Electrofusion of protoplasts from celery (Apium graveolens L.) with protoplasts from the filamentous fungus Aspergillus nidulans

A method was developed for electrofusion of higher-plant protoplasts from celery and protoplasts from the filamentous fungus Aspergillus nidulans. Initially, methods for the fusion of protoplasts from ecch species were determined individually and, subsequently, electrical parameters for fusion between the species were determined. Pronase-E treatment and the presence of calcium ions markedly increased celery protoplast stability under the electrical conditions required and increased fusion frequency with A. nidulans protoplasts. A reduction in protoplast viability was observed after electrofusion but the majority of the protoplasts remained viable over a 24-h incubation period. A small decline in protoplast respiration rate occurred during incubation but those celery protoplasts fused with A. nidulans protoplasts showed elevated respiration rates for 3 h after electrofusion.Abbreviations AC alternating current - DC direct current     

Comparative effects of fusion facilitators on electrofusion attributes of N. tabacum mesophyll protoplasts

Mesophyll protoplasts isolated from in vitro-grown Nicotiana tabacum L. shoots were subjected to electrofusion.Dielectrophoresis was induced by an AC field of 50 V cm^-1 inter-electrode distance and 0.5 MHz oscillation frequency. Fusion was effected by two 0.7 kV cm^-1 DC pulses, each of 50 s duration, applied within one second of each other. Various chemical treatments were tested for their effects on dielectrophoresis efficiencies (percentages of protoplasts that made contact with at least one other protoplast under the AC field), fusion efficiencies (percentages of protoplasts participating in fusion events), cell lysis (percentages of protoplasts bursting during the electrofusion processes), overall viabilities of fusion products 24 h post-fusion and overall plating efficiencies 7 d post-fusion (percentages of fusion-derived cells that had undergone division). The various attributes assessed on the electrofusion of protoplasts in the control treatment, 10% mannitol, differed considerably for experiments carried out on different days. Relative to the control treatment, only the Ca²⁺ treatments, and to a lesser extent lipase treatment reduced dielectrophoresis efficiencies. Polyamines, cytochalasins and Ca²⁺ treatments significantly reduced cell lysis percentages. All electrofusion facilitators tested (except for spermine at 150 mg l^-1, the cytochalasins B and D, and Ca²⁺ treatments) increased fusion efficiencies to more than 1.5 times those obtained with the standard 10% mannitol electrofusion medium. Ca²⁺ treatments increased overall viabilities of fusion products by more than 1.5 times. With the exception of the prostaglandins, lecithin and CaCl₂ treatments, overall plating efficiencies were reduced by treatment of protoplasts with fusion facilitators. Substantial increases in overall plating efficiencies over those observed in the control treatment were obtained using prostaglandin F_2a, lecithin and CaCl₂.2H₂O treatments. The implications of the results are discussed.Abbreviations AC alternating current, approx.-approximately - BA benzylaminopurine, cv.-cultivar - DC direct current, diam.-diameter - FDA fluorescein diacetate - MS Murashige & Skoog (1962) - NAA napthaleneacetic acid - PCM protoplast culture medium - PIM protoplast isolation medium - PPM protoplast purification medium - rpm revolutions per minute - SD(n) standard deviation of a variate - SEM standard error of the mean     

Modulation and direction of the electrofusion response in plant protoplasts

In experiments on electrofusion of protoplasts (from Solanum brevidens, S. tuberosum, Nicotiana plumbaginifolia) the presence of divalent cations (Ca²⁺) at 1 mM in the fusion medium was found to increase the yield of hybrids observed directly after fusion and decrease the duration of pulse needed for fusion. Pretreatment of protoplasts with the polyamine spermine also enhanced fusion yield, and when combined with 1 mM Ca²⁺ the effects were additive. The improvement in fusion yield (2–4 fold) was most marked for protoplast populations (e.g. from suspension cultured cells) that were least responsive to electrofusion in mannitol alone. Short term viability, judged from FDA fluorescence was found to be high at these increased fusion levels. Optimum fusion parameters for electrofusion thus may be determined from short term experiments. Attempts to direct to fusion response between populations of protoplasts of identical properties by pretreatment of one fusion partner with spermine were inconclusive.     

Factors affecting protoplast electrofusion efficiency

The electrofusion efficiency of protoplasts isolated from a carrot (Daucus carota) suspension culture was increased by treatment with 0.1 mg/ml lysolecithin, 2.5% dimethylsulfoxide (DMSO), or 0.5 mM Ca²⁺. The lysolecithin and DMSO treatments substantially increased protoplast lysis, whereas calcium treatment did not. The enzymes used for protoplast isolation were also found to have a dramatic effect on the efficiency of fusion. A mixture of Cellulysin and Driselase led to a two-fold enhancement of fusion as compared with Driselase alone. The stimulation by Cellulysin appears to be due to enzymatic modification of the cell surface. However, comparison of the time course for wall digestion with the development of susceptibility to electrofusion suggests that the effect of Cellulysin is not simply due to removal of the cell wall. Brief treatment of the cells with pronase or proteinase K also doubled the efficiency of fusion. Taken together, these results indicate that electrofusion efficiency can be enhanced by the method used for protoplast isolation; they also suggest that modification of membrane/cell-surface proteins during protoplast isolation may be particularly important in determining electrofusion efficiencies.Abbreviations a.c. alternating current - d.c. direct current - DMSO dimethylsulfoxide - NAA naphthaleneacetic acid - PEG polyethylene glycol     

Induction of fast-growing and morphologically different strains through intergeneric protoplast fusions of Ulva and Enteromorpha (Ulvales,Chlorophyta)

Isolated protoplasts of Ulva pertusa and Enteromorpha prolifera were electrically fused. Treatment of protoplasts in 1% protease for 15–20 min prior to fusion enhanced fusion ability. Protoplasts from each fusion partner were mixed together in 1:1 ratio in low conductivity electrofusion solution at a density of 1 × 10⁵ cells ml⁻¹ before subjecting them to electrofusion. The protoplasts were aligned in AC field (1MHz, 25 V for 10–15 s) and subsequently fused by a high intensity single DC pulse of 250 V for 25 μs duration. Fusion buffer supplemented with 1 mM calcium and 1 mM magnesium yielded optimum fusion frequencies (about 18–24%). Entrapment of fusion treated cells inside agarose/agar plate facilitated marking and regeneration of fusion products. The regeneration patterns of fused protoplasts were similar to normal (unfused) protoplast development. Most of the regenerated plants from fusion products had a thallus similar to either U. pertusa type or E. prolifera type. Although some of the plants of the former were morphologically similar to U. pertusa, but most had a higher growth rate (1.9 to 1.5 times) than U. pertusa. Furthermore the thallus of some plants had a characteristic irregular and dentate margin, which was never observed in the parental type.     

Uptake of protoplasts from the filamentous fungiAspergillus nidulans andFusarium oxysporum into protoplasts from celery (Apium graveolens L.)

Summary Protoplasts isolated from celery cell suspension cultures, were mixed with fungal protoplasts, from either the saprophytic speciesAspergillus nidulans or the pathogenic speciesFusarium oxysporum. The incubation of protoplast mixtures with PEG caused close adhesion between plant and fungal protoplasts. Subsequent dilution of PEG resulted in the uptake of protoplasts from either fungal species into the plant protoplast cytoplasm. A range of PEG concentrations, incubation times and dilution rates were tested to maximise adhesion and uptake frequencies. Identification of uptake was achieved either by fluorescent staining of nuclei or by electron-microscopy. A maximum of 10% celery protoplasts had taken upA. nidulans protoplasts after PEG treatment. Fungal protoplasts were taken up into celery protoplast cytoplasm by endocytosis, and were maintained within vesicles; two bounding membranes were observed by electron microscopy. Plant protoplast viability was determined during prolonged incubation following fungal protoplast uptake. The presence ofA. nidulans protoplasts tended to maintain celery protoplast viability and although some morphological disintegration occurred intact celery protoplasts remained for at least 92 h after uptake. The uptake ofF. oxysporum protoplasts markedly depressed celery protoplast viability after 24 h incubation and greater celery protoplast disintegration occurred.Abbreviations PEG Polyethylene glycol - DAPI 4,6-diaminido-2-phenylindole - 2,4-D 2,4-dichlorophenoxyacetic acid     

Electrofusion,a simple and reproducible technique in somatic hybridization of Nicotiana plumbaginifolia mutants

Electrofusion of protoplasts from two complementary nitrate reductase deficient mutants of Nicotiana plumbaginifolia has resulted in somatic hybrid lines. Mesophyll protoplasts isolated from the cofactor mutant CNX 20 and fluorescein diacetate stained protoplasts derived from a cell suspension culture of the NA 36 line, being defective in the apoenzyme, were used in the fusion experiments. In total, 594 lines were recovered which could proliferate on a selective medium with nitrate as the sole nitrogen source. This is including 141 putative hybrid lines which were obtained after transfer of 1048 heterokaryons with a micromanipulator one day after electrofusion. The hybrid character of some of the selected lines was confirmed by nitrate reductase activity measurements. Plants were grown from hybrid calli.Abbreviations NR nitrate reductase - FDA fluorescein diacetate - 2,4-D 2,4-dichlorophenoxyacetic acid - BAP benzylaminopurine - NAA naphthaleneacetic acid - NED N-1-naphtyl-ethylenediamide hydrochloride - PEG polyethylene glycol - AC alternating current - DC direct current     

Effects of Physical Parameters upon Protoplast Electrofusion

The effects of three physical parameters upon protoplast electrofusionwere studied using protoplasts from cultured cells of Coptisjaponica and Euphorbia millii. The osmotic potential of themedium did not appreciably affect the AC-field-induced protoplast-pairformation, but significantly influenced the fusion process ofthe paired protoplasts in response to DC pulses. The optimumosmotic potential was 0.55 to 0.60 Osm/kg H₂O in our system.The density of the medium markedly influenced both pair formationand fusion process. The optimum density was 1.13 to 1.14 g/cm₃,and at this density the yield of the fused protoplasts increasedto more than twice that of the control (1.10 g/cm₃). Hydrophiliccoating of the bottom surface of the chamber with Gellan gumor polyacrylamide gel was also effective for both pair formationand the fusion process, while coating with hydrophobic siliconewas entirely inhibitory. Possible interpretations of the effectsof these physical parameters upon protoplast electrofusion arepresented. ¹Permanent address: Biochemical Research Laboratories, KanegafuchiChemical Industry Co., Ltd., Takasago, Hyogo 676, Japan. (Received December 21, 1987; Accepted March 18, 1988)     

Optimization of Electrofusion Parameters and Interspecific Somatic Hybrid Regeneration in Citrus

This study was primarily attempted to optimize the electrofusion parameters using protoplasts isolated from cell suspension cultures of "Page" tangelo ( Citrus reticulata Blanco x C. paradisi Macf) and mesophyll protoplasts of rough lemon ( Citrus jambhiri Lush) as fusion partners. It was shown that the binuclear heterokaryons frequency reached 15% with the following parameters: alternate current (AC) 125 V/cm, AC time 60 s, direct current (DC) 1 250 V/cm, DC pulse width 50 μs, DC pulse interval O. 5 s, No. of DC pulse 3. Considering the fact that different types of protoplasts have different specific weights, higher frequency of the binuclear heterokaryons was obtained by controlling the centrifugation time after fusion. The fusion products regenerated into plantlets after 3 to 4 months of culture. Chromosome counting of the root tips and morphological observation of the regenerants verified that 78% were tetraploids and the rest were diploids with the leaf morphology of mesophyll parent. Peroxidase (POX) isozyme and RAPD analysis indicated that interspecific somatic hybrids were obtained and an autotetraploid plant of mesophyll parent type was also verified.     

Factors Influencing Protoplast Viability of Suspension-Cultured Rice Cells during Isolation Process

Callus cells of rice (Oryza sativa L.) that were actively dividing in suspension culture had lost the ability to divide during the isolation process of protoplasts. Factors influencing the protoplast viability were examined using highly purified preparations of cellulase C₁, xylanase, and pectin lyase, which were essential enzymes for the isolation of protoplasts from the rice cells. The treatment of the cells with xylanase and pectin lyase, both of which are macerating enzymes, caused cellular damage. Xylanase treatment was more detrimental to the cells. Osmotic stress, cell wall fragments solubilized by xylanase, and disassembly of cortical microtubules were not the primary factors which damaged the rice cells and protoplasts. The addition of AgNO₃, an inhibitor of ethylene action, to the protoplast isolation medium increased the number of colonies formed from the cultured protoplasts, although the yield of protoplasts was reduced by the addition. Superoxide radical (O₂-) was generated from the cells treated with xylanase or pectin lyase. The addition of superoxide dismutase and catalase to the protoplast isolation medium resulted in a marked improvement in protoplast viability especially when the non-additive control protoplasts formed colonies with a low frequency. The addition of glutathione peroxidase and phospholipase A₂, which have been known to reduce and detoxify lipid hydroperoxides in membranes, to the protoplast culture medium significantly increased the frequency of colony formation. These results suggested that some of the damage to rice protoplasts may be caused by oxygen toxicity.     

Protoplast isolation for species in the Chamelaucium group and the effect of antioxidant enzymes (superoxide dismutase and catalase) on protoplast viability

An effective protocol for protoplast isolation from young leaves and somatic embryogenic cells of species in the Chamelaucium group and the use of superoxide dismutase (SOD) and catalase (CAT) to enhance protoplast viability are described. Mesophyll protoplasts were isolated from young leaves of a white Geraldton waxflower (Chamelaucium uncinatum) line 583, using a mixture of 1% (w/v) cellulase R10, 0.5% (w/v) macerozyme R10, and 0.1% (w/v) pectolyase. Viability of isolated mesophyll protoplasts increased dramatically when SOD and CAT were added. The highest increase of 7.61-fold in viability and 4.34-fold of viable protoplast yield were achieved when a combination of SOD at 500 units mL^?1 and CAT at 2,000 units mL^?1 was added to the enzyme mixture. Somatic embryogenic cell-derived protoplasts were isolated from embryogenic suspension cells of C. uncinatum line 583 when 1% (w/v) hemicellulase was added to a combination of 2% (w/v) cellulase R10, and 1% (w/v) macerozyme R10. Addition of SOD at 500 units mL^?1 and CAT at 2,000 units mL^?1 to the enzyme mixture improved viability only slightly, to above 90%, but improved yield significantly (6.6-fold). This combination of enzymes was also used to isolate protoplasts from embryogenic suspension cells of Chamelaucium repens and from young leaves of C. uncinatum, Actinodium calocephalum, Verticordia etheliana, Verticordia grandis, Verticordia hughanii, and Verticordia mitchelliana successfully with viability >80% and viable yield >7?×?10⁵ cells g^?1 fresh weight (or per milliliter packed cell volume in the case of suspension cells).     

Fusion characteristics of plant protoplasts in electric fields

The electrical parameters important in the fusion of plant protoplasts aligned dielectrophoretically in high-frequency alternating electric fields have been established. Protoplasts were aligned in an alternating electric field between two relatively distant (1 mm) electrodes, by dielectrophoresis induced by field inhomogeneities caused by the protoplasts themselves. This arrangement allowed ease of manipulations, large throughput and low loss of protoplasts. In analytical experiments, sufficiently large samples could be used to study pulse duration-fusion response relations at different pulse voltages for protoplasts of different species, tissues and size (mesophyll protoplasts of Solanum brevidens, Triticum aestivum, Hordeum vulgare; suspension-culture protoplasts of Nicotiana sylvestris, N. rustica, Datura innoxia and S. brevidens; root-tip protoplasts of Vicia faba, hypocotyl protoplasts of Brassica napus). The percentage of aligned protoplasts that fused increased with increasing pulse parameters (pulse duration; voltage) above a threshold that was dependant on pulse voltage. The maximum fusion values obtained depended on a number of factors including protoplast origin, size and chain length. Leaf mesophyll protoplasts fused much more readily than suspension-culture protoplasts. For both types, there was a correlation of size with fusion yield: large protoplasts tended to fuse more readily than small protoplasts. In short chains (five protoplasts), fusion frequency was lower, but the proportion of one-to-one products was greater than in long chains (ten protoplasts). In formation by electrofusion of heterokaryons between mesophyll and suspension-culture protoplasts, the fusion-frequency response curves reflected those of homofusion of mesophyll protoplasts rather than suspension-culture protoplasts. There was no apparent limitation to the fusion of the smallest mesophyll protoplast with the largest suspension-culture protoplasts. Based on these observations, it is possible to direct fusion towards a higher frequency of one-to-one (mesophyll/suspension) products by incorporating low densities of mesophyll protoplasts in high densities of suspensionculture protoplasts and by using a short fusion pulse. The viability of fusion products, assessed by staining with fluorescein diacetate, was not impaired by standard fusion conditions. On a preparative scale, heterokaryons (S. brevidens mesophyll-N. sylvestris or D. innoxia suspension-culture) were produced by electrofusion and cultured in liquid or embedded in agar, and were capable of wall formation, division and growth. It is concluded that the electrode arrangement described is more suitable for carrying out directed fusions of plant protoplasts than that employing closer electrodes.     

Electrofusion of protoplasts from Aspergillus nidulans

Abstract Electrical parameters were determined and quantified for the stimulation of the optimum alignment and fusion of Aspergillus nidulans protoplasts. In a non-homogeneous alternating electrical field A. nidulans protoplasts aligned to form pearl chains associated with the electrodes of the fusion chamber. Most protoplasts were in pearl chains in an alignment field frequency of 3.0 MHz but maximum pair formation occurred at 1.0 MHz. At a field strength between 100 and 1000 V · cm⁻¹ pearl chain formation occurred with minimal protoplast rotation or lysis. The application of DC pulses resulted in protoplast fusion. Most fusion events were observed after two 500 V · cm⁻¹ DC pulses with a 0.5 s interpulse period. Using 1 × 10³ protoplasts · cm⁻³ in a 7 μm fusion chamber a maximum of 17.2 ± 2.0% fusion events were achieved.     

Interspecific hybrid plant formation by electrofusion in Nicotiana

Summary We obtained complete hybrid plants by electrofusion of mesophyll protoplasts from Nicotiana glauca and N. langsdorffii. Electrofocusing analysis of Fraction I proteins isolated from the leaves of these plants confirmed their hybridity. Cytological analysis indicated that the chromosome number (2n) of these plants is between 60 to 66, suggesting that they are the products of triple fusion. All plants were fertile and set viable seeds after self pollination. As we did not use an AC field for electrofusion, the present results indicate that an AC field is not essential for obtaining hybrid plants with electrofusion.     

INFLUENCE ON ELECTROFUSION BY ADSORPTION OF FLUORESCENT DEXTRAN ON PROTOPLAST MEMBRANES

In this paper, the influence of negatively charged active fluorescent dextran on electrofusion of barley protoplasts was investigated. We discovered that this biopolymer inhibits the electrofusion process. The adsorption of fluorescent dextran on membranes was determined by observing their fluorescence microphotograph in protoplast suspension. A green fluorescent ring appeared around the membrane. The adsorption phenomena were also investigated by measuring the influence of additives on electrophoresis of protoplasts. It was detected that the membrane of barley protoplasts had a negative charge. After being stored in solution containing fluorescent dextran, the protoplasts demonstrated increased relative mobility due to the increase of negative charge on membranes by adsorption. The mobility decreased when the protoplasts were pretreated in the solution containing positively charged substances Bardac 2080. The increase of the membrane's negative charge by adsorption F-DX enhances the repulsion between protoplasts, and therefore decreases the electrofusion yield.     

Factors affecting the electrofusion efficiency ofPorphyra protoplasts

The effects of various factors on the electrofusion efficiencies ofPorphyra protoplasts were investigated. These factors were protoplast stabilizing reagents, divalent cations, membrane digestive enzymes and cold storage of the protoplasts. Fusion efficiencies were dependent on the concentrations of reagents used to adjust the osmotic pressure of the medium. With mannitol or sorbitol the maximum fusion efficiency (approximately 16%) was observed at concentrations of 0.6 to 0.7 M; glucose was less effective. Brief treatment of the protoplasts with pronase stimulated electrofusion, whereas treatment with proteinase K, trypsin, phospholipase C or lipase repressed fusion. The addition of Ca²⁺ at 10^-5 to 10^-4 M in the protoplast medium enhanced the fusion efficiency to approximately four times that of the non-treated control. Sr²⁺ and Co²⁺ also stimulated electrofusion, but less effectively than Ca²⁺. The fusion capacity of the protoplasts remained stable for about 3 h when kept on ice, but decreased gradually when left at room temperate.     

Plant regeneration from protoplasts of Triticum aestivum L. cv. Nakasoushu

A fast-growing, small, granular, embryogenic callus was selected from primary calli induced from the Japanese wheat cultivar Nakasoushu and the Australian wheat cultivar Bodallin. Regenerable and fine suspension cultures were induced three to six months after liquid culture was initiated and were characterized by dense cytoplasm and active division. These suspension cultures routinely provided high yields of protoplasts with about 90% viability when incubated in a modified KMP (Kao and Michayluk, 1975) medium containing 1 mg l^-1 2,4-D (2,4-dichlorophenoxyacetic acid), and 1 mg l^-1 zeatin. Nakasoushu and Bodallin protoplasts divided at frequencies of 8.6% and 11.1%, respectively, in agarose-solidified media. When Nakasoushu protoplasts were cultured with effective nurse cells of sorghum and wheat, protoplast division increased to 16.9% and 12.6%, respectively. Plating efficiencies varied from 0.03% to 2.5%. After subculture, protocolonies yielded embryogenic calli and somatic embryos, from which green plants were eventually regenerated. Whole plants obtained from Nakasoushu protoplasts were fertile, demonstrating the first report of Japanese cultivars in wheat protoplast cultures. This revised version was published online in June 2006 with corrections to the Cover Date.     

Flow cytometric quantification of electroporation-mediated uptake of macromolecules into plant protoplasts

Summary Flow cytometry was used to provide a rapid and accurate assessment of electroporation-induced uptake of macromolecules into plant protoplasts. Rice protoplasts were electroporated in the presence of fluorescein isothiocyanate-conjugated dextran (FITC-dextran). After washing, the protoplasts were resuspended in a solution containing propidium iodide which intercalates with DNA, but which is excluded by an intact plasma membrane. Electroporation in the presence of FITC-dextran gave rise to populations of protoplasts that fluoresced green or yellow due to the presence of non-conjugated FITC. Non-viable protoplasts fluoresced red because of their inability to exclude propidium iodide molecules. Flow cytometry was used to resolve and quantify these protoplast populations and thus identify optimal conditions for macromolecule uptake. A direct relationship was observed between FITC-dextran uptake and transient gene expression following plasmid uptake. Thus, simultaneous electroporation of protoplasts with foreign DNA and FITC-dextran followed by fluorescence activated cell sorting may permit partial selection of transformed cells and so reduce the need for a selectable marker.Abbreviations ADC analogue to digital converter - CAT chloramphenicol acetyl transferase (enzyme) - cat chloramphenicol acetyl transferase (gene) - CPW solution cell and protoplast wash solution - DC direct current - EF electrofusion - FALS forward angle light scatter - FITC fluorescein isothiocyanate - FITC-dextran fluorescein isothiocyanate conjugated dextran - PI propidium iodide - PMT photomultipliertube - TLC thin layer chromatography     

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 5·10⁵ protoplasts (0.5 ml of cells at 10⁶/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.Abbreviations AC alternating current - DC direct current - PEG polyethylene glycol     

Determination of physical membrane properties of plant cell protoplasts via the electrofusion technique: prediction of optimal fusion yields and protoplast viability

By variation of physical parameters (field strength, pulse duration) which result in electrofusion and electroporation, properties of the plasma membrane of different types of plant cell protoplasts were analyzed. The lower threshold for that field pulse intensity at which membrane breakdown occurred (recorded as fusion event) depended on pulse duration, protoplast size, and protoplast type (tobacco, oat; vacuolated, evacuolated). This fusion characteristic of plant protoplasts can also be taken as a measure of the charging process of the membrane and allows thus a non-invasive determination of the time constant and the specific membrane capacitance. Although the fusion yield was comparable at pulse duration/field strength couples of, e.g., 10 s/1.5 kV*cm^–1 and 200 s/0.5 kV*cm^–1, hybrid viability was not. Rates of cell wall regeneration and cell division of tobacco mesophyll protoplasts were not affected but may have been increased at short pulse duration/high field strength. Plating efficiency, in contrast, was significantly decreased with longer pulse duration at low field strengths.