Medical/biological study (experimental study)

Exposure to an Extremely-Low-Frequency Magnetic Field Stimulates Adrenal Steroidogenesis via Inhibition of Phosphodiesterase Activity in a Mouse Adrenal Cell Line med./bio.

By: Kitaoka K, Kawata S, Yoshida T, Kadoriku F, Kitamura M

Published in: PLoS One 2016; 11 (4): e0154167-

Aim of study (acc. to author)

The effects of exposure of mouse and human adrenal cortex-derived cells to a 60 Hz magnetic field on steroid hormone production and the underlying mechanisms of action should be investigated.

Background/further details

Except for one test, all experiments, a magnetic flux density of 1.5 mT was used. Only for the quantification of corticosterone, mouse adrenal cortex-derived cells were exposed to 0.25 mT, 0.5 mT, 1.5 mT and 3 mT.

Endpoint

endocrine changes: steroid hormone production in adrenal cells

Exposure

- 60 Hz
- 50/60 Hz
- magnetic field

Exposure	Parameters
Exposure 1: 60 Hz Exposure duration: for 1 h, 6 h, 24 h or 48 hours	magnetic flux density: 1.5 mT
Exposure 2: 60 Hz Exposure duration: for 24 hours	magnetic flux density: 0.25 mT
Exposure 3: 60 Hz Exposure duration: for 24 hours	magnetic flux density: 0.5 mT
Exposure 4: 60 Hz Exposure duration: for 24 hours	magnetic flux density: 3 mT

Exposure 1

Main characteristics

Frequency	60 Hz
Type	magnetic field
Exposure duration	for 1 h, 6 h, 24 h or 48 hours

Exposure setup

Exposure source	coil(s)
Chamber	cell culture dishes in incubator
Setup	the exposure apparatus consisted of a cylindrical plastic (polyvinyl chloride) container (37 cm outer diameter, 34.5 cm inner diameter, 33 cm length) placed vertically with a coil inside; the coil consisted of one primary coil and two secondary coils that were placed on the upper and lower ends of the primary coil; coils were made of enameled wires (2.12 mm diameter); for the primary coil, the wire was wound 150 times around the plastic container; for the two secondary coils, the wire was wound 33 times around every layer to correct the uneven distribution of the magnetic flux density of the primary coil; a plastic incubator (25 cm length, 20 cm width and 10 cm height) containing the culture dishes was placed in the middle of each plastic container; to maintain the temperature of 37 ± 0.5°C and 5% CO₂ in the incubator, warm water (40 ± 0.5°C) and 5% CO₂ air were supplied in the container; the temperature difference between ELF-MF and sham exposure apparatuses was maintained within ± 0.5°C
Sham exposure	A sham exposure was conducted.
Additional info	sham exposure was performed simultaneously with exposure using a sham apparatus, which was made using the same materials with the same size, except for the coil

Parameters

Measurand	Value	Type	Method	Mass	Remarks
magnetic flux density	1.5 mT	-	measured	-	-

Additional parameter details

background ELF magnetic flux density was 40-50 µT and static magnetic flux density was 25-30 µT in apparatuses

Exposure 2

Main characteristics

Frequency	60 Hz
Type	magnetic field
Exposure duration	for 24 hours

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	0.25 mT	-	measured	-	-

Exposure 3

Main characteristics

Frequency	60 Hz
Type	magnetic field
Exposure duration	for 24 hours

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	0.5 mT	-	measured	-	-

Exposure 4

Main characteristics

Frequency	60 Hz
Type	magnetic field
Exposure duration	for 24 hours

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	3 mT	-	measured	-	-

Reference articles

Soda A et al. (2008): Effect of exposure to an extremely low frequency-electromagnetic field on the cellular collagen with respect to signaling pathways in osteoblast-like cells

Exposed system:

intact cell/cell culture
mouse adrenal cortex-derived cells (Y-1) and human adrenal cortex-derived cells (H295R)

Methods Endpoint/measurement parameters/methodology

molecular biosynthesis: gene expression of adrenal steroid hormone synthesis related genes after 24 h: mouse steroidogenic acute regulatory protein (StAR), mouse cytochrome P450 (Cyp)11a1, Cyp11b1, Cyp11b2 (only in Y-1 cells) and human StAR, human cytochrome P450 (Cyp)11a1, Cyp11b1, Cyp11b2, Cyp17a1 (only in H295R cells) (real-time RT-PCR); protein expression after 6 h and 24 h of StAR, CYP11B2, CYP17A1, CREB and phosphorylated CREB (Western blot); cyclic adenosine monophosphate (cAMP) quantification after 24 h (only with Y-1 cells with and without addition of 10 µM or 30 µM NF449 (inhibitor of G protein), ELISA); total protein concentration (BCA protein assay)
cell function: phosphodiesterase (for degradation of cAMP) enzyme activity after 1 h, 6 h and 24 h (commercial kit), intracellular calcium concentration after 24 h (FURA-2 stain, fluorescence analysis) (only with Y-1 cells)
endocrine changes: quantification of adrenal steroid hormones (corticosterone (only in Y-1 cells), aldosterone and cortisol (only in H295R cells) after 1 h, 6 h, 24 h and 48 h of exposure (ELISA))

Investigated system:

isolated bio./chem. substance
DNA/RNA
intact cell/cell culture
cell extracts, culture medium

Time of investigation:

during exposure
after exposure

Main outcome of study (acc. to author)

Exposure to the magnetic field was found to significantly increase the secretion of corticosterone and aldosterone and the gene expression and/or protein expression of Cyp11a1 and Cyp11b2 in mouse Y-1 cells compared to the control group. It was also found that only a magnetic flux density of 0.5 mT or more could induce a significant increase in corticosterone secretion in exposed Y-1 cells compared to the control group.
Exposed Y-1 cells showed significant decreases in phosphodiesterase enzyme activity and intracellular calcium concentration and significant increases in cAMP concentration and CREB phosphorylation compared to cells of the control group. The increase in cAMP concentration was not inhibited by treatment with NF449, suggesting that it did not result from an activation of G protein-coupled receptors.
No effects were found in human adrenal cortex-derived cells.
The authors conclude that exposure of mouse adrenal cortex-derived cells to a 60 Hz magnetic field might stimulate the steroid hormone production via an increase in intracellular cAMP caused by the inhibition of phosphodiesterase enzyme activity.

Study character:

medical/biological study
experimental study
full/main study

Study funded by

Japan Society for the Promotion of Science (JSPS), Japan

Kitaoka K et al. (2013): Chronic exposure to an extremely low-frequency magnetic field induces depression-like behavior and corticosterone secretion without enhancement of the hypothalamic-pituitary-adrenal axis in mice
Kitaoka K et al. (2013): Erratum: Low-frequency magnetic field induces depression-like behavior and corticosterone secretion without enhancement of the hypothalamic-pituitary-adrenal Axis in mice
Szemerszky R et al. (2010): Stress-related endocrinological and psychopathological effects of short- and long-term 50Hz electromagnetic field exposure in rats
Mostafa RM et al. (2002): Effects of exposure to extremely low-frequency magnetic field of 2 G intensity on memory and corticosterone level in rats
Selmaoui B et al. (1997): Endocrine functions in young men exposed for one night to a 50-Hz magnetic field. A circadian study of pituitary, thyroid and adrenocortical hormones
Picazo ML et al. (1996): Changes in mouse adrenalin gland functionality under second-generation chronic exposure to ELF magnetic fields. I. males

Exposure to an Extremely-Low-Frequency Magnetic Field Stimulates Adrenal Steroidogenesis via Inhibition of Phosphodiesterase Activity in a Mouse Adrenal Cell Line 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

Exposure 3

Main characteristics

Exposure setup

Parameters

Exposure 4

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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