Effect of sinusoidally varying magnetic fields on cell proliferation and adenosine deaminase specific activity

The effect of sinusoidally varying magnetic fields (SVMF) on chick embryo fibroblasts (CEF) was examined by two independent methods: 1) measurement of cell proliferation at 0.06–0.7 mT (100, 60 and 50 Hz) using a colorimetric assay (MTT); 2) monitoring of specific activity of adenosine deaminase (ADA) at 0.3 and 0.7 mT, 60 Hz. Both increased cell proliferation and reduced ADA specific activity are associated with cell transformation. The MTT test showed an increase in cell proliferation of up to 64% after a 24 h exposure to SVMF at 100 Hz, 0.7 mT. Cell proliferation at constant frequency (100 Hz) depended on SVMF intensity. Cell proliferation at constant intensity (0.7 mT) increased with increasing field frequency. At 0.7 mT, 60 Hz cell proliferation increased by 31%, 28%, and 26% when measured by hemocytometry, ³H-thymidine incorporation, and the MTT assay, respectively. ADA specific activity in CEF decreased by circa 48% on exposure to SVMF at 60 Hz, 0.3 mT for 24 h; only a statistically insignificant trend was seen at 0.7 mT, 60 Hz. Our findings showed that CEF cell proliferation and ADA specific activity were modified by SVMF. Both methods, independently, qualitatively detect a magnetic field effect. Bioelectromagnetics 19:46–52, 1998. © 1998 Wiley-Liss, Inc.     

Effects of time-varying uniform magnetic fields on Natural Killer cell activity and antibody response in mice

Natural Killer cell activity and antibody response were studied in Balb/c mice which were exposed in vivo to uniform pulsed magnetic fields (square-wave, 0.8 Hz, 120 mT maximum field strength, 0.1 s rise-time) for 5 days, 10 h/day. No effects were found in antibody response to sheep red blood cell (SRBC) immunization as assayed by counting the plaque-forming cells (PFC) in the spleens of animals on the sixth day. Following 5-day exposures, the activity of Natural Killer (NK) cells was measured in vitro by challenge with YAC-1 cells, in experiments in which mice were not immunized. An increase of NK cytotoxic activity due to exposure was found which depended on the age of the mice (effect observed above 12 weeks) and on the strength of the applied field (effect observed above 30 mT). © 1993 Wiley-Liss. Inc.     

Permeability change in transformed mouse fibroblasts caused by ionophores,and its relationship to membrane permeabilization by exogenous ATP

Summary Electrogenic ionophores have been found to induce membrane permeabilization in Swiss mouse 3T3 cells that had undergone spontaneous transformation (3T6 cells). Cells attached to plastic dishes were loaded with [³H] uridine, and then the medium was replaced by buffered salt solution at pH 7.8. The enhancement of membrane permeability was assayed by following the efflux of uridine nucleotides, normally impermeant substances. Titration with electrogenic ionophores, such as carbonylcyanidem-chlorophenylhydrazone (CCCP), SF-6847 and gramicidin D, markedly increased the membrane permeability within a very narrow range of ionophore concentration. Nonelectrogenic ionophores, such as monensin and nigericin, did not affect membrane permeability. Measurements of the distribution of the lipophilic cation tetraphenylphosphonium (TPP⁺) between the cells and their environment implied that the remarkable increase in permeability took place within a narrow range of membrane potential (). The data could be explaine by a threshold value, under which aqueous channels are opened in the plasma membrane. The effects exerted by electrogenic ionophores on the plasma membrane were found to be similar to those induced by exogenous ATP. In both cases rapid efflux of K⁺, influx of Na⁺ and reduction of preceded membrane permeabilization to low molecular weight, charged molecules, such as nucleotides. It is suggested that dissipation of induces conformational alterations in membranal components, and/or topological changes, such as aggregation of protein molecules, to form membranal aqueous channels. Electrogenic ionophores permeabilize both normal (3T3) and transformed (3T6) mouse fibroblasts, whereas ATP effects are specific for transformed cells. Thus, it is postulated that ATP actsvia specific sites on the surface of transformed cells.     

An increase in the negative surface charge of U937 cells exposed to a pulsed magnetic field.

Pulsed magnetic fields have been used to enhance healing of bone fractures and purportedly of lesions in soft tissue. However, their mechanism of action is poorly understood. We report changes in the plasma membrane of a nonadherent mammalian cell line, U937, which was exposed to a 25-pps magnetic field for 48 hours. Aqueous polymer two-phase partition studies showed that magnetic-field-exposed cells exhibited an increased negative surface charge but membrane hydrophobicity was not significantly altered. The observed increase in membrane electronegativity of exposed cells did not reflect a significant change in growth rate.     

Effects of surfactant, salt and solvent on the structure and activity of adenosine deaminase: molecular dynamic and spectrophotometric studies

Effects of sodium dodecyl sulfate, dodecyltrimethylammonium bromide, sodium chloride, sodium sulfate, methanol and ethanol, on the structure and activity of adenosine deaminase (ADA) were investigated by UV-Vis, circular dichroism spectrophotometry and molecular dynamics (MDs) studies. Relative activity, experimental and computational helix content, total accessible surface area (ASA) and exposed charged surface area (ECSA) were obtained. The relative activity of ADA in the absence and the presence of denaturants were compared with structural results. It was shown that an increase in the surface area and a decrease in the amount of helicity are associated with a decrease in the activity of ADA.     

Serum plays a critical role in modulating [Ca2+]c of primary culture bone cells exposed to weak ion-resonance magnetic fields

Primary-culture bone cells were exposed to ion-resonance (IR) magnetic fields tuned to Ca²⁺. Cytosolic calcium concentration, [Ca²⁺]_c, was measured by using fura-2 during field exposure. The fields investigated were 20 μT static + 40 μT p-p at either 15.3 or 76.6 Hz, and 0.13 mT static + either 0.5 or 1.0 mT p-p at 100 Hz. Other parameters included field orientation, culture age (2 or 5 days after plating), and the presence of serum (0 or 2%) during exposure. Total experiment time was 29.5 min: The field was applied after 2 min, and bradykinin was added as an agonist control after 22 min. The data were quantified on a single-cell basis during the 2–22 min exposure period in terms of the magnitude of the largest occurring [Ca²⁺]_c spike normalized to local baseline. Field-exposed and control groups were characterized in terms of the percent of cells exhibiting spike magnitudes above thresholds of 100 or 66% over baseline and were compared by using Fisher's exact test. Without serum, there was little evidence that IR magnetic fields altered [Ca²⁺]_c. However, in the presence of 2% serum, 3 of the 16 experiments exhibited significant effects at the 100% threshold. Reducing this threshold to 66% resulted in five experiments exhibiting significant effects. Most strikingly, in all of these cases, the field acted to enhance [Ca²⁺]_c activity as opposed to suppressing [Ca²⁺]_c activity. These findings suggest a role for serum or for constituents within serum in mediating the effects of IR magnetic fields on cells and may provide a resolution pathway to the dilemma imposed by theoretical arguments regarding the possibility of such phenomena. Possible roles of serum and future studies are discussed. Bioelectromagnetics 18:203–214, 1997. © 1997 Wiley-Liss, Inc.     

Differential effects in cells exposed to ultra-short, high intensity electric fields: cell survival, DNA damage, and cell cycle analysis

High power, nanosecond pulsed electric field (nsPEF) effects have been focused on bacterial decontamination, but the impact on mammalian cells is now being revealed. During nsPEF applications, electrical pulses of 10, 60 or 300 ns durations were applied to cells using electric field amplitudes as high as 300 kV/cm. Because of the ultra-short pulse durations, the energy transferred to cells is negligible, and only non-thermal effects are observed. We investigated the genotoxicity of nsPEF on adherent and non-adherent cell lines including 10 human lines and one mouse cell line with different origin and growth characteristics. We present data examining the effects of nsPEF exposure on cell survival assessed by clonogenic formation or live cell count; DNA damage determined by the comet assay and chromosome aberrations; and cell cycle parameters by measuring the mitotic indices of exposed cells. Using each of these indicators, we observed differential effects among cell types with non-adherent cells being more sensitive to the genotoxic effects of nsPEF exposures than adherent cells. Non-adherent cultures showed a rapid decrease in cell viability (90%), induction of DNA damage, and a decrease in the number of cells reaching mitosis after one 60 ns pulse with an electric field intensity of 60 kV/cm. These effects were not observed in cells grown as adherent cultures, with the exception of the mouse 3T3 cell line, which showed survival characteristics similar to non-adherent cultures. These data suggest that nsPEF genotoxicity may be cell type specific, and therefore have potential applications in the selective removal of one cell type from another, for example, in diseased states.     

Use of stable emulsion to improve stability, activity, and enantioselectivity of lipase immobilized in a membrane reactor

The enantiocatalytic performance of immobilized lipase in an emulsion membrane reactor using stable emulsion prepared by membrane emulsification technology was studied. The production of optical pure (S)-naproxen from racemic naproxen methyl ester was used as a model reaction system. The O/W emulsion, containing the substrate in the organic phase, was fed to the enzyme membrane reactor from shell-to-lumen. The enzyme was immobilized in the sponge layer (shell side) of capillary polyamide membrane with 50 kDa cut-off. The aqueous phase was able to permeate through the membrane while the microemulsion was retained by the thin selective layer. Therefore, the substrate was kept in the enzyme-loaded membrane while the water-soluble product was continuously removed from the reaction site. The results show that lipase maintained stable activity during the entire operation time (more than 250 h), showing an enantiomeric excess (96 +/- 2%) comparable to the free enzyme (98 +/- 1%) and much higher compared to similar lipase-loaded membrane reactors used in two-separate phase systems (90%). The results demonstrate that immobilized enzymes can achieve high stability as well as high catalytic activity and enantioselectivity.     

A novel butyrolactone derivative inhibited smooth muscle cell migration and proliferation and maintained endothelial cell functions through selectively affecting Na, K-ATPase activity and mitochondria membrane potential during in vitro angiogenesis

We have found that 3-benzyl-5-((2-nitrophenoxy) methyl)-dihydrofuran -2(3H)-one (3BDO), could effectively suppress human umbilical vascular endothelial cell (HUVEC) apoptosis induced by deprivation of fibroblast growth factor-2 and serum. Here, our purpose was to investigate whether 3BDO could modulate angiogenesis and its possible acting mechanism. The effect of 3BDO on angiogenesis was investigated by capillary-like tubule formation and rat aortic ring assay. Proliferation and migration of cells were detected by counting living cell number and scraping cell monolayer, respectively. Na, K-ATPase activity was measured spectrophotometrically. Mitochondrial membrane potential was analyzed using tetramethylrhodamine methylester fluorescence by confocal microscopy. Our results showed that 3BDO inhibited migration and proliferation of vascular smooth muscle cells (VSMCs), but maintained migration and tubule formation of HUVECs. In HUVECs, 3BDO inhibited Na, K-ATPase activity, but had no effect on mitochondria membrane potential. In VSMCs, it did not affect Na, K-ATPase activity, but depressed mitochondria membrane potential obviously. The data showed that 3BDO had selective effects on HUVECs and VSMCs, it might perform its role through the selective effects on the activity of Na, K-ATPase and the mitochondria membrane potential in HUVECs and VSMCs.     

Static magnetic fields affect cell size, shape, orientation, and membrane surface of human glioblastoma cells, as demonstrated by electron, optic, and atomic force microscopy.

BACKGROUND: It is common knowledge that static magnetic fields (SMF) do not interact with living cells; thus, fewer studies of SMF compared with variable magnetic fields are carried out. However, evidence demonstrated that SMF affect cellular structures. To investigate the effect of exposure to increasing doses of SMF on cell morphology, human glioblastoma cells were exposed to SMF ranging between 80 and 3,000 G (8 and 300 mT). METHODS: Cell morphology of human glioblastoma cells, derived from a primary culture, was studied by electron and optic microscopy. FITC-phalloidin staining of actin filaments was also investigated. Finally, cell surface structure changes were detected by atomic force microscopy. RESULTS: Scanning electron microscopy demonstrated a dose-dependent cell shape modification, progressive cell detachment, loss of the long villi, and appearance of membrane roughness and blebs. FITC-phalloidin staining confirmed the villi retention and cell dimension decrease. At 3,000 G, the appearance of apoptotic morphology was also observed by transmission electron microscopy. Cell exposed to SMF showed different orientation and alignment when compared with nonexposed cells. The atomic force microscopy of the exposed cells' membrane surfaces demonstrated the disappearance of the ordered surface ripples and furrows typical of the unexposed cells, and the occurrence of surface membrane corrugation at increasing dose exposure CONCLUSIONS: Our experimental procedures demonstrated that exposure to SMF affects not only cell size, shape, and orientation but also human glioblastoma cells' membrane surfaces.     

Cytotoxicity of daunorubicin in trisomic (+21) human fibroblasts: relation to drug uptake and cell membrane fluidity

The influence of daunorubicin (DNR) on survival of human normal (S-126) and trisomic, with respect to chromosome 21 (T-164; S-240), skin fibroblasts and some parameters related to it, such as intracellular drug accumulation, distribution and interaction with cell membrane, were studied. The in vitro growth-inhibition assay indicated that DNR was less cytotoxic for trisomic than for normal cells. Comparison of kinetic parameters and intracellular distribution of this compound showed that the uptake and the amount of intracellular free DNR were greater in normal than in trisomic cells. Contrary to this, there were no significant differences between the amount of DNA-bound drug in both types of cells. TMA-DPH and 12-AS fluorescence anisotropy measurements demonstrated that DNR decreased lipid fluidity in the inner hydrophobic region of plasma membrane in both cell types, but did not influence the fluidity of the outer surface of membrane. We conclude that fibroblasts derived from individuals affected with Down's syndrome are better protected from the damage induced by DNR than normal cells.     

Comparison of characteristics of cultured limbal cells on denuded amniotic membrane and fresh conjunctival, limbal and corneal tissues

This study aimed to evaluate proposed molecular markers related to eye limbal stem cells (SC) and to identify novel associated genes. The expression of a set of genes potentially involved in stemness was assessed in freshly prepared limbal, corneal and conjunctival tissues. PAX6, AC133, K12 and OCT4 were detected in all the tissues and p63(+)/K3(-)/K12(+)/Nodal(+)/Cx43(+) were expressed in conjunctival, p63(-)/K3(+)/K12(+)/Nodal(-)/Cx43(+) in corneal, and p63(+)/K3(-)/K12(-)/Nodal(-)/Cx43(-) in limbal tissues. Limbal explants were cultured on human amniotic membrane for 21 days. The cells expressed p63 but not K3, K12, Nodal and Cx43, however, the expression of K3, K12 and Cx43 was detected, and p63 and the high BrdU-labeling index decreased with more culture. Ultrastructure analysis of the cultured cells showed typically immature organization of intracellular organelles and architecture. Our data suggest that limbal, corneal and conjunctival tissues are heterogeneous with some progenitors. Also, the expression of traditional SC markers may not be a reliable indicator of limbal SC and there is an increasing need to determine factor(s) involved in their stemness.     

Dynamics of growth,proliferation and differentiation of wheat root cells exposed to a high nickel concentration

The dynamics of root growth, proliferation of initial cells of the root cap, rhizodermis, and central metaxylem, as well as structural changes in the cells induced by a 72-h exposure to a high (0.1 mM) concentration of NiSO₄ were studied in 3-day-old wheat (Triticum aestivum L.) seedlings. In the roots of control plants, we observed a 12-h rhythm of changes in the length of the cells that completed elongating. Upon the treatment with nickel, this effect was negated, and a considerable reduction in the root length increment was observed in 12 h. In 24 h, root growth essentially ceased. Cell elongation was suppressed acropetally, and the cells, whose elongation was over, became shorter. In the meristem and apical part of the elongation zone, slow cell growth continued during the second and even third days. Autoradiography showed that the earliest effect of nickel on the processes of root morphogenesis observed in 6 h was a suppression of cell transition to DNA synthesis. The cells, where DNA synthesis has already started or which were in other stages of the cycle, continued to pass slowly through the cycle and completed it. Sister cells formed as a result of division subsequently left the cycle in the phase G1 and transited to dormancy. It was found that the main mechanism of cell proliferation cessation was the suppression of cell transition to DNA synthesis. In the cells elongating when exposed to nickel, tissue-specific changes in the nucleus structure were observed (chromatolysis in the rhizodermis and cortex, pycnosis in the endodermis, a disturbance of the nucleus structure in the central metaxylem). These disorders were only observed after cessation of elongation. Root incubation in 0.1 mM nickel solution did not affect the onset of cell differentiation in the xylem and metaphloem and shifted its beginning to the root tip. However, in 24 h the initiation and growth of root hairs were suppressed. It was concluded that tissue-specific nickel-induced changes in the nucleus structure in the elongating cells do not cause the cessation of root growth, although point to nickel toxic effect on the cells in the course of elongation.     

Conformation and activity of chloroplast coupling factor exposed to low chemical potential of water in cells

(1) Photophosphorylation, fCa²⁺-ATPase and Mg²⁺-ATPase activities of isolated chloroplasts were inhibited 55–65% when the chemical potential of water was decreased by dehydrating leaves to water potentials (ψ_w) of ?25 bars before isolation of the plastids. The inhibition could be reversed in vivo by rehydrating the leaves.(2) These losses in activity were reflected in coupling factor (CF₁) isolated from the leaves, since CF₁ from leaves with low ?_w had less Ca²⁺-ATPase activity than control CF₁ and did not recouple phosphorylation in CF₁-deficient chloroplasts. In contrast, CF₁ from leaves having high ?_w only partially recoupled phosphorylation by CF₁-deficient chloroplasts from leaves having low ?_w. This indicated that low ?_w affected chloroplast membranes as well as CF₁ itself.(3) Coupling factor from leaves having low ψ_w had the same number of subunits, and the same electrophoretic mobility, and could be obtained with the same yields as CF₁ from control leaves. However, direct measurements of fluorescence polarization, ultraviolet absorption, and circular dichroism showed that CF₁ from leaves having low ?_w differed from control CF₁. The CF₁ from leaves having low ?_w also had decreased ability to bind fluorescent nucleotides (?-ATP and ?-ADP).(4) Exposure of isolated CF₁ to low ?_w in vitro by preincubation in sucrose-containing media inhibited the Ca²⁺-ATPase activity of the protein in subsequent assays without sucrose. Inclusion of 5 or 10 mM Mg²⁺ in the preincubation medium markedly inhibited Ca²⁺-ATPase activity.(5) These results show that CF₁ undergoes changes in cells which alter its phosphorylating ability. Since low cell ?_w changed the spectroscopic properties but not other protein properties of CF₁, the changes were most likely caused by altered conformation of the protein. This decreased the binding of nucleotides and, in turn, photophosphorylation. The inhibition of ATPase activity in CF₁ in vitro at low ?_w and high ion concentration mimicked the change in activity seen in vivo.     

Absence of genotoxicity in human blood cells exposed to 50 Hz magnetic fields as assessed by comet assay, chromosome aberration, micronucleus, and sister chromatid exchange analyses

In the past, epidemiological studies indicated a possible correlation between the exposure to ELF fields and cancer. Public concern over possible hazards associated with exposure to extremely low frequency magnetic fields (ELFMFs) stimulated an increased scientific research effort. More recent research and laboratory studies, however, have not been able to definitively confirm the correlation suggested by epidemiological studies. The aim of this study was to evaluate the effects of 50 Hz magnetic fields in human blood cells exposed in vitro, using several methodological approaches for the detection of genotoxicity. Whole blood samples obtained from five donors were exposed for 2 h to 50 Hz, 1 mT uniform magnetic field generated by a Helmholtz coil system. Comet assay, sister chromatid exchanges (SCE), chromosome aberrations (CA), and micronucleus (MN) tests were used to assess DNA damage, one hallmark of malignant cell transformation. The effects of a combined exposure with X-rays were also evaluated. Results obtained do not show any significant difference between ELFMFs exposed and unexposed samples. Moreover, no synergistic effect with ionizing radiation has been observed. A slight but significant decrease of cell proliferation was evident in ELFMFs treated samples and samples subjected to the combined exposure.     

Kinetics of IL-2 and interferon-gamma production, expression of IL-2 receptors, and cell proliferation in human mononuclear cells exposed to staphylococcal enterotoxin A

Staphylococcal Enterotoxin A (SEA) at picogram amounts induces high levels of interleukin 2 (IL-2) and interferon in human mononuclear cells. SEA is a stronger inducer of IL-2 than phytohemagglutinin, leukoagglutinin, and concanavalin A. The IL-2 induction is very rapid with maximal levels being reached after 18 to 24 hr. The IL-2 concentration decreases rapidly and almost no IL-2 activity can be detected in supernatants of cells cultured for 3 days or more. Maximal DNA synthesis is recorded 3 days after maximal IL-2 levels have been reached in the culture medium. The DNA synthesis shows a 24 hr delay as compared to the expression of the IL-2 receptor during the initiation phase. An increase in the level of IL-2 receptor expression is apparent as early as 12 hr after stimulation with SEA and maximal expression is reached 48 to 72 hr after stimulation. The percentage of cells expressing the IL-2 receptor is maximal at 96 hr after onset of culture but the surface concentration of the receptor is lower than at 72 hr. The decline in expression of the IL-2 receptor is accompanied by a decline in mean cell size and in DNA-synthesis. The concentration of the T-cell marker T11 increases in parallel with the growing expression of the IL-2 receptor. It remains increased over a longer period than the IL-2 receptor and is still significantly augmented after 10 days' exposure to SEA.     

Differential sensitivity of astrocyte primary cultures and derived spontaneous transformed cell lines to 70-hydroxycholesterol: effect on plasma membrane lipid composition and fluidity,and on cell surface protein expression

Summary The cytotoxicity of 7-hydroxycholesterol (7-OHC) was investigated on rat astrocyte primary cultures and spontaneously transformed cell lines derived from them. Confluent astrocyte primary cultures (normal cells) were unaffected by 20 µM 7(3-OHC over a period of 72 h whereas 30 µM markedly affected the viability of the transformed cells within the first 72 h. Both cell types incorporated 18% of the total amount of 7-OHC added to the cultures at concentrations of 20 µM or 30 µM. Cellular fractionation after incubation with 20 µM or 30 µM 7-OHC indicated that the plasma membrane incorporated 2 or 6 fold more 7-OHC than the intracellular one's respectively. Plasma membrane cholesterol (CH) and phospholipid (PL) analysis showed that 20 µM 7-OHC did not affect CH/PL in normal cells; in contrast, plasma membranes of transformed cells displayed a significant CH/PL decrease, which was more pronounced with 30 µM 7-OHC treatment. Fluorescence anisotropy measurements indicated that 20 µM 7-OHC slightly fluidified the plasma membrane of normal cells whereas it has not effect on that of the transformed cells one; however, an increase in plasma membrane fluidity was observed when the transformed cells were treated with 30 µM 7-OHC. Lactoperoxidase catalyzed radioiodination of cell surface proteins and subsequent autoradioelectrophoretic analysis demonstrated that the labelled protein pattern was unchanged when both cell types were incubated with 30 µM 7-OHC.