Elevated sister chromatid exchange frequencies in dividing human peripheral blood lymphocytes exposed to 50 Hz magnetic fields

The in vitro cytomolecular technique, sister chromatid exchange (SCE), was applied to test the clastogenic potentiality of extremely low frequency (ELF) electromagnetic fields (EMFs) on human peripheral blood lymphocytes (HPBLs). SCE frequencies were scored in dividing peripheral blood lymphocytes (PBLs) from six healthy male blood donors in two rounds of experiments, R1 and R2, to determine reproducibility. Lymphocyte cultures in the eight experiments conducted in each round were exposed to 50 Hz sinusoidal (continuous or pulsed) or square (continuous or pulsed) MFs at field strengths of 1 microT or 1 mT for 72 h. A significant increase in the number of SCEs/cell in the grouped experimental conditions compared to the controls was observed in both rounds. The highest SCE frequency in R1 was 10.03 for a square continuous field, and 10.39 for a square continuous field was the second highest frequency in R2. DNA crosslinking at the replication fork is proposed as a model which could explain the mechanistic link between ELF EMF exposure and increased SCE frequency.     

Implications of an elevated sister-chromatid exchange frequency in rat lymphocytes cultured in the absence of erythrocytes

One important variable in complex culture systems such as whole blood is the interaction of the cell types present. To investigate the effects of erythrocytes (RBCs) and monocytes on the sister-chromatid exchange (SCE) frequency, Ficoll-Hypaque-separated Fischer-344 rat leukocytes were added to 1.9 ml of culture medium containing either 4 micrograms phytohemagglutinin or 4-8 micrograms concanavalin A/ml. Bromodeoxyuridine (BrdU;2 microM) was added at 24 h, and the cultures were harvested at 54 or 72 h. SCE frequencies in the mononuclear leukocyte cultures were consistently about 1.5- to 2-fold higher than in the whole-blood cultures. The titration of rat or human RBCs (0.05-2.5 X 10(9)) into purified rat leukocyte cultures reduced the SCE frequency to that of whole-blood cultures. Monocyte depletion decreased the elevated SCE frequency by approximately 50%. Scintillation counting of [14C]BrdU uptake in isolated RBCs revealed that less than 8% of the total amount of BrdU was sequestered. Also, BrdU induced a concentration-dependent increase in SCE in purified leukocytes, but the absolute increase was no greater than in whole-blood lymphocytes. Thus, BrdU had a minor role in the elevated SCE frequency in purified lymphocytes. Neither anti-oxidant enzymes such as catalase and superoxide dismutase nor the hydroxyl radical scavenger, dimethyl sulfoxide, decreased the SCE frequency. Although purified human lymphocytes had a small, but significant increase in SCE compared to whole blood, the magnitude of the dichotomous response between man and rat may represent a fundamental species difference.     

Cytogenetic effects of pulsing electromagnetic field on human lymphocytes in vitro: chromosome aberrations, sister-chromatid exchanges and cell kinetics

Exposure of human lymphocyte cultures to a pulsing electromagnetic field (PEMF; 50 Hz, 1.05 mT) for various durations (24, 48 and 72 h) resulted in a statistically significant suppression of mitotic activity and a higher incidence of chromosomal aberrations. Furthermore, the shorter exposure times (24 and 48 h) did not cause a significant delay in cell turnover (cell proliferation index) or an increase in the baseline frequency of sister-chromatid exchanges (SCE). However, cultures continuously exposed to PEMF for 72 h exhibited significant reduction of the cell proliferation index (CPI) and an elevation of SCE rate. These results suggest that exposure to PEMF may induce a type of DNA lesions that lead to chromosomal aberrations and cell death but not to SCE, except probably at longer exposure times.     

Cytological effects of 60 Hz magnetic fields on human lymphocytes in vitro: sister-chromatid exchanges, cell kinetics and mitotic rate

Incubation for 72 h of human peripheral blood cultures in the presence of 60 Hz sinusoidal magnetic fields (MF) at magnetic flux densities of 1.0, 1.5, and 2.0 mT led to stimulation of lymphocyte proliferation but had no influence on the frequency of sister-chromatid exchanges (SCE). The cytotoxic potential of MF combined with the mutagen Mitomycin-C also was analyzed. An opposite effect between MF exposure and Mitomycin-C treatment in terms of cell kinetics and mitotic rate was found, whereas no variation in SCE frequency was observed for this coexposure condition.     

Effect of high-density extremely low frequency magnetic field on sister chromatid exchanges in mouse m5S cells

The induction of sister chromatid exchanges (SCEs) was evaluated in the cultured mouse m5S cells after exposure to extremely low frequency magnetic field (ELFMF; 5, 50 and 400 mT). Exposure to 5 mT and 50 mT ELFMF led to a very small increase in the frequency of SCEs, but no significant difference was observed between exposed and unexposed control cells. The cells exposed to 400 mT ELFMF exhibited a significant elevation of the SCE frequencies. There was no significant difference between data from treatments with mitomycin-C (MMC) alone and from combined treatments of MMC plus ELFMF (400 mT) at any MMC concentrations from 4 to 40 nM. These results suggest that exposure to highest-density ELFMF of 400 mT may induce DNA damage, resulting in an elevation of the SCE frequencies. We suppose that there may be a threshold for the elevation of the SCE frequencies, that is at least over the magnetic density of 50 mT.     

Effect of high-density extremely low frequency magnetic field on sister chromatid exchanges in mouse m5S cells

The induction of sister chromatid exchanges (SCEs) was evaluated in the cultured mouse m5S cells after exposure to extremely low frequency magnetic field (ELFMF; 5, 50 and 400 mT). Exposure to 5 mT and 50 mT ELFMF led to a very small increase in the frequency of SCEs, but no significant difference was observed between exposed and unexposed control cells. The cells exposed to 400 mT ELFMF exhibited a significant elevation of the SCE frequencies. There was no significant difference between data from treatments with mitomycin-C (MMC) alone and from combined treatments of MMC plus ELFMF (400 mT) at any MMC concentrations from 4 to 40 nM. These results suggest that exposure to highest-density ELFMF of 400 mT may induce DNA damage, resulting in an elevation of the SCE frequencies. We suppose that there may be a threshold for the elevation of the SCE frequencies, that is at least over the magnetic density of 50 mT.     

Analyses for in vitro growth conditions,cytokinetics, and sister chromatid exchanges in lymphocytes cultured from the Sprague-Dawley rat

Summary Peripheral blood samples from Sprague-Dawley rats gave successful lymphocyte growth in GIBCO: IA, RPMI 1640, and Eagle's minimum essential medium (MEM) culture media. Various growth conditions, cytokinetics, and sister chromatic exchange (SCE) induction were studied using reconstituted GIBCO 1A only. Neither methoxyflurane anesthesia of the rats before sampling nor washing of the cells with phosphate buffered saline affected the mitotic index. Cultures treated with [³H]thymidine showed the lymphocytes entering into DNA synthesis after approximately 24 h. The time at which BUdR (5-bromo-2′ deoxyuridine) was added, i.e. 0 vs. 24 h incubation, had minimal effect on the mitotic index of cultures harvested at 48 h. However, when harvest was extended to 72 h, mitotic activity was greater in the cultures treated with BUdR at 24 h. No significant differences in mitotic index and the number of average lymphocyte division were detected in cultures exposed to 0.3 to 0.5 μg/ml BUdR at 24 h and harvested at 72 h. Although SCE frequencies increased in the presence of BUdR, the baseline level of SCEs was estimated to be 5 to 6/cell. Average generation time of the lymphocytes dividing between 48 and 72 h was 16.5 h. Because of its simplicity of culture and the reproducible nature of its in vitro growth kinetics, the Sprague-Dawley rat lymphocyte is a suitable model for cytogenetic investigations.     

Cytogenetic Changes in Human Lymphocytes from Workers Occupationally Exposed to High-Voltage Electromagnetic Fields

The present study was carried out to assess the possible cytogenetic changes in peripheral blood lymphocytes as a means of monitoring human populations subjected to environmental electromagnetic fields. The mean frequencies of chromosome aberrations (CA) and sister-chromatid exchanges (SCE) were determined in 72-h whole blood cultures from 15 workers (mean age 31.4 ± 5.6 years) occupationally exposed to 50 Hz electromagnetic field from a 132-230 kV electric supply substation.

Compared to a control group of eight men (mean age 31.6 ± 6.12 years), the percentage of aberrant cells was significantly increased (12.83 ± 1.28% for exposed and 7.00 ± 0.6% for nonexposed). No statistical difference was observed in the mean SCE values between the exposed (5.40 ± 0.15) and the nonexposed (5.12 ± 0.55) groups.

Furthermore, the cell proliferation index (CPI) and the mitotic index (MI) were analyzed. The two indices were significantly lower in the exposed group than in the nonexposed one: 1.44 versus 1.60 and 1.45 versus 1.79 for the two indices, respectively. The smoking habit did not influence any of the parameters investigated.     

Sister chromatid exchanges in bromine incorporation into DNA cytosine nucleotides. III. 5-bromodeoxycytidine as a DNA thymine precursor. The characteristics of the exchanges]

Cell movement through the mitotic cycle and sister chromatid exchanges (SCE) were studied in human blood lymphocytes cultured in the presence of 5-bromodeoxycytidine (BrdC, 0.05 mM) plus thymidine (dT 0.4, 0.8, and 1.0 mM). In controls, lymphocytes were cultivated in the presence of 5-bromodeoxyuridine (BrdU, 0.05 mM) and deoxycytidine (0.1 mM), or BrdC alone. All nucleosides were added to the cultures 28 hours prior to fixation and were maintained in the medium for 16 hours. As determined from percentage of metaphases of 1st to 3rd divisions, BrdC did not release from thymidine block. This fact leads us to conclude that BrdC in contrast to deoxycytidine does not serve as a cytosine precursor. No significant differences in the frequency of SCE and their distribution among chromosomes were found between cultures treated with BrdC and with BrdU.     

Physical,chemical, and biological factors affecting sister-chromatid exchange induction in human lymphocytes exposed to mitomycin C prior to culture

In experiments to assess the effects of several biological, chemical, and physical variables on sister-chromatid exchange (SCE) induction in cultured lymphocytes exposed to mitomycin C (MMC) before PHA stimulation we observed: (1) high SCE frequencies in female cells, and normal SCE frequencies in Y-bearing metaphases in mixed cultures containing equal numbers of MMC-treated female lymphocytes and untreated male lymphocytes; (2) small, but statistically significant, decreases in SCEs with increasing pH after G₀ exposure in the pH range 6.6–7.6; (3) pronounced reductions in MMC-induced SCEs in lymphocytes exposed at 4°C vs. 37°C. In other studies, SCE induction was evaluated in cultures exposed during G₀ to MMC concentrations ranging from 0.25 to 2.5 μg/ml for varying time intervals ranging from 5 min to 24 h. For all concentrations tested SCE induction varied as a linear function of G₀ exposure time. To compare SCE induction between cultures, we calculated the mean frequencies of SCEs induced per metaphase/unit dose MMC/unit G₀ exposure time (SCE/μg/h). A mean frequency of 20.7 ± 4.8 SCE/μg/h was observed for 41 lymphocyte cultures suggesting that a single term adequately describes the rate of SCE induction following G₀ exposure to a 10-fold range in concentration of MMC for time intervals of 30 min to 24 h.     

Chemical induction of sister-chromatid exchanges in human lymphocytes treated in G0 prior to stimulation by different mitogens and revealed 72 h later in second division cells

Frequencies of sister-chromatid exchanges (SCE) were determined in second-division metaphases of human lymphocytes, exposed for 1 h during the G0 phase to mitomycin C (MMC) alone or to cyclophosphamide (CP) in the presence of S9 mix. The cells were then cultured for 72 h in the presence of phytohemagglutinin (PHA), concanavalin A (Con A), Wistaria floribunda (WFA) or Lens culinaris (LcH-A) extracts. Large differences in mitotic indices (MI) and cell-cycle kinetics were observed among cells subjected to the various treatments. However, in the controls as well as in the cultures submitted to a G0 mutagenic exposure, the yield of SCE was not influenced by the mitogenic agent and was, therefore, independent of the proliferation properties of the cultured lymphocyte population.     

Sister-chromatid exchange in highly purified human CD4+ and CD8+ lymphocytes.

Sister-chromatid exchange (SCE) frequencies were determined in human peripheral blood CD₄⁺ and CD₈⁺ T lymphocyte subpopulations which were rapidly and highly purified from pooled T lymphocytes by immunological methods. The purified lymphocytes were stimulated with phytohemagglutinin (PHA) for 4 days. CD₄⁺ lymphocytes showed significantly higher SCE frequencies than autologous CD₈⁺ lymphocytes when measured simultaneously after identical bromodeoxyuridine (BrdU) incubation times. Differences in SCE frequencies between CD₄⁺ and CD₈⁺ lymphocytes were also detected when mitomycin C (MMC) was added to the cultures. Higher SCE frequencies in CD₄⁺ lymphocytes were associated with lower proliferating rate indices (PRI) as compared to autologous CD₈⁺ lymphocytes. Abnormalities in CD₄⁺ T lymphocyte function and number in peripheral blood have been observed in several diseases characterized by immunological disorders. Thus, our data may suggest a link between some immunological disturbances and abnormal SCE frequencies in T lymphocyte subsets.     

Spontaneous sister-chromatid exchange frequencies in human B and T lymphocytes at BrdU borderline concentrations for sister-chromatid differentiation

Human peripheral blood B and T lymphocytes, highly purified by immunologic methods, were supplemented with gamma-irradiated unseparated autologous mononuclear cells to restore helper functions and stimulated with pokeweed mitogen and phytohemagglutinin, respectively. Spontaneous sister-chromatid exchange (SCE) frequencies were investigated in proliferating B and T lymphocyte cultures labeled with the cell-type-specific borderline concentrations of 5-bromodeoxyuridine (BrdU) for sister-chromatid differentiation (SCD). B lymphocytes from 6 different donors showed mean values of 3.28-3.72 SCE events/cell. In T lymphocytes, mean values of 6.30-7.28 SCEs/cell were observed. The differences between the SCE distributions of the cell populations are highly significant. The results show that the differences in the spontaneous SCE frequencies between human B and T lymphocytes were not due to a difference in the uptake of BrdU.     

Applied AC and DC magnetic fields cause alterations in the mitotic cycle of early sea urchin embryos

This study demonstrates that exposure to 60 Hz magnetic fields (3.4–8.8 mT) and magnetic fields over the range DC-600 kHz (2.5–6.5 mT) can alter the early embryonic development of sea urchin embryos by inducing alterations in the timing of the cell cycle. Batches of fertilized eggs were exposed to the fields produced by a coil system. Samples of the continuous cultures were taken and scored for cell division. The times of both the first and second cell divisions were advanced by ELF AC fields and by static fields. The magnitude of the 60 Hz effect appears proportional to the field strength over the range tested. The relationship to field frequency was nonlinear and complex. For certain frequencies above the ELF range, the exposure resulted in a delay of the onset of mitosis. The advance of mitosis was also dependent on the duration of exposure and on the timing of exposure relative to fertilization. © 1995 Wiley-Liss, Inc.     

Cell shape and plasma membrane alterations after static magnetic fields exposure

The biological effects of static magnetic fields (MFs) with intensity of 6 mT were investigated in lymphocytes and U937 cells in the presence or absence of apoptosis-inducing drugs by transmission (TEM) and scanning (SEM) electron microscopy. Lectin cytochemistry of ConA-FITC conjugates was used to analyze plasma membrane structural modifications. Static MFs modified cell shape, plasma membrane and increased the level of intracellular [Ca++] which plays an antiapoptotic role in both cell types. Modifications induced by the exposure to static MFs were irrespective of the presence or absence of apoptotic drugs or the cell type. Abundant lamellar-shaped microvilli were observed upon 24 hrs of continuous exposure to static MFs in contrast to the normally rough surface of U937 cells having numerous short microvilli. Conversely, lymphocytes lost their round shape and became irregularly elongated; lamellar shaped microvilli were found when cells were simultaneously exposed to static MFs and apoptosis-inducing drugs. In our experiments, static MFs reduced the smoothness of the cell surface and partially impeded changes in distribution of cell surface glycans, both features being typical of apoptotic cells. Cell shape and plasma membrane structure modifications upon static MFs exposure were time-dependent. Lamellar microvilli were clearly observed before the distortion of cell shape, which was found at long times of exposure. MFs exposure promoted the rearrangement of F-actin filaments which, in turn, could be responsible for the cell surface modifications. Here we report data that support biological effects of static MFs on U937 cells and human lymphocytes. However, the involvement of these modifications in the onset of diseases needs to be further elucidated.     

Effect of 60-Hz magnetic fields on ultraviolet light-induced mutation and mitotic recombination in Saccharomyces cerevisiae.

The purpose of this study was to examine the effect of extremely low frequency (ELF) magnetic fields on the induction of genetic damage. In general, mutational studies involving ELF magnetic fields have proven negative. However, studies examining sister-chromatid exchange and chromosome aberrations have yielded conflicting results. In this study, we have examined whether 60-Hz magnetic fields are capable of inducing mutation or mitotic recombination in the yeast Saccharomyces cerevisiae. In addition we determined whether magnetic fields were capable of altering the genetic response of S. cerevisiae to UV (254 nm). We measured the frequencies of induced mutation, gene conversion and reciprocal mitotic crossing-over for exposures to magnetic fields alone (1 mT) or in combination with various UV exposures (2-50 J/m2). These experiments were performed using a repair-proficient strain (RAD+), as well as a strain of yeast (rad3) which is incapable of excising UV-induced thymine dimers. Magnetic field exposures did not induce mutation, gene conversion or reciprocal mitotic crossing-over in either of these strains, nor did the fields influence the frequencies of UV-induced genetic events.     

Effects of anticoagulants upon sister-chromatid exchanges, cell-cycle kinetics, and mitotic index in human peripheral lymphocytes

The effects of 3 blood anticoagulants, heparin, acid citrate dextrose (ACD), and ethylenediaminetetraacetic acid (EDTA) were investigated using human peripheral lymphocytes. Three different endpoints were examined: sister-chromatid exchange (SCE), cell kinetics index (CKI), and mitotic index (MI). SCEs were significantly increased in cells treated with EDTA, while the CKI and MI were significantly decreased in cultures treated with either ACD or EDTA when compared to cultures treated with heparin. These results suggest that anticoagulants may produce undesired effects upon cultured cells and indicate that the type of anticoagulant should be considered carefully prior to commencing cytogenetic studies using human peripheral lymphocytes.     

Sister-chromatid exchange in highly purified human CD4 and CD8 lymphocytes

Sister-chromatid exchange (SCE) frequencies were determined in human peripheral blood CD₄⁺ and CD₈⁺ T lymphocyte subpopulations which were rapidly and highly purified from pooled T lymphocytes by immunological methods. The purified lymphocytes were stimulated with phytohemagglutinin (PHA) for 4 days. CD₄⁺ lymphocytes showed significantly higher SCE frequencies than autologous CD₈⁺ lymphocytes when measured simultaneously after identical bromodeoxyuridine (BrdU) incubation times. Differences in SCE frequencies between CD₄⁺ and CD₈⁺ lymphocytes were also detected when mitomycin C (MMC) was added to the cultures. Higher SCE frequencies in CD₄⁺ lymphocytes were associated with lower proliferating rate indices (PRI) as compared to autologous CD₈⁺ lymphocytes. Abnormalities in CD₄⁺ T lymphocyte function and number in peripheral blood have been observed in several diseases characterized by immunological disorders. Thus, our data may suggest a link between some immunological disturbances and abnormal SCE frequencies in T lymphocyte subsets.     

No effect of exposure to static and sinusoidal magnetic fields on nitric oxide production by macrophages

The effects of exposure to static (1–100 mT) or sinusoidal (1 Hz, 1.6 mT) magnetic fields on the production of nitric oxide (NO) by murine BCG-activated macrophages were investigated. In these cells, the inducible isoform of NO synthase is present. No significant differences were observed in nitrite levels among exposed, sham-exposed, or control macrophages after exposure for 14 h to static fields of 1, 10, 50, and 100 mT and to sinusoidal 1.6 mT, 1 Hz magnetic fields. © 1996 Wiley-Liss, Inc.     

No evidence of cellular alterations by MilliTesla-level static and 50 Hz magnetic fields on S. cerevisiae

In an attempt to determine whether magnetic field (MF) exposures might induce cellular alterations, S. cerevisiae yeast cells were exposed to static or sinusoidal 50?Hz homogeneous MF (0.35?mT, 1.4?mT, and 2.45?mT) for 1?h and 72?h. Unsynchronized cells grown exponentially while exposed to MF, containing cells in all stages of the mitotic cell cycle. MF was generated by a pair of Helmholtz coils (40?cm in diameter, coaxial, separated by 20?cm). Survival, cell cycle distribution, colony forming ability, and mutation frequency were assayed. No differences in the above-mentioned parameters were observed in MF exposed samples in relation to unexposed controls, suggesting that homogeneous MF at these intensities do not produce appreciable cellular alterations in this organism under typical in vitro growth conditions.