differentiation of hepatocarcinoma cells
Martinez MA et al. (2012): The Proliferative Response of NB69 Human Neuroblastoma Cells to a 50 Hz Magnetic Field is mediated by ERK1/2 Signaling
Trillo MA et al. (2012): Influence of a 50 Hz magnetic field and of all-transretinol on the proliferation of human cancer cell lines
Sulpizio M et al. (2011): Molecular basis underlying the biological effects elicited by extremely low-frequency magnetic field (ELF-MF) on neuroblastoma cells
Marcantonio P et al. (2010): Synergic effect of retinoic acid and extremely low frequency magnetic field exposure on human neuroblastoma cell line BE(2)C
Pozzi D et al. (2007): Effect of 50 Hz magnetic field exposure on neuroblastoma morphology
Nie K et al. (2003): MAP kinase activation in cells exposed to a 60 Hz electromagnetic field

Power Frequency Magnetic Fields Affect the p38 MAPK-Mediated Regulation of NB69 Cell Proliferation Implication of Free Radicals med./bio.

Aim of study (acc. to author)

Background/further details

Endpoint

Exposure

Exposure 1

Main characteristics

Exposure setup

Parameters

Additional parameter details

Exposure 2

Main characteristics

Exposure setup

Parameters

Reference articles

Methods Endpoint/measurement parameters/methodology

Main outcome of study (acc. to author)

Study funded by

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