HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Full Text (PDF) All Versions of this Article: 19/12/1686 04-3549fjev1    most recent Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Nikolova, T. Articles by Wobus, A. M. Search for Related Content PubMed PubMed Citation Articles by Nikolova, T. Articles by Wobus, A. M.

Electromagnetic fields affect transcript levels of apoptosis-related genes in embryonic stem cell-derived neural progenitor cells

Teodora Nikolova^*, Jaroslaw Czyz^*,1, Alexandra Rolletschek^*, Przemyslaw Blyszczuk^*, Jörg Fuchs^*, Gabriele Jovtchev^*, Jürgen Schuderer, Niels Kuster and Anna M. Wobus^*,2

^* Institute of Plant Genetics and Crop Plant Research (IPK), Gatersleben, Germany;
Foundation for Research on Information Technologies in Society (IT’IS), Zurich, Switzerland

² Correspondence: In Vitro Differentiation Group, Institute of Plant Genetics and Crop Plant Research (IPK), Correnstr.3, D-06466 Gatersleben, Germany. E-mail: wobusam{at}ipk-gatersleben.de

SPECIFIC AIMS

In the present study we aimed to investigate the effects of radiofrequency (RF) and extremely low frequency (ELF) electromagnetic fields (EMF) on the transcript level of cell cycle regulatory and apoptosis-related genes, on proliferation, apoptosis and chromosomal damage in neural progenitors generated from pluripotent mouse embryonic stem cells in vitro.

PRINCIPAL FINDINGS

1. ELF-EMF exposure affected bcl-2, bax, and GADD45 transcript levels in embryonic stem (ES) cell-derived neural progenitors
Pluripotent mouse ES cells were cultured as aggregates ("embryoid bodies," EBs) for 4 days followed by differentiation induction into neural progenitor and neuronal cells (Fig. 1 ). Differentiation of 4d EBs resulted in up to 85% of nestin-positive neural progenitor cells 4–6 days after plating. The cells were exposed to 50 Hz powerline ELF-EMF for 48 h at day 4+4, differentiated into the neuronal lineage, and analyzed at various time points. Magnetic flux density of 2 mT was applied with 5 min ON/ 30 min OFF intermittency cycles. The ELF exposure setup allowed studies under "blind" conditions and the control of temperature differences (±0.2°C) for sham- and ELF-EMF-exposed cultures. Quantitative (Q) RT-PCR analysis (Fig. 2 ) showed a relative increase of bcl-2 and bax mRNA levels at stage 4+11d relative to transcript levels of GAPDH, used as an internal standard. Transcript levels of the "growth arrest and DNA damage-inducible gene" GADD45 were down-regulated at terminal stage (4+23d, Fig. 2A ). Immunofluorescence analysis of EMF- and sham-exposed cells, however, showed no differences in the intracellular distribution and number of cells expressing neuronal (ßIII-tubulin, tyrosin hydroxylase, TH) or astrocytic (glial fibrillary acidic protein, GFAP) proteins.

View larger version (33K): [in this window] [in a new window]   Figure 1. ES (R1) cells were cultured as "embryoid bodies" (EBs) for 4 days (4d). After plating of 4d EBs to gelatin-coated culture plates, cells start to differentiate. The formation of nestin-positive neural progenitor cells was induced by medium containing insulin, transferrin, selenium, and fibronectin (ITSFn). The neural progenitor cells were exposed to EMF [ELF-EMF (50 Hz Powerline; 2.0 mT; intermittency scheme, 5 min ON/ 30 min OFF)- or RF-EMF (GSM signal 217 Hz; 1.5 W/kg; 1.71 GHz; intermittency scheme, 5 min ON/ 30 min OFF)] at day 4+4 for 6 and 48 h, respectively. After exposure, cells were analyzed for transcriptional levels of regulatory genes by quantitative (Q) RT-PCR, for the induction of DNA breaks by the COMET assay, for chromosomal aberrations (CA) and sister chromatid exchanges (SCE), for proliferation by BrdU incorporation into nestin-positive cells (by immunofluorescence analysis, IF) and by the estimation of the 1st, 2nd, and 3rd mitosis (M1: M2: M3) ratio, for nuclear apoptosis by FACS analysis of cells with hypodiploid content (subG1 fraction) and for mitochondrial function by the Mitotracker CM-H2X ROS assay. At day 4+8, EB outgrowths were dissociated and replated onto poly-L-ornithine/laminin-coated tissue culture plates. At day 4+14, differentiation induction into neuronal and glial cells was induced by cultivation in "Neurobasal" medium supplemented by neurotrophic and survival promoting factors. At various stages of neural differentiation, cells were analyzed for transcript levels of neural genes by Q-RT-PCR, and for expression of neuronal (ßIII-tubulin, tyrosine hydroxylase, TH) and glial proteins (GFAP) by IF.

View larger version (43K): [in this window] [in a new window]   Figure 2. Q-RT-PCR analysis was applied to determine relative mRNA levels in ELF- and RF-EMF-exposed ES-derived neural progenitor cells. Bcl-2, GADD45, bax, p53, nestin, Nurr1, and TH (tyrosine hydroxylase) transcript levels were evaluated. Transcript level of the mouse GAPDH gene was used as endogenous reference. The TaqMan probes for Q-RT-PCR were 5'-labeled with FAM (6-carboxyfluorescein) and with 3' quencher, TAMRA. Template-free controls were used as negative controls. Control samples (before exposure) were collected at day 4+4. Cells were exposed to ELF-EMF (A) and RF-EMF (B) for 48 h and collected at days 7, 11, 17, and 23 after plating. Q-RT-PCR reactions were carried out in 96-well plates (separate wells) using iCycler IQ Optimal Software, Version 3.0.6070 (BioRad). The relative mRNA levels were calculated using the comparative Ct method. Error bars represent standard deviations of n = 10 RT-PCR reactions (5 experiments with 2 replicates/experiment). Statistical significance was tested by the nonparametric Mann-Whitney test. A) ELF-EMF induced up-regulation of bcl-2 and bax at stage 4+11d (**P0.01; *P0.05) and down-regulation of GADD45 at stage 4+23d (**P0.01). B) RF-EMF induced up-regulation of bax at stage 4+17d (*P0.05) and of GADD45 mRNA levels at stage 4+23d, as well as down-regulation of Nurr1 at stage 4+7d (*P0.05).

2. RF-EMF exposure affected Nurr1, bax, and GADD45 transcript levels in neural progenitor cells
According to the experimental protocol described above, ES-derived neural cells were exposed to RF-EMF at stage 4+4d for 48 h. The RF-EMF setup was defined to operate at 1.71 GHz, which is within the up-link band of the GSM1800 system, also named GSM DCS [Digital Communication System]. The GSM signals were amplitude modulated by rectangular pulses with a repetition frequency of 217 Hz corresponding to the dominant modulation component of GSM. Signals were applied to the cells at time-averaged specific absorption rate (SAR) values of 1.5 W/kg with intermittency cycles of 5 min ON/30 min OFF.

Exposure of ES-derived cells to RF-EMF revealed an up-regulation of bax at stage 4+17d and of GADD45 mRNA level at stage 4+23d (Fig. 2B ). Transcript levels of Nurr1 (a transcription factor implicated in the development of dopaminergic neurons) were significantly down-regulated at stage 4+7d, whereas IF analysis showed that the distribution and abundance of neuronal and glial proteins were not affected.

3. RF-EMF induced transient double-strand DNA breaks in neural progenitor cells at low level
To study primary DNA damage in neural progenitor cells, we applied 6 h and 48 h EMF exposure followed by the alkaline (detecting single-strand breaks) and neutral (detecting double-strand breaks) COMET assay. We found a low but statistically significant increase of DNA double-strand breaks in ES-derived progenitor cells immediately after 6 h RF-EMF exposure (Fig. 3 ). The exposure of cells to 48 h RF-EMF did not result in DNA break induction suggesting the activation of short-term and transient responses by RF-EMF (similarly, 6 and 48 h ELF-EMF exposure did not induce single- or double-strand DNA breaks).

View larger version (19K): [in this window] [in a new window]   Figure 3. COMET assay for the detection of single- and double-strand DNA breaks in EMF- and sham-exposed ES-derived neural progenitor cells. A) Cells were exposed at stage 4+4d. After 6 h RF-EMF exposure, alkaline and neutral COMET assays were performed immediately after exposure (t=0 h) or after a recovery time of 18 h (t=18 h). Ethidium bromide stained nuclei (n=1000) of cells from EMF- and sham-exposed variants were analyzed by fluorescence microscopy, classified into 5 groups according to tail length and intensity and the tail factor calculated as % value. Statistical significance was analyzed by Student’s t test (*P0.05). B) Examples of COMETs found in ES-derived neural progenitor cells immediately after 6 h RF-EMF exposure were classified into group A (0–5% DNA damage), B (5–20%), C (20–40%), D (40–95%) and E (>95%). Bar: 50 µm.

4. RF- and ELF-EMF exposure did not induce cytogenetic effects or detectable changes of cell proliferation and apoptosis
Metaphase analysis of EMF-exposed ES-derived neural cells did not present evidence for the induction of chromosomal aberrations (CA) or sister chromatid exchanges (SCE). Determination of BrdU-positive/nestin-positive (BrdU+/nestin+) cells (as % of Hoechst 33342-labeled cells) and the estimation of the number of cells in the 1st, 2nd, and 3rd mitosis (M1: M2: M3 ratio) did not indicate changes in the proliferation rate of EMF-exposed cells. The mitochondrion-selective dye (Mitotracker CM-H2X ROS) applied to detect loss of mitochondrial membrane potential, as an early marker of apoptosis, did not show EMF-induced effects. FACS analysis revealed no significant differences between EMF- and sham-exposed cells with respect to the percentage values of the "subG1 fraction" (=hypodiploid DNA content).

CONCLUSIONS AND SIGNIFICANCE

Epidemiological studies and experimental models using mammalian cells in vivo and in vitro performed to elucidate potential hazardous effects of ELF and RF EMF raised controversies about the involvement of electromagnetic fields in the origin of cancer and/or neurological disorders.

In the present experiments using the ES cell differentiation model, we detected specific changes of transcript levels of various regulatory genes in ES-derived neural progenitor cells exposed to either extremely low electromagnetic fields or high-frequency GSM signals.

ELF-EMF induced a significant up-regulation of transcript levels of two opposing members of the bcl-2 family, bcl-2 and bax. Because the increase of the (anti-apoptotic) bcl-2 level was only slightly higher in comparison to (proapoptotic) bax level, we would not expect significant effects on apoptosis in the neural progenitor cells. Microscopic analysis of selectively stained active mitochondria and FACS analysis of nuclear apoptosis did not show effects on the apoptotic process in EMF- and sham-exposed cells. The down-regulation of transcript levels of GADD45 might be considered as an indication of subtle stimulatory effects on cell proliferation. However, neither the BrdU incorporation into nestin-positive cells, nor the M1: M2: M3 ratio indicated changes in the proliferation rate of EMF-exposed cells. Our finding that neuron (Nurr1, TH)- and glial (GFAP) -specific transcript and protein abundance was not altered, lead us to conclude that ELF-EMF exposure does not affect the process of neural differentiation.

RF-EMF exposure resulted in down-regulation of transcript levels of the neural-specific gene Nurr1 at early stage. Because this effect was observed only after RF-EMF exposure, we may conclude that specific cellular responses are dependent on the electromagnetic field frequency. RF-EMF induced also up-regulation of bax at intermediate and GADD45 mRNA levels at the terminal stage of differentiation. However, similar to ELF-EMF data, we did not detect effects on proliferation and apoptosis. Despite the low induction of DNA double strand breaks in neural progenitor cells after short-term exposure to GSM signals, RF-EMF did not increase the spontaneous frequency (=sham exposure) of chromosomal aberrations and sister chromatid exchanges in ES-derived neural cells.

In summary, we conclude that EMF signals are able to trigger responses at the transcript level of cell cycle regulatory and apoptosis-related genes in neural progenitor cells derived from pluripotent ES cells in vitro. However, due to the lack of effects on other cellular processes including proliferation, chromosomal stability and apoptosis, we postulate that EMF responses at the mRNA level may be gradually compensated at the translational and post-translational level and do not lead to detectable changes of cell physiology.

FOOTNOTES

¹ Present address: Department of Cell Biology, Faculty of Biotechnology, Jagiellonian University, Cracow, Poland.

To read the full text of this article, go to http://www.fasebj.org/cgi/doi/10.1096/fj.04-3549fje;

This Article Full Text (PDF) All Versions of this Article: 19/12/1686 04-3549fjev1    most recent Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Nikolova, T. Articles by Wobus, A. M. Search for Related Content PubMed PubMed Citation Articles by Nikolova, T. Articles by Wobus, A. M.