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

Membrane integrity and amyloid cytotoxicity: a model study involving mitochondria and lysozyme fibrillation products

Recent findings implicate that fibrillation products, the protein aggregates formed during the various steps leading to formation of mature fibrils, induce neurotoxicity predominantly in their intermediate oligomeric state. This has been shown to occur by increasing membrane permeability, eventually leading to cell death. Despite accumulating reports describing mechanisms of membrane permeabilization by oligomers in model membranes, studies directly targeted at characterizing the events occurring in biological membranes are rare. In the present report, we describe interaction of the original native structure, prefibrils and fibrils of hen egg white lysozyme (HEWL) with mitochondrial membranes, as an in vitro biological model, with the aim of gaining insight into possible mechanism of cytotoxicity at the membrane level. These structures were first characterized using a range of techniques, including fluorescence, size-exclusion chromatography, dynamic light scattering, transmission electron microscopy, dot blot analysis and circular dichroism. HEWL oligomers were found to be flexible/hydrophobic structures with the capacity to interact with mitochondrial membranes. Possible permeabilization of mitochondria was explored utilizing sensitive fluorometric and luminometric assays. Results presented demonstrate release of mitochondrial enzymes upon exposure to HEWL oligomers, but not native enzyme monomer or mature fibrils, in a concentration-dependent manner. Release of cytochrome c was also observed, as reported earlier, and membrane stabilization promoted by addition of calcium prevented release. Moreover, the oligomer-membrane interaction was influenced by high concentrations of NaCl and spermine. The observed release of proteins from mitochondria is suggested to occur by a nonspecific perturbation mechanism.

Method of oocyte activation affects cloning efficiency in pigs

The following experiments compared the efficiency of three fusion/activation protocols following somatic cell nuclear transfer (SCNT) with porcine somatic cells transfected with enhanced green fluorescent protein driven by the chicken beta-actin/rabbit beta-globin hybrid promoter (pCAGG-EGFP). The three protocols included electrical fusion/activation (NT1), electrical fusion/activation followed by treatment with a reversible proteasomal inhibitor MG132 (NT2) and electrical fusion in low Ca(2+) followed by chemical activation with thimerosal/dithiothreitol (NT3). Data were collected at Days 6, 12, 14, 30, and 114 of gestation. Fusion rates, blastocyst-stage mean cell numbers, recovery rates, and pregnancy rates were calculated and compared between protocols. Fusion rates were significantly higher for NT1 and NT2 compared to NT3 (P < 0.05). There was no significant difference in mean nuclear number. Pregnancy rate for NT2 was 100% (n = 19) at all stages collected and was significantly higher than NT1 (71.4%, n = 28; P < 0.05), but was not significantly higher than NT3 (82.6%, n = 23; P < 0.15). Recovery rates were calculated based on the number of embryos, conceptuses, fetuses, or piglets present at the time of collection, divided by the number of embryos transferred to the recipient gilts. Recovery rates between the three groups were not significantly different at any of the stages collected (P > 0.05). All fusion/activation treatments produced live, pCAGG-EGFP positive piglets from SCNT. Treatment with MG132 after fusion/activation of reconstructed porcine embryos was the most effective method when comparing the overall pregnancy rates. The beneficial effect of NT2 protocol may be due to the stimulation of proteasomes that infiltrate donor cell nucleus shortly after nuclear transfer.

The effects of gramicidin on electroporation of lipid bilayers

The effects of the channel-forming peptide gramicidin D (gD) on the conductance and electroporation thresholds of planar bilayer lipid membranes, made of the synthetic lipid 1-palmitoyl 2-oleoyl phosphatidylcholine (POPC), was studied. High-amplitude ( approximately 200-900 mV) rectangular voltage pulses of 15 ms duration were used to perturb the bilayers and monitor the transmembrane conductance. Electroporation voltage thresholds were found, and conductance was recorded before and after electroporation. Gramicidin was added to the system in peptide/lipid ratios of 1:10, 000, 1:500, and 1:15. The addition of gD in a ratio of 1:10,000 had no effect on electroporation, but ratios of 1:500 and 1:15 significantly increased the thresholds by 16% (p < 0.0001) and 40% (p < 0.0001), respectively. Membrane conductance before electroporation was measurable only after the addition of gD and increased monotonically as the peptide/lipid ratio increased. The effect of gD on the membrane area expansivity modulus (K) was tested using giant unilamellar vesicles (GUVs). When gD was incorporated into the vesicles in a 1:15 ratio, K increased by 110%, consistent with the increase in thresholds predicted by an electromechanical model. These findings suggest that the presence of membrane proteins may affect the electroporation of lipid bilayers by changing their mechanical properties.

Improving electrotransfection efficiency by post-pulse centrifugation

We have demonstrated that the viability of electrotransfected adherent CHO and suspended NK-L, K-562, L1210 and MC2 cells is improved if pelleting by centrifugation is performed immediately after pulsing. The protection effect on cell viability is cell line- and pellet thickness-dependent. For forming CHO cell pellets, centrifugation force (300-13,000 g) and duration are not crucial; about five to 10 cell layers in the pellet provide the optimal protection effect. NK-L, K-562, L1210 and MC2 cell pellets are optimally formed by centrifugation at 13,000 g in an Eppendorf desktop centrifuge. Pelleting improves the cell viability over the whole range of the NK-L, K-562, L1210 and MC2 cell concentrations studied. When this pelleting method is applied to load CHO cells with FITC-dextran (41,000 MW), not only is the success rate close to 100%, but the growth rate is similar to the control, which is far better than the conventional electroporation method. Furthermore, the transfection efficiency of the five cell lines in pellet is significantly higher than that in suspension.

Cell hybridization, hybridomas, and human hybridomas

Cell hybridization is one of the most basic cytotechnologies. The hemagglutinating virus of Japan was first used to cause cell fusion; however, polyethylene glycol is widely used now because of simplicity of procedure. This chapter first explains the principles of cell hybridization methods and then describes the practical protocols for preparing mouse hybridomas using polyethylene glycol. So far, lack of an excellent human fusion partner cell line that has high fusion efficiencies and does not produce immunoglobulin has hindered the spread of human-human hybridoma preparation methods. In the authors' laboratory NAT-30 and HO-323, human parent cell lines with high fusion efficiencies, have been established to prepare many hybridoma cell lines producing cancer-specific human monoclonal antibodies. Because NAT-30 and HO-323 cell lines are IgM producers, it is difficult to obtain IgG-producing hybridomas because the types of immunoglobulin produced by hybridomas are strongly affected by the characteristics of parent cells. Thus a nonimmunoglobulin-producing human parent cell line, A4H12, derived from human T lymphoma was established that can efficiently obtain IgG-producing human hybridomas. Another problem with preparing human hybridomas is that it is difficult to obtain B lymphocytes immunized with optional antigens for ethical reasons. To overcome this problem, in vitro immunization methods have been developed that allow exposure of a large number of B lymphocytes to cultured cancer cell or soluble antigens. The section on human hybridomas explains human fusion partners, in vitro immunization methods, and the preparation of human-human hybridomas using an electrofusion method. Finally, the application of human monoclonal antibodies to medical uses and the preparation of supranatural monoclonal antibodies are reviewed. These include multifunctional monoclonal antibodies and altered monoclonal antibodies having increased affinity and specificity by exchanging or modifying light chains.

Divalent cations, phospholipid asymmetry and osmotic swelling in electrically-induced lysis, cell fusion and giant cell formation with human erythrocytes

We have previously reported that acidic phospholipids are exposed at the surface of human erythrocytes when the cells are subjected to electrical breakdown. It has now been shown that the prothrombinase assay, which was used previously for the determination of acidic phospholipids, is specific for phosphatidylserine under the conditions of our experiments. In the light of this finding, we have investigated and characterised factors that govern cell lysis, cell fusion, and the formation of giant cells induced by electrical breakdown with human erythrocytes in media of low ionic strength. Divalent cations (1.1 mM) protected the cells against haemolysis, in the order Mn2+ > Ca2+ > Ba2+ > Mg2+ >> Zn2+, whereas about 99% of the cells lysed immediately on breakdown in the presence of Na+ or K+ (2.1 mM), or Al3+ (0.95 mM). The lengths of pearl chains of fused erythrocytes formed was similarly greatest with Mn2+ and decreased progressively with Ba2+, Zn2+, Ca2+ and Mg2+. No cell fusion occurred with Na+, K+, or Al3+. It is suggested that interactions with phosphatidylserine, which is exposed at the cell surface by electrical breakdown, may enable Mn2+, Ba2+ and Ca2+ ions to inhibit cell lysis (via membrane resealing) and facilitate cell fusion. Following electrically-induced cell fusion, erythrocytes round-up into giant cells. It has previously been proposed that Ca2+ ions accelerate the rounding-up process. However, data are presented which show that, as with erythrocytes treated with Sendai virus, the formation of rounded, giant cells following cell fusion depends on the osmotic swelling properties of permeabilised erythrocytes. Osmotic swelling may also have induced any hemi-fused cells present to fuse completely. Zn2+ ions anomalously enabled erythrocytes to round-up very rapidly into giant cells following electrical breakdown. This phenomenon may result from an interaction of Zn2+ ions with cysteine groups in membrane proteins, which decreases the immediate loss of ions that occurs when erythrocytes are subjected to electrical breakdown in low-ionic-strength media.

Relationships between the surface exposure of acidic phospholipids and cell fusion in erythrocytes subjected to electrical breakdown

The procoagulant activity of human erythrocytes, which provides a measure of the translocation of acidic phospholipids from the inner to the outer monolayer of the plasma membrane, has been compared with the percentage cell fusion in experiments on the effects of electrical breakdown pulses under differing experimental conditions. After treatment with breakdown pulses of 20 microseconds or longer (5 kV cm-1), the plasma membranes of erythrocytes in 250 mM sucrose exhibited an almost complete loss of asymmetry with respect to acidic phospholipids. As the breakdown voltage was increased from 2 to 5 kV cm-1 (with breakdown pulses of 99 microseconds), the surface exposure of acidic phospholipids and cell fusion increased approximately in parallel. Furthermore, with 99 microseconds pulses and a voltage of 3 kV cm-1, a decrease in the osmolarity from 250 to 150 mM of the sucrose medium was accompanied by an increase in both the surface exposure of acidic phospholipids and the extent of cell fusion. Breakdown pulses of 2-5 microseconds were sufficient to cause a marked loss of asymmetry, but no cell fusion was observed unless the pulse length was at least 20 microseconds. Kinetic experiments indicated that exposure of the acidic phospholipids at the cell surface was more likely to be due to a direct effect of the electric field pulses on plasma membrane structure than to secondary effects, such as the action of endogenous proteinases on the membrane skeleton. It seems possible that a localised, surface exposure of acidic phospholipids may contribute to the 'long-lived fusogenic state' (Sowers, A.E. (1986) J. Cell Biol. 102, 1358-1362) and the 'transient permeant structures' (Teissié, J. and Rols, M.P. (1986) Biochem. Biophys. Res. Commun. 140, 258-266) that enable cell fusion to occur when contact between cells is established after they have been subjected to field pulses. Our observations also provide circumstantial support for the concept that changes in the phospholipid asymmetry of membranes may be important in physiologically-occurring instances of biomembrane fusion.

Transfer of defined numbers of chloroplasts into albino protoplasts using an improved subprotoplast/protoplast microfusion procedure: transfer of only two chloroplasts leads to variegated progeny

A procedure is described by which it is possible to perform controlled microfusion of microscopically selected protoplast fusion partners with high efficiencies. The procedure is applied to fusion of Nicotiana tabacum (line 92V37. N. undulata cytoplasm) plastid albino protoplasts as a recipient and spontaneously formed subprotoplasts of green N. tabacum (line SR1) as donor. Products of individual electrofusion events are cloned via single cell nurse culture and the derived cell lines are analysed for the occurrence of variegated or green regenerating shoots, which are indicative of the establishment of the transferred organelles in the cell progeny. The plastid population in green regenerants recovered after the transfer of only two chloroplasts was demonstrated to have originated from the donor subprotoplast organelles by restriction analysis of total DNA using a plastome-specific probe.

Membrane fusion without cytoplasmic fusion (hemi-fusion) in erythrocytes that are subjected to electrical breakdown

There are many reports of hemi-fusion in phospholipid vesicles but few published studies on hemi-fusion in cells. We report evidence from both fluorescence microscopy and freeze-fracture electron microscopy for hemi-fusion in the electrofusion of human erythrocytes. We have also characterised the conditions that favour hemi-fusion as opposed to complete fusion, and discuss the possibility that hemi-fusion might precede complete electrically-induced cell fusion. A membrane probe (DiIC16) and a cytoplasmic probe (6-carboxyfluorescein) were used to investigate the behaviour of doubly-labelled human erythrocytes which were aligned in chains by dielectrophoresis and then exposed to high voltage breakdown pulses. Some of the cells were fused by the pulses, as shown by diffusion of both membrane and cytoplasmic probes from labelled to unlabelled cells. With other cells, the membrane probe diffused into unlabelled cells after the breakdown pulses, without the cytoplasmic probe diffusing into unlabelled cells or leaking into the medium. Membrane fusion (hemi-fusion) thus occurred without cytoplasmic fusion in these erythrocytes. Such cells were irreversibly, but fragilely, attached to their neighbours by the breakdown pulses. There was an inverse relationship between conditions that permit complete fusion and those that favour hemi-fusion, with respect to breakdown pulse length, breakdown voltage and, in particular, osmolarity and temperature. The incidence of hemi-fusion in 250 mM erythritol was twice that in 150 mM erythritol, and hemi-fusion was 5-fold greater at 25 degrees C than at 20 degrees C. Hemi-fused erythrocytes occasionally fused completely on heating to 50 degrees C, demonstrating that hemi-fusion can proceed to complete cell fusion. Freeze fracture electron micrographs of preparations of hemi-fused cells revealed long-lived, complementary depressions and protrusions on the E- and P-fracture faces, respectively, of tightly apposed cells that may mediate hemi-fusion. The possibility that the fusion of closely adjacent human erythrocytes by electrical breakdown pulses may involve an intermediate, shared bilayer structure, which is stable in certain conditions but which can be ruptured by osmotic swelling of the permeabilised cells, is discussed.

Electroacoustic production of murine hybridomas

The optimal conditions for the production of murine hybridomas by electroacoustic fusion of cells in sugar solutions and of cells in ionic strength media (up to 115 mM NaCl) have been investigated. In the electroacoustic fusion technique cells were brought into contact in a 3 MHz ultrasonic standing wave field and were fused by application of an electric pulse. Hybridomas of murine splenocytes and X63-Ag8.653 mouse myelomas were successfully produced in low ionic strength mannitol solutions and in a range of salt concentrations up to 115 mM. The yield of hybridomas by electroacoustic fusion of cells in mannitol was at least as good as that obtained when cells were fused following conventional dielectrophoresis induced contact. The electroacoustic fusion yield was also comparable to conventional yields when cells were exposed to a pulse in higher ionic strength media where dielectrophoresis induces heating effects. Hybridomas were produced at similar electric field strengths when cells were suspended in high ionic strength media (up to 115 mM NaCl) or in mannitol. The effective electric field strength for hybridoma production was close to that at which trypan blue tests indicated membrane damage.

Enhanced hybridoma production by electrofusion in strongly hypo-osmolar solutions

Electrofusion of mammalian cells in strongly hypo-osmolar media containing sorbitol, small amounts of divalent cations and albumin resulted in high yields of hybrids. The number of viable hybrids was higher than any value for chemically- or electrically-mediated fusion reported in the literature. Optimum clone numbers were obtained for fusion of osmotically-stable subclones of murine myeloma cells with DNP-Hy-stimulated lymphocytes provided that the osmolarity of the fusion medium was as low as 75 mosmol/l. Similar results were obtained for fusion of osmotically stable subclones of myeloma cells with the murine hybridoma cell line G8. Due to the dramatic increase in volume the field strength of the breakdown pulse (leading to fusion of the dielectrophoretically aligned cells) has to be reduced, as predicted by theory. The efficacy of hypo-osmolar electrofusion allowed the use of very few cells (about 10(5) lymphocytes or G8 cells per fusion chamber). This figure is considerably smaller than that reported in the literature for iso-osmolar electrofusion. It is significant that, in contrast to iso-osmolar conditions, the fusion yield in hypo-osmolar electrofusion was reproducible over long periods of time and less dependent of variations between cultures. At suspension densities of about 10(6) cells per fusion chamber (normally used in iso-osmolar electrofusion) hypo-osmolar electrofusion of homogeneous cell suspensions resulted in the formation of many giant cells when the appropriate field conditions were applied. Similar high or, at some field strengths, even higher numbers of clones at low cell suspension density were obtained when G8 and myeloma cells were first exposed during the washing procedure to strongly hypo-osmolar media, but then transferred to iso-osmolar solutions for electrofusion. Similar experiments with lymphocytes and myeloma cells failed because of destruction of many lymphocytes by the two osmotic shock steps in rapid succession. Volume distribution measurements of G8 and myeloma cells showed that after re-incubation of the osmotically pre-stressed cells the original volume distribution is largely, but not completely re-established. This and other results indicate that osmotic pressure gradients and associated tensions in the membrane do not play a primary role in the initiation of the electrofusion process. The experiments suggest that due to the osmotic (pre-) stress the membrane permeability is slightly and uniformly increased presumably due to the dissolution of membrane- and cell-skeleton proteins. Obviously, this facilitates electrofusion in hypo-osmolar or subsequently in iso-osmolar solutions.

Intracellular Calcium and Control of Burst Generation in Neurons of Guinea-Pig Neocortex in Vitro

Response properties of neurons in brain slices of guinea pig parietal neocortex were examined following intracellular injection of the Ca2+ chelators, EGTA and BAPTA. Although chelator injection did not cause any consistent change in passive membrane properties, it did induce 81% of neurons encountered at all sub-pial depths to become 'bursters', in that just-threshold depolarizing current pulses triggered all-or-none bursts of 2 - 5 fast action potentials. Transition to 'burstiness' was associated with disappearance of an AHP and appearance of a DAP. Although chelator caused a slight increase in steady-state firing rate, marked accommodation persisted. Extracellular Co2+ or Mn2+ had an effect on steady-state firing rate similar to that of the intracellular chelators; however, exposure to these Ca2+ channel blockers also caused steady state depolarization, increased resting input resistance and time constant, and profound spike broadening. This treatment never induced transition to 'burstiness'. Chelator-injected neurons ceased to generate bursts when Ca2+ was replaced by Mn2+ in the Ringer's solution. During exposure to 10-6 M TTX and 20 mM TEA, 50 - 200 msec Ca2+ spikes followed brief depolarizing pulses. As chelator was injected into the cell, there was progressive prolongation of the Ca2+ plateaus, which was associated with slowing of the rate at which membrane resistance gradually recovered following the initial increase in conductance. These findings indicate that under normal conditions, activity-related increases in intracellular Ca2+ activate processes which prevent most neocortical neurons from being bursters. These processes probably include Ca2+-dependent K+ currents, and Ca2+-dependent Ca2+ channel inactivation.

Cytoskeletal reorganization during electric-field-induced fusion of Chinese hamster ovary cells grown in monolayers

Mammalian cells were shown to fuse after direct electric pulsation of the plated cells in culture. The extent of fusion was controlled by the duration of the post-pulse incubation. Formation of polynucleated cells was slow, even at 37 degrees C. Pre-pulse incubation with colchicine increased the fusion yield slightly. Cytoskeletal organization during the post-pulse incubation was observed using immunofluorescence techniques. Microfilaments were unaffected, but microtubules disappeared during the first minutes following the pulse, and then reformed on subsequent incubation.

Efficient generation of stable antibody forming hybridoma cells by electrofusion

A variety of modified electrofusion protocols designed to improve the efficiency of hybridoma production have recently appeared in the literature. We undertook to maximize the number of antibody secreting murine hybridomas by optimizing the temperature and fusion strength parameters of the conventional electrofusion technique. Anti-DNP secreting hybridomas were generated by fusing SP2/0 to immunized mouse splenic lymphocytes using an unmodified electrofusion protocol consisting of washing in a weakly conducting sorbitol fusion medium supplemented with bovine serum albumin, calcium and magnesium ions. This was followed by dielectrophoretic alignment and application of 3 short duration, high intensity field pulses in helical chambers. Optimal efficiencies of hybridomas were generated by the application of 2000 V/cm pulses at 25 degrees C (2.45 hybridomas x 10(-4) splenocytes) and as many as 63% of resulting hybridomas secreted anti-DNP monoclonal antibodies, the majority of which were IgG's. These data show that modification of the electrofusion protocol by pretreatment of fusion partners with proteolytic enzymes or the use of antigen bridging is not required for the successful and efficient production of specific monoclonal antibodies by electrofusion.

Electrical stability of erythrocytes in the presence of divalent cations

Erythrocytes suspended in a medium of low ionic strength lyse under the effect of an exponential electrical pulse. The percentage of haemolysed cells decreases several-fold in the presence of divalent cations. The protective action of the ions studied increases in the following order: Ca++, Mg++, Zn++. It is assumed that divalent ions bind to the negative charges of the lipid and protein molecules and reduce their electrostatic repulsion, which results in stabilization of the membranes.

An improved method of electroporation for introducing biologically active foreign genes into cultured mammalian cells

We have developed a modified, reproducible, and efficient method for introducing cloned genes into mammalian cells by using an electric field followed by treatment with sodium butyrate. Transfection frequencies with plasmid pSV2-neo, consisting of an antibiotic (G418) resistance gene and simian virus 40 (SV40) early promoter, by electroporation were higher than those by calcium phosphate DNA precipitation. Treatment with sodium butyrate following electroporation significantly increased the frequency of transfection in various types of cell lines and primary cultured cells including human skin fibroblasts. Treatment with sodium butyrate also increased the transient expression of the gene for chloramphenicol acetyltransferase (acetyl-CoA; chloramphenicol O3-acetyltransferase, CAT, EC 2.3.1.28) when the gene was introduced into BALB/c 3T3 cells by electroporation. Electroporation combined with sodium butyrate treatment is an improved method for stable and transient biochemical transformation of foreign genes in cultured mammalian cells.

Improvement in the basic technology of electrofusion for generation of antibody-producing hybridomas

In order to define the optimum conditions of electrofusion technique for the generation of antibody-producing hybridomas, mouse spleen cells or EBV-transformed human B cells were fused with mouse myeloma cells (SP2/0) or human fusion partner cells (KR-4 or KR-12), respectively, by electric field pulse under various conditions. The results confirm reports that the presence of both Ca2+ and Mg2+ in fusion medium and pretreatment of mixed cells with proteases improve hybridoma yield. Moreover, the presence of liposome or hydrophobic protein in the fusion medium greatly enhanced the yield. Under optimum conditions, hybridoma yields of mouse cells and human cells were 2.5 X 10(-4) and 1 X 10(-4), respectively. These efficiencies were about ten times higher than those obtained by the conventional polyethylene glycol technique. Microscopic observation of the fusion-process revealed that in a human cell system 20%-50% of the cells were physically fused, although only one in 5000 physically fused human cells grew as a hybridoma after hypoxanthine-aminopterin-thymidine selection.

Usefulness of Ficoll in electric field-mediated cell fusion

Electrofusion is a technique that enables the production of new cell types with desired properties to be done. Ehrlich ascites tumor cells are fused by means of an electric field. Under too harsh external field strength or pulse length conditions, however, membrane breakdown leads to a loss of cellular cytoplasm. Addition of the high polymer Ficoll to the fusion medium increases its density and osmotic pressure, thus preventing cytoplasm from running out and, therefore, maintaining cell viability. Fusion between cells of different sizes is made possible or facilitated by means of Ficoll, as big cells do not lose their cytoplasm under conditions required for enhancing membrane permeability of the small cells. In presence of the proteolytic enzyme pronase, addition of Ficoll to the fusion medium further raises the fusion percentage compared to the exclusive addition of pronase. The fusion of cells of different densities is also greatly facilitated and its percentage increased by addition of Ficoll, thus obviating the necessity to perform electrofusion under conditions of microgravity.

Osmotic forces in artificially induced cell fusion

The importance of cell swelling in the fusion of erythrocytes by three different chemical treatments has been investigated with cells that were cytoplasmically labelled with 6-carboxyfluorescein. Hen erythrocytes, which had been pre-incubated with ionophore A23187 and 5 mM Ca2+ to cause a proteolytic breakdown of the membrane skeleton, were induced to fuse by applying an osmotic shock. Human erythrocytes that had been incubated in an isotonic salt/buffer solution, which was progressively diluted and which contained 0.5 mM La3+ to minimise cell lysis, were also fused. In addition, the fusion of human erythrocytes by 40% poly(ethylene glycol) began only when the poly(ethylene glycol) was diluted, and it mostly occurred when the diluted polymer solution was subsequently replaced by isotonic buffer. In related experiments, the effect of an osmotic gradient on electrically induced cell fusion has been studied. Human erythrocytes in 150 mM erythritol fused more readily than less swollen cells in 200-400 mM erythritol when subjected to a 20 microseconds pulse of 3.5 kV X cm-1, indicating that the extent of cell fusion induced by the breakdown pulse is governed by the combined electrical-compressive and osmotic forces. Since osmotic phenomena are already known to be important in exocytosis, we suggest that these observations on cell fusion indicate that osmotic forces may provide the driving force for many membrane fusion reactions in biological systems.