Induction of a long-lived fusogenic state in viable plant protoplasts permeabilized by electric fields

Electropermeabilized tobacco mesophyll protoplasts are shown to fuse by creating cell contact several minutes after electropulsation. Electropermeabilization was analysed by measuring calcein uptake. Experiments were performed at low temperature to avoid resealing of protoplast transient permeation structures. These results confirm that the long-lived permeabilized state induced by the electric field is associated to a fusogenic state, under viability conditions. This is indicative that as for mammalian cells, the electric field-induced membrane modifications, which give the permeable state, are such as to decrease the magnitude of the intercellular repulsive forces between plant protoplasts. Such a fusion method may be useful for somatic hybrids production with protoplasts showing morphological and physiological differences.     

A long-lived fusogenic state is induced in erythrocyte ghosts by electric pulses

Treatment of erythrocyte ghosts in random positions in a suspension with membrane fusion-inducing direct current electric field pulses causes the membranes to become fusogenic. Significant fusion yields are observed if the membranes are dielectrophoretically aligned into membrane-membrane contact with a weak alternating electric field as much as 5 min after the application of the pulses. This demonstrates that a long-lived membrane structural alteration is involved in this fusion mechanism. Other experiments indicate that the areas on the membrane which become fusogenic after treatment with the pulses may be very highly localized. The locations of these fusogenic areas coincide with where the trans-membrane electric field strength was greatest during the pulse. The fusogenic membrane alteration, or components thereof, in these areas laterally diffuses very slowly or not at all, or, to be fusogenic, must be present at concentrations in the membrane above a certain threshold. The loss of soluble 0.9-3-nm-diameter fluorescent probes from resealed cytoplasmic compartments of randomly positioned erythrocyte ghosts occurs through electric field pulse-induced pores only during a pulse but not between pulses or after a train of pulses if the probe diameter is 1.2 nm or greater. For a given pulse treatment of membranes in random positions in suspensions, an increase in ionic strength of the medium results in (a) a decrease in loss during the pulse, (b) no difference in loss between pulses, and (c) an increase in fusion yield when membrane-membrane contact is established. The latter two results (b and c) are incompatible with a fusion mechanism that proposes a simple relationship between electric field-induced pores and fusion.     

Application of electric field fusion in plant tissue culture

Manipulation of protoplasts via fusion and organelle transfer is expected to be facilitated by the technique known as electric field fusion. Construction and use are described of three flow-through fusion chambers that incorporate flat-sided electrodes in a manner that makes fusion of protoplasts possible througout the chambers' total volume (4, 49 or 110 μl) under constant electrical, chemical and physical conditions. Brassica napus L. protoplasts subjected to fusogenic conditions, that is, application of voltages that induce reversible membrane breakdown, were capable not only of survival but also of cell wall resynthesis, cell division and subsequent growth and development. Intraspecific ( B. napus × B. napus ), interspecific. ( B. napus × B. campestris L.) and intergeneric ( B. napus × Primula acaulis L.) fusion and engulfment events were followed by using on the one hand autofluorescence and fluorescein isothiocynate as respective markers or on the other hand autofluorescence and vacuolar anthocyanin ( Primula ). Properties and merits of flat-sided versus cylindrical electrodes are discussed.     

The Systematic Study of the Electroporation and Electrofusion of B16-F1 and CHO Cells in Isotonic and Hypotonic Buffer

The fusogenic state of the cell membrane can be induced by external electric field. When two fusogenic membranes are in close contact, cell fusion takes place. An appropriate hypotonic treatment of cells before the application of electric pulses significantly improves electrofusion efficiency. How hypotonic treatment improves electrofusion is still not known in detail. Our results indicate that at given induced transmembrane potential electroporation was not affected by buffer osmolarity. In contrast to electroporation, cells’ response to hypotonic treatment significantly affects their electrofusion. High fusion yield was observed when B16-F1 cells were used; this cell line in hypotonic buffer resulted in 41?±?9?% yield, while in isotonic buffer 32?±?11?% yield was observed. Based on our knowledge, these fusion yields determined in situ by dual-color fluorescence microscopy are among the highest in electrofusion research field. The use of hypotonic buffer was more crucial for electrofusion of CHO cells; the fusion yield increased from below 1?% in isotonic buffer to 10?±?4?% in hypotonic buffer. Since the same degree of cell permeabilization was achieved in both buffers, these results indicate that hypotonic treatment significantly improves fusion yield. The effect could be attributed to improved physical contact of cell membranes or to enhanced fusogenic state of the cell membrane itself.     

Electric field-induced fusion of isolated vacuoles and protoplasts of different developmental and metabolic provenience

Using an electric field pulse technique, we induced fusion between vacuoles and protoplasts of Kalanchoë daigremontiana , between protoplasts from etiolated and green leaf mesophyll, and between mesophyll protoplasts from plants of different physiological properties ( Avena sativa : C₃ mechanism of photosynthesis, Kalanchoë daigremontiana : crassulacean acid metabolism). Close membrane contact amongst protoplasts or between protoplasts and vacuoles (as required for fusion) was achieved by the application of an alternating, non-uniform electric field to the suspension. Due to the dielectrophoresis effect the cells attach to each other along the field lines. The fusion process is initiated by the injection of an electric field pulse of high intensity and short duration (μs range). The field intensity has to be sufficiently high to induce reversible breakdown in the area of close membrane contact. After the application of the field pulse, the fusion process is initiated and completed within seconds to a few minutes, depending on the material investigated.
Fusion occurs between protoplasts and vacuoles as well as between protoplasts of different species. Both tonoplast and plasma membranes completely intermingled, indicating that in contrast to suggestions in the literature these membranes are compatible. Furthermore the cytoplasms of etiolated and green protoplasts obviously do not mix after fusion is completed, as etioplasts and chloroplasts kept separated from each other. In all experiments the volume of the fusion product equalled the sum of the compartments that underwent fusion. The wide spectrum of possible applications resulting from these fusion experiments in relation to metabolic problems is discussed.     

External electric fields stimulate the electrogenic calcium/sodium exchange in plant protoplasts

External electric fields of low intensity stimulated calcium influx in protoplasts isolated from carrot cell suspension cultures in field intensity dependent and frequency-dependent ways. The field-induced calcium uptake involved a temperature-dependent system that was saturable by external calcium. The induction process appeared mainly cumulative as long as the morphology of the protoplasts did not change (up to 10 min). The stimulation elicited by the electric fields was effective even after switching the field off; the influx increased for 5 min and then slowed down to its initial value 15 min later. During electrostimulation, an additional amount of ATP was accumulated; on removal of the stimulatory field, the extra amount of ATP was consumed, whereas the plasma membrane was hyperpolarized and sodium ions were expelled from the protoplasts. Inhibition of either ATP accumulation or consumption results in the inhibition of both calcium influx and sodium efflux, demonstrating that these processes are coupled. From the data obtained in this work, it may be concluded that the electric field stimulates an ATP synthase like activity; the consumption of the ATP thus formed elicits an electric potential (probably due to the efflux of cations and more specifically sodium) that drives the influx of calcium.     

Membrane instability induced by purified myelin components. Its possible relevance to experimental allergic encephalomyelitis.

The fusogenic properties of purified myelin components in a system employing chicken erythrocytes were studied. Sulphatides, myelin basic protein and the apoprotein of Folch-Lees proteolipid were capable of individually inducing membrane fusion in the presence of Ca2+. By contrast, cerebrosides or a mixture of sulphatides and myelin basic protein (molar ratio 19 : 1) did not show such effect. The fusogenic ability of sulphatide was correlated to its behaviour in mixed monolayers with phospholipids at the air-water interface. Mixed films of sulphatides with phosphatidylcholine or sphingomyelin but not with phosphatidylethanolamine showed reductions of molecular packing and surface potential similar to those found for other fusogenic compounds. The effects of myelin components described could be of importance in the membrane instability and vesicular disruption of myelin occurring in demyelinative disorders.     

The isolation and purification of surface specific proteins of somatic and reproductive protoplasts of lily and rapeseed

The plasma membrane surface proteins of intact somatic (leaf) and reproductive (pollen, generative cell or sperm cell) protoplasts of lily ( Lilium longiflorum ) and rapeseed ( Brassica napus cv. Midas) were compared after probing with N-hydroxysuccinimido- (NHS) or sulfo-NHS-biotin. The plasma membranes of intact protoplasts are impermeable to these biotin probes, which bind covalently to the free amino groups of surface proteins. Enzyme-labelled streptavidin was used to detect membrane proteins after separation by SDS-PAGE and western blotting. In lily, six proteins specific to the surface membrane of leaf protoplasts were identified varying from 25–64 kDa, three proteins to pollen protoplasts in the range 35–64 kDa and two proteins to generative cell protoplasts, 63 and 67 kDa. In rapeseed leaf protoplasts, seven proteins in the range 22–69 kDa were detected, while in the sperm enriched fraction five proteins were present in the same kDa range. The proteins identified as membrane specific for generative cell protoplasts of lily have been isolated and were used as antigens for monoclonal antibody production. Preliminary results indicate the successful production of antibodies to surface antigens. These antibodies will be used to localise surface specific epitopes which are likely to be involved in cell-cell recognition at fertilization.     

Immunological Properties of Micrococcus lysodeikticus Membranes

Membranes of Micrococcus lysodeikticus possess antigens which are distinct from other cellular components such as cytoplasm, ribosomes, and cell walls. Only a few (two to three) components are found when dissociated membranes are examined by immunodiffusion and immunoelectrophoresis techniques. Membranes treated with 0.3% sodium dodecyl sulfate, 0.3% Triton X-100, trypsin, phospholipase A or C, or by sonic oscillation at pH 9.0, all showed the same pattern (three major bands) when examined against membrane antisera by immunoelectrophoresis. Immunological analysis of fractions isolated by sucrose gradient centrifugation or by polyacrylamide gel electrophoresis suggests that individual components cross-react. Antibodies to adenosine triphosphatase (EC 3.6.1.3) and fast-moving component are not removed by absorption with protoplasts. Removal of antibody to one of the membrane antigens by protoplast absorption indicated a surface location. Glutaraldehyde fixation of protoplasts resulted in the loss of membrane antigens detectable by immunodiffusion.     

Fusion of Avena sativa mesophyll cell protoplasts by electrical breakdown

Studies with the light microscope were carried out on mesophyll cell protoplasts of Avena sativa which had been made to undergo fusion by reversible electrical breakdown of the cell membrane. In order to establish close membrane contact between the cells, an important prerequisite for fusion, a method known as dielectrophoresis was used. In an inhomogeneous alternating electrical field the protoplasts adhere to the electrodes and to each other in the direction of the field lines. The cells which were thus brought into close contact with each other could be made to fuse by the application of a field pulse of high amplitude (about 750 V/cm) and short duration (20–50 μs). The field strength required for fusion exceeds the value necessary for the electrical breakdown of the cell membrane. Fusion took place within some minutes and led to a high yield of fused protoplasts. The fusion of cells being in the electric field occured in a synchronous manner. In some of the fusion experiments part of the protoplasts of A. sativa were stained with neutral red. When these cells were fused with unstained protoplasts, the vacuoles from the different cells within the fused aggregate could be shown to remain separate for quite some time.     

Electro-Enhancement of the Formation of Cell Clusters from Protoplasts of Tritium aestivum

Under the treatment of 0.5—2.0 μA direct electric currents, the number of cell clusters derived from wheat (Triticum aestivum L. ) protoplasts was dramatically increased. The effect was related to the time-length of the treatments, and appeared only when the timelength was more than the threshold. The threshold time decreased with increase of electric current intensity. The effect was not related to the starting time of the treatments in culture of the protoplasts.     

Aspects of plant plasmalemma charging induced by external electric field pulses

The charging of the plasmalemma is a necessary condition for permeabilization of the plasma membrane (electroporation) in response to external electric field exposure. Common theories explain this permeabilization by formation of pores in the lipid bilayer. Using pulsed laser fluorescence microscopy, we measured the charging process of the membrane during the application of an external electric field with a temporal resolution of 5 ns. Visualization of the charging process of protoplasts plasma membrane (Nicotiana tabacum Bright Yellow 2) was achieved by staining of the plasma membrane with the voltage-sensitive fluorescent dye ANNINE-6. Measurements on membranes exhibiting negligible membrane permeabilization confirm the sine-shaped azimuthal distribution of the membrane voltage predicted by the relation of Cole. At higher membrane voltages, enhanced pore formation allows for the exchange of charge carriers, leading to deviations from the sine-shaped curve progression, i.e., a saturation of the membrane voltage at membrane segments facing the electrodes. Additionally, measurements on protoplasts exposed to multiple successive pulses indicate that the recovery of the membrane seems to be a fast process, occurring within seconds after termination of the external electric field pulse.     

The hydraulic conductivity as a criterion for the membrane integrity of protoplasts fused by an electric field pulse

The hydraulic conductivity of the membrane, Lp, of fused plant protoplasts was measured and compared to that for unfused cells, in order to identify possible changes in membrane properties resulting from the fusion process. Fusion was achieved by an electric field pulse which induced breakdown in the membranes of protoplasts in close contact. Close membrane contact was established by dielectrophoresis. In some experiments pronase was added during field application; pronase stabilizes protoplasts against high field pulses and long exposure times to the field. The Lp-values were obtained from the shrinking and swelling kinetics in response to osmotic stress. The Lp-values of fused mesophyll cell protoplasts of Avena sativa L. and of mesophyll and guard cell protoplasts of Vicia faba L. were found to be 1.9±0.9·10^-6, 3.2±2.2·10^-6, and 0.8±0.7·10^-6 cm·bar^-1·s^-1, respectively. Within the limits of error, no changes in the Lp-values of fused protoplasts could be detected in comparison to unfused protoplasts. The Lp-values are in the range of those reported for walled cells of higher plants, as revealed by the pressure probe.Abbreviations GCP guard cell protoplast - Lp hydraulic conductivity - MCP mesophyll cell protoplast     

Membrane instability induced by purified myelin components. Its possible relevance to experimental allergic encephalomyelitis

The fusogenic properties of purified myelin components in a system employing chicken erythrocytes were studied. Sulphatides, myelin basic protein and the apoprotein of Folch-Lees proteolipid were capable of individually inducing membrane fusion in the presence of Ca²⁺. By contrast, cerebrosides or a mixture of sulphatides and myelin basic protein (molar ratio 19 : 1) did not show such effect. The fusogenic ability of sulphatide was correlated to its behaviour in mixed monolayers with phospholipids at the air-water interface. Mixed films of sulphatides with phosphatidylcholine or sphingomyelin but not with phosphatidylethanolamine showed reductions of molecular packing and surface potential similar to those found for other fusogenic compounds. The effects of myelin components described could be of importance in the membrane instability and vesicular disruption of myelin occurring in demyelinative disorders.     

Cytochalasin D attenuates the desensitisation of pressure-stimulated vesicle fusion in guard cell protoplasts

Fusion of vesicular membranes with the plasma membrane during pressure-driven swelling of guard cell protoplasts was studied using patch clamp capacitance measurements. Hydrostatic pressure pulses were applied via the patch pipette and resulted in an immediate and linear increase in membrane capacitance, a parameter proportional to the surface area. In any given protoplast, pressure-stimulated increases in membrane capacitance could be provoked repetitively. However, the rate of rise in capacitance upon the same strength of stimulation decreased exponentially with time (tau = 4 min) for subsequent pressure stimuli. This process was the result of a desensitisation of the plasma membrane to mechanical forces. Incubation of guard cell protoplasts in cytochalasin D, which depolymerises actin filaments, nearly abolished this desensitisation process. These results suggest that membrane stretch initiates a reactive process that may fortify or stabilise the plasma membrane of guard cell protoplasts.     

Morphological Analysis of the Interaction of Charged Surfactant Vesicles (SVs) with Human Cultured Cells

We analyzed the binding and fusogenic properties of surfactant vesicles (SVs), composed of ionic and nonionic surfactants and cholesterol, with the surface of different human lymphoid cells. The influence of charge on SVs-cell interaction was evaluated by monitoring the presence of fluorescent sodium calcein artificially entrapped in the vesicles using optical fluorescence microscopy and laser scanning confocal microscopy. Our results clearly indicate that only negatively charged vesicles bind and fuse with the plasma membrane of human lymphoid cells, and the number of SVs bound to the cell surface was variable among the positive cells. Thin section electron microscopy illustrated that the fusogenic events of SVs with the cell plasma membrane mostly occurred at smooth and nonvillous regions of the cell surface. Taken together, our results suggest that binding and fusion of SVs with the cell plasma membrane might be dependent on interactions with specific membrane components that preferentially recognize negatively charged SVs.     

Quantitative studies on the viability of yeast protoplasts following dielectrophoresis

Abstract Protoplasts from Saccharomyces cerevisiae and Saccharomyces diastaticus were collected in a non-homogeneous alternating electric field. The dependence of the viability of the protoplasts on different conditions of collection was tested by determining the regeneration rates in each case. The parameters varied in collection were the field strength (0.33 kV/cm–6.67 kV/cm), the frequency of the alternating field (1–2 MHz) and the collection time (2–10 min). The introduction of a new type of fusion chamber (meander chamber) permitted, for the first time, quantitative exposure of protoplasts to the electric field as well as their complete transference into the regeneration medium. The regeneration rates of yeast protoplasts collected under those conditions employed for electrofusion did not differ from those of protoplasts which had been maintained under the same experimental conditions but were not subject to the influence of an alternating electric field. The two yeast strains were fused together (collection 1 kV/cm; pulse 15 kV/cm; duration of pulse 40 μs) and the fusion products were introduced into a selection medium for regeneration. The fusion rate was about 4.8 × 10⁻⁴; on average 272 colonies grew on the selection medium for each chamber filling.     

Phospholipid diversity: correlation with membrane-membrane fusion events

The transport of various metabolically important substances along the endocytic and secretory pathways involves budding as well as fusion of vesicles with various intracellular compartments and plasma membrane. The membrane-membrane fusion events between various sub-compartments of the cell are believed to be mainly mediated by so-called "fusion proteins". This study shows that beside the proteins, lipid components of membrane may play an equally important role in fusion and budding processes. Inside out (ISO) as well as right side out (RSO) erythrocyte vesicles were evaluated for their fusogenic potential using conventional membrane fusion assay methods. Both fluorescence dequenching as well as content mixing assays revealed fusogenic potential of the erythrocyte vesicles. Among two types of vesicles, ISO were found to be more fusogenic as compared to the RSO vesicles. Interestingly, ISO retained nearly half of their fusogenic properties after removal of the proteins, suggesting the remarkable role of lipids in the fusion process. In another set of experiments, fusogenic properties of the liposomes (subtilosome), prepared from phospholipids isolated from Bacillus subtilis (a lower microbe) were compared with those of erythrocyte vesicles. We have also demonstrated that various types of vesicles upon interaction with macrophages deliver encapsulated materials to the cytosol of the cells. Membrane-membrane fusion was also followed by the study, in which a protein synthesis inhibitor ricin A (that does not cross plasma membrane), when encapsulated in the erythrocyte vesicles or subtilosomes was demonstrated to gain access to the cytosol.     

Phospholipid diversity: Correlation with membrane-membrane fusion events

The transport of various metabolically important substances along the endocytic and secretory pathways involves budding as well as fusion of vesicles with various intracellular compartments and plasma membrane. The membrane-membrane fusion events between various sub-compartments of the cell are believed to be mainly mediated by so-called “fusion proteins”. This study shows that beside the proteins, lipid components of membrane may play an equally important role in fusion and budding processes. Inside out (ISO) as well as right side out (RSO) erythrocyte vesicles were evaluated for their fusogenic potential using conventional membrane fusion assay methods. Both fluorescence dequenching as well as content mixing assays revealed fusogenic potential of the erythrocyte vesicles. Among two types of vesicles, ISO were found to be more fusogenic as compared to the RSO vesicles. Interestingly, ISO retained nearly half of their fusogenic properties after removal of the proteins, suggesting the remarkable role of lipids in the fusion process. In another set of experiments, fusogenic properties of the liposomes (subtilosome), prepared from phospholipids isolated from Bacillus subtilis (a lower microbe) were compared with those of erythrocyte vesicles. We have also demonstrated that various types of vesicles upon interaction with macrophages deliver encapsulated materials to the cytosol of the cells. Membrane-membrane fusion was also followed by the study, in which a protein synthesis inhibitor ricin A (that does not cross plasma membrane), when encapsulated in the erythrocyte vesicles or subtilosomes was demonstrated to gain access to the cytosol.     

Microtubule arrays in regeneratingMougeotia protoplasts may be oriented by electric fields

Summary Initially non-polar protoplasts of the green algaMougeotia will regenerate to re-establish their original cylindrical cell shape. The orientation of the growth axis of regenerating protoplasts held in agarose was independent of both the direction of incident white light and gravity. Protoplasts elongated parallel to applied DC electric fields of approx. 0.2 Vcm^–1 (1 mV/protoplast) and greater, with an increasing percentage oriented with increasing field strength. At the maximum field strength used (10 mV/cell), 53% of protoplasts were oriented within +- 10° of the 0/180° axis of the field. In untreated controls, the orientation of elongation was random. Protoplast survival was unaffected by field treatment. Some protoplasts (up to 37% in 10 mV/cell fields) formed outgrowths towards the cathode and occasionally towards the anode. Regenerating protoplasts in fields displayed the normal sequence of microtubule reorganization. This means that the positioning of the ordered symmetrical array of microtubules centred on two foci that appears within 3 to 4 h, and the subsequent organization of microtubules by 8 to 12 h into a band that intersects both foci and which is transverse to the axis of elongation (Galway and Hardham 1986), may be controlled by externally applied electric fields. In the region of this microtubule band, the applied field causes the plasma membrane to be stretched parallel to the field (Bryant and Wolfe 1987). We suggest that microtubules may become oriented perpendicular to the direction of field-induced membrane stretching, and that membrane stretching may be one of the orienting mechanisms for membrane-linked microtubules in elongating plant cells.Abbreviations PBS phosphate buffered saline - PMM protoplast maintenance medium - DMM dilute maintenance medium - MES 2(N-morpholino)ethanesulfonic acid - TRIS tris(hydroxymethyl)aminomethane - ANOVA analysis of variance