Effect of heavy metal uptake on the electrokinetic properties of Saccharomyces cerevisiae

Summary The effect of heavy metal ions (Cu²⁺, Ni²⁺) on the electrokinetic properties of S. cerevisiae was investigated by microelectrophoresis. The uptake of metal ions is associated with a change in surface charge on the cell surface. Increasing pH results in the cell surface being more negatively charged. Also, the change in the electrophoretic mobility in the presence of multi-ions is not simply due to the change in the metal concentration of the solutions, but is also dependent on the metal species involved.     

Loss of net negative surface charge during MLC stimulation of human T lymphocytes: correlation to "stable" E-rosette formation and natural attachment to normal and malignant target cells.

Activation of human blood T lymphocytes in mixed lymphocyte culture (MLC) causes a reduction in the net negative surface charge, as indicated by the reduction in the electrophoretic mobility. Concomitantly, the activated cells acquire new properties, including the ability to form “stable” E rosettes, and attach to normal and malignant cells of the same species (natural attachment (NA)). These properties were found to be expressed by lymphocytes within the low electrophoretic fractions (cells with low negative charge) of the MLC populations. The formation of stable E rosettes and natural attachment capacities of human thymocytes were also found to correlate with the amount of surface negative charge. The slowly migrating (less negative charged) cortical thymocytes, reported earlier as being able to form stable E rosettes, were found also to exhibit NA activity. Medullary thymocytes carrying a high net negative surface charge lack these characteristics. We consider it likely that the reduction of negative charge during activation of peripheral T cells, facilitates cell-to-cell contacts, and thus prepares the (activated) cells to perform cooperative interactions with other cell types, and express the lytic activity of T cells.     

Surface charge of mammalian neurones as revealed by microelectrophoresis

Summary The surface charge of isolated rat dorsal root ganglion neurones was studied by microelectrophoresis technique. The increase of Ca concentration caused greater reduction of the electrophoretic mobility compared to that produced by an equivalent amount of divalent organic cations, dimethonium or hexamethonium. No charge reversal for Ca concentrations up to 80 mM was observed. These data fit the suggestion that two anion groups of the outer membrane surface can bind one Ca ion with apparent binding constant of about 50 M^–1. In solutions of low pH the electrophoretic mobility of cells decreased corresponding to titration of acidic groups with apparent pK=4.2. Trypsin treatment in mild conditions markedly reduced the surface charge: however, neuraminidase and hyaluronidase did not change it. N-bromosuccinimide (a specific reagent for carboxylic groups of proteins) decreased the electrophoretic mobility about 60%. However, no increase of the surface charge after the action of specific reagents for amino groups (2,4,6-trinitrobenzenesulfonic acid and maleic anhydride) was observed. It was shown that the surface charge depends also on the intracellular metabolism. If 1 mM dibutyryl cAMP or theophilline was added to the culture medium (thus, raising the concentration of cAMP inside the cell) the surface charge increased. This effect developed slowly and reached its maximum on the third day of incubation. Treatment of cells by 5 mM tolbutamide (an inhibitor of some protein kinases) did not change cell mobility. Addition of 5 mM N-ethylmaleimide (an inhibitor of adenylate cyclase) to the culture medium produced some decrease of the surface charge. On the basis of data obtained it is suggested that the charge of the outer membrane surface of neurones studied is mainly determined by carboxylic groups of membrane proteins, and changes in intracellular cAMP concentration influence the synthesis and reconstruction of these membrane components.     

A cell surface alteration in mouse L cells induced by interferon

Mouse L cells grown in suspension culture when treated with L cell interferon have a greater electrophoretic mobility toward the anode than control cells. This change in electrophoretic mobility depends on the concentration of interferon in the medium and the duration of interferon interaction with the cells. It is concluded that the interferon-treated cells have a greater net negative charge on the cell surface than control cells and it is suggested that the cell surface is altered because of the interaction with interferon.     

Change in electrophoretic mobility of human erythrocyte as the result of membrane shape change in vitro.

Shape change of human erythrocyte due to the membrane externalization induced by incorporation of excess lysolecithin or by hypertonic treatment in vitro, was accompanied by a decrease in the electrophoretic mobility of the cell. No change in sialic acid content of the membrane, mostly responsible for the cell surface charge, was observed in any of these treatments. Therefore, the membrane externalization seems to cause a redistribution of the surface charge and the resulting alteration of the electrophoretic mobility of the cell. Heating at 48 degrees C for 1 hour induced both the shape change and change in the mobility, but at the same time it reduced the membrane sialic acid content.     

THE ELECTROPHORETIC MOBILITY OF HUMAN ERYTHROCYTES—WHOLE CELLS,GHOSTS, AND FRAGMENTS

The electrophoretic mobility of human red cell ghosts decreases in the presence of chicken serum. The decrease is not directly due to the presence of adsorbed material but to a change which is catalyzed by the foreign substance. It is suggested that abnormal serum materials resulting from disease may serve as catalysts. Fragments of broken cells have the same mobility as whole cells at first, then decrease even in pure salt suspension, while the whole cells remain essentially unchanged for hours. The results suggest that the slow change of whole cells, the change of ghosts in the presence of foreign serum, and the change of fragments are all manifestations of the same modification of structure or composition of the cell surface.     

Label-free determination of the number of biomolecules attached to cells by measurement of the cell's electrophoretic mobility in a microchannel

We developed a label-free method for a determination of the number of biomolecules attached to individual cells by measuring the electrophoretic mobility of the cells in a microchannel. The surface of a biological cell, which is dispersed in aqueous solution, is normally electrically charged and the charge quantity at the cell's surface is slightly changed once antibody molecules are attached to the cell, based on which we detect the attachment of antibody molecules to the surface of individual red blood cells by electrophoretic mobility measurement. We also analyzed the number of antibody molecules attached to the cell's surface using a flow cytometer. We found that there is a clear correlation between the number of antibody molecules attached to the individual cells and the electrophoretic mobility of the cells. The present technique may well be utilized not only in the field of cell biology but also in the medical and pharmaceutical industries.     

The effects of calcium2+ and magnesium2+ on the electrophoretic mobility of chromaffin granules measured by electrophoretic light scattering

Electrophoretic light scattering was used to determine the electrophoretic mobility distributions of isolated bovine adrenal chromaffin granules as a function of divalent metal ion concentrations. Changes in the electrophoretic mobility reflected changes in the surface charge density of the granules. Ca2+ and Mg2+ (0.10--2.0 mM) were equally effective in reducing the electrophoretic mobilities. These findings are consistent with recent studies of the binding of Ca2+ and Mg2+ to the surface of chromaffin granules and are further evidence that the specific role of Ca2+ in exocytosis is due to effects other than the ability of Ca2+ to decrease the electrostatic repulsion between negatively charged membranes.     

Changes in the cell surface of human diploid fibroblasts during cellular aging.

The electrophoretic mobility of 13 human diploid cell strains, TIG-1, TIG-2, TIG-3, TIG-7, WI-38, IMR-90, MRC-5, MRC-9, TIG-1H, TIG-1L, TIG-2M, TIG-2B, and TIG-3S, which were established from different tissues of human embryos, was studied at different passages. The net negative surface charge of the cells was characteristic for each cell strain and decreased significantly during the in vitro aging of the cells. The decrease in the net negative charge of the cells correlated well with the decrease in cell density throughout the life span of the cells. A strict linear correlation between the electrophoretic mobility and the number of cells harvested at each passage was obtained for all the human diploid cell strains. Moreover, almost the same linear regression coefficient of the cells was obtained among these cell strains. Therefore, the net negative surface charge of human diploid cell strains could serve as a cell surface marker for in vitro cellular aging.     

Electrophoretic mobility of UV-irradiated bacterial cells

Electrophoretic mobility of Escherichia coli cells exposed to various doses of UV-radiation was investigated. The method of free flow electrophoresis was used to study a correlation between membrane protein charge and cell surface electric charge. The change in the cell surface charge and electrophoretic motility was associated with the damage to membrane proteins and the survival of UV-irradiated bacteria.     

Early electrochemical events in lectin-lymphocyte interaction. I. Mechanism of lectin-mediated changes in the electrophoretic mobility of lymphocytes

Concanavalin A, at extremely low concentrations, will produce significant increases in the electrophoretic mobility of murine splenic T lymphocytes. It has been established that the alteration in cellular surface charge is mediated by a factor produced by those lymphocytes that have reacted directly with con A. We originally conjectured that the mobility change might be the consequence of an alteration in the distribution of the charged moieties of membrane glycoproteins. The results of experiments conducted at low temperature raise some questions about this mechanism. Further experiments have been performed to establish the nature of the physicochemical alterations in the peripheral zone of the factor-stimulated lymphocytes that are manifest as changes in cellular surface charge. The results of these studies indicate that, subsequent to the interaction of T lymphocytes with con A, there is a reduction in the number of positively charged amino groups effective at the electrophoretic surface of the cells.     

Size-dependent mobile surface charge model of cell electrophoresis

A model that accurately predicts the effects of cellular size and electric field strength on electrophoretic mobility has been developed. Previous models have predicted that electrophoretic mobility (EPM) is dependent only on cell surface charge, bath viscosity and ionic strength of the electrolyte. However, careful analysis of experimental data from the literature shows that these models do not accurately depict the relationship between chemically determined surface charge and observed mobility. We propose a new model that accounts for electrically driven redistribution of mobile surface charge islands, such as the recently proposed lipid raft structures. This model predicts electrophoretic mobility as a function of a new dimensionless quantity, A, that incorporates the cell radius, the electric field strength, and the average diameter of charged membrane complexes.     

Changes in electronegativity of the cell surface during the development of the cell surface during the development of the cellular slime mold, Dictyostelium discoideum

A microelectrophoretic method was applied to determine electrophoretic mobility of the amoebae of the cellular slime molds at various stages of development. The vegetative amoebae were negatively charged and their electrophoretic mobility remained unchanged as long as they fed. After the cessation of feeding mobility of the amoebae decreased gradually in the interphase. Proteolytic enzymes and EDTA had no effect on mobility of the amoebae right after finishing feeding. On the contrary, mobility of the amoebae in the middle interphase was increased by treatment with proteolytic enzymes, lipase, and EDTA. EDTA and pronase showed an additive effect on the increase in mobility, and the increased mobility was almost the same as that of the vegetative a-moebae. These results indicate that the decrease in mobility during the interphase is due to the accumulation of a substance(s) (probably lipoprotein) on the cell surface. The cells disaggregated from the migrating slugs showed lower mobility than the cells obtained from the aggregation centers. The latter had still lower mobility than the interphase amoebae. These changes in electrophoretic mobility were discussed in relation to corresponding changes in adhesiveness.     

The Surface Charge of Isolated Toad Bladder Epithelial Cells : Mobility, effect of pH and divalent ions

The surface charge of epithelial cells isolated from the toad bladder has been determined by the microscope method of cell electrophoresis. The cells possess a net negative charge, and a net surface charge density of 3.6 x 10⁴ electronic charges per square micron at pH 7.3. Estimates of net surface charge over the alkaline pH range indicate (a) that an average distance of the order of 40 A separates the negatively charged groups, and (b) that amino as well as acid groups are present at the electrophoretic surface of shear. A significant increase in mobility following cyanate treatment of the cells suggests that a large proportion of the amino groups are the ε-amino groups of lysine. In view of the known effects of calcium and other divalent ions on cell permeability and cell adhesion, the extent of binding of calcium and magnesium to the cell surface was determined by the electrophoretic technique. Mobility was significantly decreased in the presence of calcium or magnesium, indicating that these ions are bound by surface groups. When the pH was lowered from 7.3 to 5.2, calcium binding was markedly decreased, an observation consistent with competition between calcium and hydrogen ions for a common receptor site.     

Leishmania mexicana amazonensis: Surface charge of amastigote and promastigote forms

The surface charge of Leishmania mexicana amazonensis was evaluated by means of the binding of colloidal iron hydroxyde particles at pH 1.8 and cationized ferritin particles at pH 7.2 to the cell surface, visualizated by electron microscopy and by direct measurements of the electrophoretic mobility of cells suspended in solutions of different pH. The following forms of the parasite were analysed: amastigotes (surrounded or not by the membrane of the endocytic vacuole, isolated from lesions), transitional forms, and infective (5 passages) and noninfective (176 passages) promastigotes. The results obtained indicate that the surface of L. m. amazonensis contains both negatively and positively charged dissociating groups and that changes occur in the surface charge during amastigote-promastigote transformation. Treatment of the parasite with neuraminidase significantly reduced the electrophoretic mobility of the cells. Neuraminidase-treated cells recovered their normal electrophoretic mobility when incubated for 8 hr in fresh culture medium by a process that is inhibited by puromycin.     

Early electrochemical events in lectin-lymphocyte interaction

Concanavalin A, at extremely low concentrations, will produce significant increases in the electrophoretic mobility of murine splenic T lymphocytes. It has been established that the alteration in cellular surface charge is mediated by a factor produced by those lymphocytes that have reacted directly with con A. We originally conjectured that the mobility change might be the consequence of an alteration in the distribution of the charged moieties of membrane glycoproteins. The results of experiments conducted at low temperature raise some questions about this mechanism. Further experiments have been performed to establish the nature of the physicochemical alterations in the peripheral zone of the factor-stimulated lymphocytes that are manifest as changes in cellular surface charge. The results of these studies indicate that, subsequent to the interaction of T lymphocytes with con A, there is a reduction in the number of positively charged amino groups effective at the electrophoretic surface of the cells.     

The cell surface of Phytomonas davidi

Carbohydrates were located on the surface of Phytomonas davidi using ultrastructural cytochemistry, and agglutination induced by lectins which bind to residues of mannose, N-acetylglucosamine, galactose, N-acetylgalactosamine, fucose and sialic acid. The surface charge of the cells was analysed by the binding of cationic particles (colloidal iron and cationized ferritin) to the cell surface and by cell electrophoretic mobility (EPM). Based on observations of binding of cationic particles to the cell surface; a decrease in the binding of these particles to the cell surface; a decrease in the mean EPM of the cells after their incubation in the presence of neuraminidase; and detection of N-acetylneuraminic acid by paper and gas-liquid chromatography, it was concluded that sialic acid residues are exposed on the surface of P. davidi. These residues may be glycolipids or are masked on the cell surface since only after brief trypsinization were the cells agglutinated by the lectin from Limulus polyphemus.     

Alterations of polymorphonuclear leukocyte surface charge by stimulated lymphocyte supernatants

The effects of human lymphokines on the surface charge density of human polymorphonuclear (PMN) leukocytes have been determined using the laser Doppler technique of electrophoretic light scattering. Unfractionated antigen (streptokinase-streptodornase or candida)-stimulated lymphocyte supernatants were found to decrease the mode electrophoretic mobility by 14%. In order to identify the responsible factor, we subjected supernatants from concanavalin A-stimulated lymphocytes to gel filtration on Sephadex G-100 columns and assayed the fractions for their ability to alter PMN electrophoretic mobilities. Two distinct species in the molecular weight ranges of 30–60K and 10–20K, respectively, were found to decrease the electrophoretic mobilities of PMN leukocytes. We have observed no effect of leukocyte inhibitory factor (LIF) on the electrophoretic mobility distribution of PMN leukocytes over a varying period of time (0–8 hr) and over a range of 2- to 10-fold supernatant concentration. Pretreatment of PMN leukocytes with neuraminidase substantially reduced their electrophoretic mobility; the addition of LIF to these pretreated cells did not alter their electrophoretic mobility distribution further. The latter finding is particularly significant in view of the fact that neuraminidase pretreatment of the target cells is known to potentiate LIF activity. We conclude that the mechanism of the inhibition of leukocyte migration by LIF does not involve an alteration of the leukocyte surface charge density.     

Analysis of electrophoretic mobility histograms of mouse splenocytes and thymocytes during tumor growth and after combined chemotherapy and immunotherapy

Changes in electrophoretic mobility histograms of splenocytes and thymocytes were studied in plasmacytoma X5563-bearing mice as an indicator of response to treatment with mitomycin C (MMC) alone or combined with the immunomodulator Krestin (PSK). Tumor growth was inhibited by 80-90% in the MMC-treated and was further inhibited in the MMC and PSK-treated group. Electrophoretic mobility histograms of splenocytes were used to determine the fraction of cells having intermediate mobility between high mobility (T cells) and low mobility (B cells). This fraction of intermediate-mobility cells increased in tumor-bearing mice, but a normal electrophoretic mobility pattern was obtained following successful antitumor treatment. In the electrophoretic mobility histogram of thymocytes, on the other hand, the low-mobility cells (cortical thymocytes) decreased in number during tumor growth and were further reduced in the MMC-treated group. This reduction was less in the MMC and PSK-treated group. These results suggest that combined therapy with MMC and PSK prevents damage of the host defence mechanism and allows more efficient antitumor treatment. Analysis of electrophoretic mobility histograms of splenocytes and thymocytes using a fully automated cell electrophoretic instrument makes possible the rapid evaluation of the immunological effects of drug therapy of tumor-bearing mice.     

Solubilization of Minerals by Bacteria: Electrophoretic Mobility of Thiobacillus ferrooxidans in the Presence of Iron, Pyrite, and Sulfur

Thiobacillus ferroxidans is an obligate acidophile that respires aerobically on pyrite, elemental sulfur, or soluble ferrous ions. The electrophoretic mobility of the bacterium was determined by laser Doppler velocimetry under physiological conditions. When grown on pyrite or ferrous ions, washed cells were negatively charged at pH 2.0. The density of the negative charge depended on whether the conjugate base was sulfate, perchlorate, chloride, or nitrate. The addition of ferric ions shifted the net charge on the surface asymptotically to a positive value. When grown on elemental sulfur, washed cells were close to their isoelectric point at pH 2.0. Both pyrite and colloidal sulfur were negatively charged under the same conditions. The electrical double layer around the bacterial cells under physiological conditions exerted minimal electrostatic repulsion in possible interactions between the cell and either of its charged insoluble substrates. When Thiobacillus ferrooxidans was mixed with either pyrite or colloidal sulfur at pH 2.0, the mobility spectra of the free components disappeared with time to be replaced with a new colloidal particle whose electrophoretic properties were intermediate between those of the starting components. This new particle had the charge and size properties anticipated for a complex between the bacterium and its insoluble substrates. The utility of such measurements for the study of the interactions of chemolithotrophic bacteria with their insoluble substrates is discussed.