Electric field-induced cell-to-cell fusion

Fusion of renal epithelial cells: a model for studying cellular mechanisms of ion transport

The investigation of epithelial ion transport at the cellular level by means of electrophysiological techniques is hampered by the small size of epithelial cells. Moreover, interpretation of experiments is complex due to poorly defined and highly variable paracellular leaks (shunt pathways). In search of a new experimental approach we developed a technique to isolate renal epithelial cells (diameter approximately equal to 10 micron) from diluting segments of the frog kidney and to fuse them to "giant" cells (diameter approximately equal to 100 micron). These cells generate membrane potentials of -54.1 +/- 1.6 mV (mean +/- SEM; n = 40). They are sensitive to the diuretic drugs furosemide and amiloride and to the K+- and Cl- -permeability blockers Ba2+ and anthracene-9-carboxylic acid. The experiments demonstrate membrane potential measurements in cells isolated from renal epithelium and fused to giant cells. The cells retain their specific membrane properties and could serve as a valuable experimental model in epithelial research.

An osmotic model for the fusion of biological membranes

A molecular model for fusion-fission reactions in membranes is proposed that is based on data from studies on artificially induced cell fusion and on the behaviour of phospholipid bilayers: it is put forward as a framework for further investigations into this fundamental property of biological systems.

Nuclear transplantation in sheep embryos

Nuclear transplantation and cell fusion techniques have proved valuable for embryological studies in several non-mammalian animal species. More recently these procedures have been used successfully in small laboratory mammals, notably the mouse, to investigate the ability of nuclei and cytoplasm from various sources to produce viable embryos when combined. The use of a similar approach to study the developmental biology of large domestic animals presents a number of technical and practical difficulties, and so far there has been no report of attempts to perform nuclear transplantation in sheep embryos. Here I describe such a procedure and its use to investigate the development of embryos in which whole blastomeres from 8- and 16-cell embryos were combined with enucleated or nucleated halves of unfertilized eggs. The procedure involves bisection of single-cell eggs in a medium containing cytochalasin; fusion of egg halves with single blastomeres, induced using Sendai virus or an electrofusion apparatus; and embedding in agar, followed by culture of the reconstituted embryos in the ligated oviducts of ewes in dioestrus. I show that fully viable embryos may be obtained by this procedure.

Stable transformation of maize after gene transfer by electroporation

The graminaceous monocots, including the economically important cereals, seem to be refractory to infection by Agrobacterium tumefaciens, a natural gene transfer system that has been successfully exploited for transferring foreign genes into higher plants. Therefore, direct transfer techniques that are potentially applicable to all plant species have been developed using a few dicot and monocot species as model systems. One of these techniques, electroporation, uses electrical pulses of high field strength to permeabilize cell membranes reversibly so as to facilitate the transfer of DNA into cells. Electroporation-mediated gene transfer has resulted in stably transformed animal cells and transient gene expression in monocot and dicot plant cells. Here we report that electroporation-mediated DNA transfer of a chimaeric gene encoding neomycin phosphotransferase results in stably transformed maize cells that are resistant to kanamycin.

Electroporation-mediated infection of tobacco leaf protoplasts with tobacco mosaic virus RNA and cucumber mosaic virus RNA

Conditions were established for the introduction of both tobacco mosaic virus (TMV) and cucumber mosaic virus (CMV) RNAs into tobacco mesophyll protoplasts by electroporation. The proportion of infected protoplasts was quantified by staining with viral coat protein-specific antibodies conjugated to fluorescein isothiocyanate. Approximately 30-40% of the protoplasts survived electroporation. Under optimal conditions, up to 75% of these were infected with TMV-RNA. Successful infection was demonstrated in 19 out of 20 experiments. Optimal infection was achieved with several direct current pulses of 90 μsec at a field strength of 5 to 10 kV/cm. Changing the position of the protoplasts within the chamber between electric pulses was essential for achievement of high rates of infection. Optimal viral RNA concentration was about 10 μg/ml in a solution of 0.5 M mannitol without buffer salts.

Kinetics of ultrastructural changes during electrically induced fusion of human erythrocytes

The sequence of events during the electrically induced fusion of human erythrocytes was studied by rapid quench freeze-fracture electron microscopy. A single electric field pulse was used to induce fusion of human erythrocytes treated with pronase and closely positioned by dielectrophoresis. The electronic circuit was coupled to a rapid freezing mechanism so that ultrastructural changes of the membrane could be preserved at given time points. Pronase treatment enabled adjacent cells to approach each other within 15 nm during dielectrophoresis. The pulse caused a brief disruption of the aqueous boundaries which separated the cells. Within 100 msec following pulse application, the fracture faces exhibited discontinuous areas which were predominantly free of intramembranous particles. At 2 sec after the pulse, transient point defects attributed to intercellular contact appeared in the same membrane areas and replaced the discontinuous areas as the predominant membrane perturbation. At 10 sec after the pulse, the majority of the discontinuous areas and point defects disappeared as the intercellular distance returned to approximately 15 to 25 nm, except at sites of cytoplasmic bridge formation. Intramembranous particle clearing was observed at 60 sec following pulse application in discrete zones of membrane fusion.

Electric field-mediated DNA transfer: transient and stable gene expression in human and mouse lymphoid cells

The technique of DNA transfer by electroporation was investigated in an effort to evaluate its utility for the identification of developmentally controlled regulatory sequences. Transient and stable gene expression was detected in a variety of lymphoid cell lines subjected to electroporation. No correlation existed between the levels of chloramphenicol acetyltransferase (acetyl-CoA; chloramphenicol 3-O-acetyltransferase, EC 2.3.1.28) expression and stable transfection frequency. In all lymphoid cell lines tested, the simian virus 40 early region was a better promoter than was the Rous sarcoma virus long terminal repeat.

Electro-acoustic fusion of erythrocytes and of myeloma cells

Mammalian cells can be concentrated in a sound field. A method is introduced, which combines the reversible aggregation of cells in a sound field with the electrical breakdown of cell membranes to fuse cells, which are in contact. Human red blood cells and mouse myeloma cells are fused by means of that procedure.

Determination of intracellular conductivity from electrical breakdown measurements

The intracellular resistivity (conductivity) of cells can be easily calculated with high accuracy from electrical membrane breakdown measurements. The method is based on the determination of the size distribution of a cell suspension as a function of the electrical field strength in the orifice of a particle volume analyser (Coulter counter). The underestimation of the size distribution observed beyond the critical external field strength leading to membrane breakdown represents a direct access to the intracellular resistivity as shown by the theoretical analysis of the data. The potential and the accuracy of the method is demonstrated for red blood cells and for ghost cells prepared by electrical haemolysis. The average value of 180 omega X cm for the intracellular resistivity of intact red blood cells is consistent with the literature.

Electric pulse-induced fusion of mouse lymphoma cells: roles of divalent cations and membrane lipid domains

Mouse leukemic lymphoblasts (L5178Y) brought into close contact by dielectrophoresis underwent cell fusion following the application of electrical pulses in the presence of electrolytes. The electrically fused cells became spherical after switching off the dielectrophoretic field. Fusion between a cell vitally stained with Janus Green and that with Neutral Red resulted in the homokaryon with a mixed color. Intracellular potentials simultaneously recorded from the two cells located on both sides of the homokaryon were identical. The fusion efficiency was remarkably dependent upon temperature, displaying a discontinuity at about 11 degrees C in the Arrhenius plot. The extracellular application of phospholipase-A2 or -C suppressed the fusion yield. Thus, it appears that the phospholipid domains play a crucial role in the electric pulse-induced cell fusion. Treatment of the cells with proteolytic enzymes markedly enhanced the fusion yield, presumably due to removing the glycocalix and/or giving rise to fusion-potent, protein-free lipid domains. The presence of millimolar concentrations of divalent cations (irrespective of Mg2+ or Ca2+) as well as of micromolar concentrations of Ca2+ (but not Mg2+) was prerequisite to the resealing of membranes suffered from electrical breakdown upon exposure to electric pulses. In addition, extracellular Ca2+ (but not Mg2+) ions at more than micromolar concentrations were indispensable for the cell fusion.

Biochemical studies on cell fusion. I. Lipid composition of fusion-resistant cells

A series of stable cell mutants of mouse fibroblasts were previously isolated (Roos, D. S. and R. L. Davidson, 1980, Somatic Cell Genet., 6:381-390) that exhibit varying degrees of resistance to the fusion-inducing effect of polyethylene glycol (PEG), but are morphologically similar to the parental cells from which they were derived. Biochemical analysis of these mutant cell lines has revealed differences in whole cell lipid composition which are directly correlated with their susceptibility to fusion. Fusion-resistant cells contain elevated levels of neutral lipids, particularly triglycerides and an unusual ether-linked lipid, O-alkyl, diacylglycerol. This ether lipid is increased approximately 35-fold over parental cells in the most highly PEG-resistant cell line. Fusion-resistant cells also contain more highly saturated fatty acyl chains (ratio of saturated to polyunsaturated fatty acids [S/P ratio] approximately 4:1) than the parental line (S/P ratio approximately 1:1). Cells which are intermediate in their resistance to PEG have ether lipid and fatty acid composition which is intermediate between the parental cells and the most fusion-resistant mutants. In a related communication (Roos, D. S. and P. W. Choppin, 1985, J. Cell. Biol., 100:1591-1598) evidence is presented that alteration of lipid content can predictably control the fusion response of these cells.

Ionic modulation of electrically induced fusion of mammalian cells

During the last few years, a new technique has been developed for the "electrofusion" of mammalian cells. No previous treatment of the culture is needed, for the contact between cells is spontaneous. Short DC electric pulses are applied directly to a culture growing in monolayers on a culture dish. When the cell density is high enough, contacts occur between cells giving the so-called contact inhibition. In the present study, a systematic investigation of the modulation of the extent of the fusion by the ionic content of the bathing medium during the pulsation is described. An increase in the content in monovalent ions decreases the fusion yield. But this decrease is modulated by the nature of the ion; Li+, a potent "water structure maker," is less effective than Na+ or K+. Ca2+, when present in the millimolar range, leads to the lysis of the cells. Mg2+, when present at concentrations smaller than 4 mM, promotes the fusion but prevents it at larger concentrations. Microelectrophoresis measurements show that the electric surface charge is not strongly affected by these changes in ionic content. Our observations are relevant of a modulation of the cell-cell interactions by the ionic content of the bathing medium.

Fusion of bacterial spheroplasts by electric fields

Spheroplasts of Escherichia coli or Salmonella typhimurium were found to fuse in an electric field. We employed the fusion method developed by Zimmermann and Scheurich (1981): Close membrane contact between cells is established by dielectrophoresis (formation of chains of cells by an a.c. field), then membrane fusion is induced by the application of short pulses of direct current. Under optimum conditions the fusion yield was routinely 90%. Fusable spheroplasts were obtained by first growing filamentous bacteria in the presence of cephalexin, then converting these to spheroplasts by the use of lysozyme. The fusion products were viable and regenerated to the regular bacterial form. Fusion of genetically different spheroplasts resulted in strains of bacteria possessing a combination of genetic markers. Fusion could not be achieved with spheroplasts obtained by growing the cells in the presence of penicillin or by using lysozyme on bacteria of usual size.

Expression of genes transferred into monocot and dicot plant cells by electroporation

We have developed a general method for electrically introducing DNA into plant cells. Gene transfer occurs when a high-voltage electric pulse is applied to a solution containing protoplasts and DNA. Carrot protoplasts were used as a model system to optimize gene-transfer efficiency, which was measured 24-48 hr after electroporation by the amount of chloramphenicol acetyltransferase activity resulting from the expression of the introduced chimeric plasmids. Gene-transfer efficiency increased with the DNA concentration and was affected by the amplitude and duration of the electric pulse as well as by the composition of the electroporation medium. Our optimized gene-transfer conditions were effective when applied to tobacco and maize protoplasts, demonstrating that the method is applicable to both monocot and dicot protoplasts.

Electrical fusion for optimal formation of protoplast heterokaryons in Nicotiana

The electrical fusion of protoplasts has been studied in order to maximize the formation of heterokaryons for culture. Heterokaryons of Nicotiana tabacum L. mesophyll protoplasts and N. plumbaginifolia Viviani supension-cell protoplasts were identified in fixed and stained as well as living material; a quantitative fusion index was thereby developed. With this index the efficiencies of various electric fields and fusion-chamber designs have been determined. Optimal fusion was obtained with an alternating-current (AC) field of 150 V/cm and direct-current (DC) square-wave pulses of 1000 V/cm. A new, simple-to-use, largescale fusion chamber is described in which batches of up to 5·10(5) protoplasts (0.5 ml of cells at 10(6)/ml) can be fused in 5-7 min with efficiencies approaching 40%. Half of the fusion products are heterokaryons, thus fusion is random. Of the fusion products, 60% are bi- or trinucleate. Using fusion procedures similar to those described here Bates and C. Hasenkampf (1985, Theor. Appl. Genet., in press) have recovered viable somatic hybrids which have been regenerated.

Culture of plant somatic hybrids following electrical fusion

Electrically-induced protoplast fusion has been used to produce somatic hybrids between Nicotiana plumbaginifolia and Nicotiana tabacum. Following fusion of suspension culture protoplasts (N. plumbaginifolia) with mesophyll protoplasts (N. tabacum) heterokaryons were identified visually and their development was followed in culture. Because electrical fusion is a microtechnique, procedures were developed for culturing the heterokaryons in small numbers and at low density. The fusion and culture procedures described are rapid, uncomplicated and repeatable. Good cell viabilities indicate that the fusion procedure is not cytotoxic. Fused material was cultured 1-2 days at high density in modified K3 medium (Nagy and Maliga 1976). The heterokaryons were isolated manually and grown, at low density in conditioned media. Calli have been regenerated. Esterase isozyme patterns confirm the hybrid character of calli and clonally-derived plantlets recovered from these fusions.

Movement of a fluorescent lipid label from a labeled erythrocyte membrane to an unlabeled erythrocyte membrane following electric-field-induced fusion

A short burst of electric field pulses was used to induce nearly simultaneous fusion among 50% or more of a population composed of unlabeled erythrocytes and erythrocytes labeled with the fluorescent lipid analogue DiI (1,1'-dihexadecyl-3,3,3'',3'-tetra-methylindo carbocyanine perchlorate). Fusion products that ended in an hourglass shape were selected for analysis. The net movement of the label from the labeled membrane to the adjacent unlabeled membrane in each of the hourglass-shaped fusion products was recorded by micrography at various known times after the fusion took place, but before equilibrium was achieved. The lateral concentration gradients were measured by densitometry and compared with predictions based on Huang's model (Huang, H.-W., 1973, J. Theor. Biol., 40:11-17) for lateral diffusion on a spherical membrane. The average lateral diffusion coefficients, 3.8 and 8.1 X 10(-9) cm2/s in pH 7.4 isotonic phosphate buffer at 23-25 degrees C and 35-37 degrees C, respectively, compare very favorably with the results of three published photobleaching studies of the lateral diffusion of DiI in erythrocyte membranes. While the fusion approach to measuring lateral diffusion is not new, it has not enjoyed widespread use because of the uncertainty in the degree of fusion synchrony and low fusion yield. This study shows that the use of pulsed electric fields to induce synchronous fusion is a promising approach to overcome both of these drawbacks and yield results comparable to those obtainable by the photobleaching approach.

An improved electrofusion technique for production of mouse hybridoma cells

An experimental procedure is described for the reproducible production of hybridoma cells using the electrofusion technique. High yields can be obtained when fusion is performed in isotonic inositol solutions containing Ca2+ and Mg2+ in a ratio of 1:5 in the millimolar range. The hybridoma cells are transferred 10 min after the field pulse application into a balanced salt solution for 30 min at 37 degrees C.

Membrane stability

Rupture and buckling of artificial and biological membranes is an important part of many biological processes. In this review, we present some of the main experimental facts and their analysis. Recent theoretical work, in particular thin film models and nucleation mechanisms of membrane instability, are discussed in detail. Possible applications to membrane adhesion and fusion are pointed out. Attempts are made to explain biological phenomena and experimental results for biological membranes based on a rigorous physicochemical approach developed previously for thin films in colloid systems.

Production of steroid hormone and cyclic AMP in hybrids of adrenal and Leydig cells generated by electrofusion

Electrofusion of rat adrenal and Leydig cells generated hybrids capable of synthesizing simultaneously both testosterone and corticosterone, under stimulation of lutropin or adrenocorticotropin. Evidence was obtained indicating that under such circumstances, heterologous lutropin receptor--adrenal adenylate cyclase complexes were formed.

Characterization of electric field-induced fusion in erythrocyte ghost membranes

Fusion has been reported to occur in a variety of membrane systems in response to the application of certain electric currents to the medium (Zimmermann, U., 1982, Biochim. Biophys. Acta., 694:227-277). The application of a weak but continuous alternating current causes the membranes in suspension to become rearranged into the "pearl-chain" formation. Fusion can then be induced by one or more strong direct current pulses that cause pore formation. This results in the conversion of individual membranes in the "pearl-chain" formation to a single membrane with one or more hourglass constrictions that form lumens which connect the cytoplasmic compartments. As the diameter of the lumens increases, the overall membrane shape grows to one large sphere. To further characterize electric field-induced fusion, experiments were conducted using the erythrocyte ghost as a model membrane, and a new combination of electrical circuit and fusion chamber that is simpler and improved over previous systems. All odd-shaped ghosts (collapsed or partly collapsed spherical shapes, echinocytes, discocytes, and stomatocytes) in 30 mM phosphate buffer was first converted to spherocytes and then fused with increasing yields by increasing the number of pulses. After fusion, the lateral diffusion of a fluorescent lipid soluble label (Dil) from labeled to unlabeled membranes was observed to occur both with and without the appearance in phase-contrast optics of distinct communication (lumens) between cytoplasmic compartments of the fused membranes. Connections between cytoplasmic compartments, however, were unmistakable with the instant transfer of a fluorescent water-soluble label (fluorescein isothiocyanate-dextran) from labeled to unlabeled cytoplasmic compartments upon fusion. Although pulses still resulted in the lateral diffusion of Dil to unlabeled membranes, the presence of glycerol in the medium strongly reduced the yield of lumens observable by phase-contrast optics in fusion events. The presence of glycerol also inhibited the conversion of membranes to spherocytes, but did not inhibit the lateral diffusion of Dil from labeled to unlabeled membranes.

Enhancer-dependent expression of human kappa immunoglobulin genes introduced into mouse pre-B lymphocytes by electroporation

We have developed a general method for introducing cloned genes into mammalian cells that affords substantial benefits over current technology. It is simple, rapid, and applicable to many (perhaps all) cell types, including those that are refractory to traditional transfection procedures. The method involves exposure of a suspension of cells and cloned DNA to a high-voltage electric discharge. In a model application of this transfection procedure, we have studied the expression of cloned human and mouse Ig kappa genes stably introduced into mouse pre-B cells and fibroblasts. We find that there is a B-cell-specific enhancer-activator region in the J-C intron of the human kappa gene that is necessary for efficient transcription of the cloned gene in mouse pre-B lymphocytes. This suggests that both the DNA element and the proteins required for its regulatory activity have been highly conserved in evolution and that these elements operate at the pre-B-cell stage of immunocyte development, a stage that precedes productive kappa gene rearrangement.

Direct experimental evidence of the vectorial character of the interaction between electric pulses and cells in cell electrofusion

Fusion is induced between cultured mammalian cells growing on culture flasks by electric pulses. The yield of fusion and the level of polynucleation are dependent on the relative direction of the applied pulses. The effect of the pulse on the cells is thus proved to be vectorial and not scalar.

Protein-mediated intermembrane contact facilitates fusion of lipid vesicles with planar bilayers

Fusion of phospholipid vesicles with planar bilayer membranes occurs provided there is an intermembrane contact, which can be mediated by phospholipid-binding proteins, even in the absence of calcium. The firm attachment phase is then followed by the osmotically-driven fusion. These results show that hydrophobic proteins (not necessarily Ca2+-binding proteins) may enhance fusion by promoting contact of membranes. Such proteins may operate synergistically with Ca2+ to reduce the threshold concentration of Ca2+ needed for fusion of biological membranes. Protein-mediated intermembrane contact resulting in fusion may play a crucial role in the regulation and catalysis of biological fusion events.

Stomatocytosis of latex particles (0.26 micron) by rat erythrocytes by the electrical breakdown technique

The uptake of macromolecules by erythrocytes can be achieved with the electrical breakdown technique [2, 4]. In this technique the erythrocyte membranes are subjected to a high external electrical field pulse for a short period. Local, reversible breakdowns of the cell membrane occur above a critical field strength which lead to a time-dependent increase in the permeability of the membrane. By this means, human erythrocyte membranes can be made permeable to DNA, pharmaceutical compounds, and latex particles following an electrical field pulse [1, 3, 5]. Larger particles should also be taken up by erythrocytes using this method. Vienken et al. [5] demonstrated the entrapment of latex particles with a diameter of 0.091 micron in human erythrocyte ghosts, although this was shown with only a single electron micrograph which does not prove that the ghost membrane was intact. In our experiments in order to entrap latex particles with a diameter of 0.26 micron rat erythrocytes were subjected to an electrical field pulse of 12 kV/cm with a decay time of 60 microseconds. Experiments using the electron microscope show that after such an electrical field pulse the uptake of latex particles by rat erythrocytes follows the stomatocytotic pathway. We show further that using electron microscopic techniques, a single section cannot demonstrate the completed uptake of a latex particle by the erythrocyte.

Microinjection of cultured cells using red-cell-mediated fusion and osmotic lysis of pinosomes: a review of methods and applications

Proteins and other macromolecules can be injected into cultured cells by several different methods. Here we review the strengths and limitations of two of these methods, red-cell-mediated microinjection and osmotic lysis of pinosomes, and indicate how they may be successfully applied to the study of cultured cells.

Magneto-electro-fusion of human erythrocytes

In inhomogeneous (static) magnetic fields close contact between 'magnetic' human erythrocytes was established. The cells were made magnetic by incubating them in a medium containing small Fe3O4 -particles which adsorbed to the outer membrane surface. Fusion was induced by applying two electric field pulses (field strength: 8.5 kV X cm-1; duration: 60 microseconds) to the magnetically collected cells. This procedure allowed the use of electrically conductive media (3 X 10(-3) omega -1 X cm-1). Fusion of red blood cells occurred very often. If cell suspensions of high density were used fusion resulted in the formation of giant red blood cells with osmotically intact membranes.

Electro-fusion of cells: principles and potential for the future

Exposure of cells or liposomes to a brief pulse of a strong electrical field can result in a reversible breakdown of the outer membrane. Such breakdown results in an increase in permeability of the plasmalemma, which however re-seals after a short incubation (i.e. the original impermeability is restored). Two or more cells in contact can be made to fuse by this process, provided that the contact is close enough and that the pulse of the electrical field is short enough not to damage the cells. Methods of achieving this contact by electrical and magnetic fields are described. The magnetic method does not demand the use of the low conductivity media used earlier. Other possible modifications of this flexible technique are also described, and used to show how the technique can be modified in future, and how it may be applied to the fields of membrane research, medicine and plant breeding.

Electric field-induced breakdown of lipid bilayers and cell membranes: a thin viscoelastic film model

A simple viscoelastic film model is presented, which predicts a breakdown electric potential having a dependence on the electric pulse length which approximates the available experimental data for the electric breakdown of lipid bilayers and cell membranes (summarized in the reviews of U. Zimmermann and J. Vienken, 1982, J. Membrane Biol. 67:165 and U. Zimmermann, 1982, Biochim. Biophys. Acta 694:227). The basic result is a formula for the time tau of membrane breakdown (up to the formation of pores): tau = alpha (mu/G)/(epsilon 2m epsilon 2oU4/24 sigma Gh3 + T2/sigma Gh-1), where alpha is a proportionality coefficient approximately equal to ln(h/2 zeta o), h being the membrane thickness and zeta o the amplitude of the initial membrane surface shape fluctuation (alpha is usually of the order of unity), mu represents the membrane shear viscosity, G the membranes shear elasticity modules, epsilon m the membrane relative permittivity, epsilon o = 8.85 X 10(-12) F/m, U the electric potential across the membrane, sigma the membrane surface tension and T the membrane tension. This formula predicts a critical potential Uc; Uc = (24 sigma Gh3/epsilon 2m epsilon 2o)1/4 (for tau = infinity and T = 0). It is proposed that the time course of the electric field-induced membrane breakdown can be divided into three stages: (i) growth of the membrane surface fluctuations, (ii) molecular rearrangements leading to membrane discontinuities, and (iii) expansion of the pores, resulting in the mechanical breakdown of the membrane.

Electrofusion. A new, highly efficient technique for generating somatic cell hybrids

A rapid and highly efficient method for generating viable somatic cell hybrids is described. A co-culture of clone ID and CH rodent cell lines was exposed to five successive electric pulses of about 1.5 kV/cm with a duration of 50 musec. This treatment induced extensive cell fusion, and independent hybrid clones were generated with a frequency of 1 X 10(-3), which represents a 100-fold increase over the polyethylene glycol induced fusion. Seventeen of them were propagated in selective medium, karyotyped and analysed for their enzyme markers, in order to establish their hybrid nature.

Clastogenic effects in human lymphocytes of power frequency electric fields: in vivo and in vitro studies

In vivo and in vitro studies of the clastogenic effects of power frequency electric fields and transient electric currents have been performed. For the in vivo investigation peripheral lymphocytes from twenty switchyard workers were screened for chromosome anomalies. The rates of chromatid and chromosome breaks were found to be significantly increased compared to the rates in 17 controls. Exposure of human peripheral lymphocytes, in vitro, to a 50-Hz current with 1 mA/cm2 current density did not induce any chromosome damage. Exposure to ten 3 mus-long spark discharge pulses with a peak field strength in the samples of 3.5 kV/cm, however, resulted in chromosome breaks at a frequency similar to that induced in lymphocytes in vitro by ionizing radiation at 0.75 Gy. The biological significance of chromosomal damage induced in somatic cells is discussed.

GM1 micelles modify the transport properties of the ionophore gramicidin D in artificial planar bilayers

We have analyzed the effects induced in different phospholipid planar bilayers by monosialoganglioside micelles containing the ionophore gramicidin D. The membrane conductance increases after the addition of GM1 micelles at various ionophore/ganglioside ratios. We believe this fact may be ascribed to gramicidin molecules that incorporate into the bilayer together with gangliosides. In the presence of micelles the mean lifetime and the amplitude of the gramicidin single channel did not present relevant modifications when dioleoylphosphatidylcholine or phosphatidylserine were used to form the bilayer. Calcium proved to trigger the interaction between phosphatidylethanolamine membranes and GM1 micelles containing gramicidin. In this case the ionic pore presents a longer lifetime and a lower amplitude with respect to pure gramicidin. We suggest that different properties developed by gramicidin may depend on structural organization of gangliosides when incorporated into the phospholipid bilayer.

Fusion of mitochondrial inner membranes by electric fields produces inside-out vesicles. Visualization by freeze-fracture electron microscopy

The fusion of vesicular-shaped mitochondrial inner membranes was observed by a new approach which combines freeze-fracture electron microscopy and electric field-induced fusion. Results show that membrane events caused by the exposure to the electric field can be time-coordinated with sample freezing for subsequent analysis by freeze-fracture electron microscopy.

Homokaryon production by electrofusion: a convenient way to produce a large number of viable mammalian fused cells

A convenient technique to obtain homokaryons is described that provides large amounts of fused mammalian cells. Chinese hamster ovary cells grown in monolayers on a Petri dish are submitted to square wave electric pulses. Viability of cells is observed not to be affected by this electric treatment. The yield of fusion is strongly dependent on the strength of the field (KV/cm range) and on the duration of the pulse (microsecond range). The yield is not improved by accumulation of pulses. Yields up to 80% are obtained and under our experimental conditions 200 000 cells are fused per assay.

Vesicle formation during electro-fusion of mesophyll protoplasts of Kalanchoë daigremontiana

Following electro-fusion of plant protoplasts the volume of the fused cell is the sum of the volumes of the parent cells. As shown for mesophyll protoplasts from leaves of Kalanchoë daigremontiana, the excess in membrane material arising from the reduction in membrane area is removed-at least to a larger extent - by the formation of vesicles which are visible in the light microscope. These vesicles, which may have been formed by the fusion of sub-microscopic vesicles, are observed in the contact zone of the fusing cells. The mechanism of the formation of vesicles during electro-fusion is discussed.