Conditions for induced fusion of fungal protoplasts in polyethylene glycol solutions.

Solutions containing polyethylene glycol MW 6000 (PEG) induced fusion of protoplasts of Penicillium chrysogenum. Balanced heterokaryons were formed by fusion of nutritionally complementing protoplasts. Heterokaryotic fusion products were obtained up to a frequency of 4% of the number of protoplasts, surviving the fusion treatment. Investigation of the conditions, necessary to achieve this high fusion frequency, showed that supplementing the PEG solution with Ca++ and adjustment to high pH gave the best results. Mechanisms of fusion of fungal protoplasts by PEG, calcium and alkaline pH are discussed in view of the obtained results.     

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.     

Conditions for induced fusion of fungal protoplasts in polyethylene glycol solutions

Solutions containing polyethylene glycol MW 6000 (PEG) induced fusion of protoplasts of Penicillium chrysogenum. Balanced heterokaryons were formed by fusion of nutritionally complementing protoplasts. Heterokaryotic fusion products were obtained up to a frequency of 4% of the number of protoplasts, surviving the fusion treatment. Investigation of the conditions, necessary to achieve this high fusion frequency, showed that supplementing the PEG solution with Ca⁺⁺ and adjustment to high pH gave the best results. Mechanisms of fusion of fungal protoplasts by PEG, calcium and alkaline pH are discussed in view of the obtained results.     

The influence of combined magnetic field on the fusion of plant protoplasts

The study of the influence of weak, alternating magnetic field, which was adjusted to the cyclotron frequency of Ca2+ and K+ ions, on the fusion of tobacco and soya protoplasts was carried out using the extra apparatus with ferromagnetic shield. An increase in the frequency of protoplasts fusion in 2-3 times and participation of calcium ions in the induction of protoplast fusion in weak alternating magnetic field have been established.     

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     

Culture and fusion of pollen protoplasts of Brassica oleracea L. var. italica with haploid mesophyll protoplasts of B. rapa L. ssp. pekinensis

Hybrid callus was formed from the successful protoplast fusion between pollen protoplasts of Brassica oleracea var. italica and haploid mesophyll protoplasts of Brassica rapa. The pollen protoplast isolation frequency in broccoli was highly related to the ratio of trinucleate pollens in the male gametophyte population. Large quantities of pollen protoplasts with high vigor could be isolated, and the isolation frequency reached up to 90% in 6.0-7.0 mm long flower buds with about 94.7% trinucleate-stage pollens. Pollen protoplasts could be collected and purified by discontinuous gradient centrifugation. In 1% Na-alginate embedding culture, cell divisions were observed but no further development was found. The haploid mesophyll protoplasts were isolated from in vitro haploid plants of B. rapa. Results strongly showed the variability in culturability of mesophyll protoplasts from different haploid lines. Both pollen protoplasts and haploid mesophyll protoplasts retained a stable round shape in the designed prefusion solution with an osmotic pressure of 0.74 osmol/kg. Polyethylene glycol was used for the protoplast fusion, and 40% polyethylene glycol 4000 enabled the highest fusion frequency of about 20%. Some postfusion protoplasts showed cell divisions up to callus proliferation. Calli were screened by random amplified polymorphic DNA analysis for their hybrid character. Results revealed the existence of the hybrid calli. Some of the hybrid calli grew well with green color and shoot primordia. According to our knowledge, this is the first report about a hybrid formation between two haploid protoplasts. Potential comprehensive applications, as well as problems of this technique, are discussed.     

Immunological evidence for transfer of the barley nitrate reductase structural gene to Nicotiana tabacum by protoplast fusion

Summary A protoplast fusion experiment was designed in which the selectable marker, nitrate reductase (NR), also served as a biochemical marker to provide direct evidence for intergeneric specific gene transfer. NR-deficient tobacco (Nicotiana tabacum) mutant Nia30 protoplasts were the recipients for the attempted transfer of the NR structural gene from 50 krad -irradiated barley (Hordeum vulgare L.) protoplasts. Barley protoplasts did not form colonies and Nia30 protoplasts could not grow on nitrate medium; therefore, selection was for correction of NR deficiency allowing tobacco colonies to grow on nitrate medium. Colonies were selected from protoplast fusion treatments at an approximate frequency of 10^-5. This frequency was similar to the Nia30 reversion frequency, and thus provided little evidence for transfer of the barley NR gene to tobacco. Plants regenerated from colonies had NR activity and were analyzed by western blotting using barley NR antiserum to determine the characteristics of the NR conferring growth on nitrate. Ten plants exhibited tobacco NR indicating reversion of a Nia30 mutant NR locus. Twelve of 26 regenerated tobacco plants analyzed had NR subunits with the electrophoretic mobility and antigenic properties of barley NR. These included plants regenerated from colonies selected from 1) co-culturing a mixture of Nia30 protoplasts with irradiated barley protoplasts without a fusion treatment, 2) a protoplast fusion treatment of Nia30 and barley protoplasts, and 3) a fusion treatment of Nia30 protoplasts with irradiated barley protoplasts. No barley-like NR was detected in plants regenerated from a colony that grew on nitrate following selfed fusion of Nia30 protoplasts. Because tobacco plants expressing barley-like NR were recovered from mixture controls as well as fusion treatments, explanations for these results other than protoplast fusionmediated gene transfer are discussed.     

Heterokaryon formation in the basidiomycete Schizophyllum commune by electrofusion of protoplasts

Summary Conditions for high frequency electrofusion of protoplasts from the basidiomycete Schizophyllum commune are described. Visual inspection revealed up to 30% of the protoplasts engaged in fusion. Using complementing nutritional mutations, nearly 7% of the regenerated protoplasts could be recovered as heterokaryotic mycelia. The method is probably equally applicable to other basidiomycetes such as Agaricus bisporus, permitting the recovery of fusion products in the absence of selection markers.     

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.     

Fusion of Agrobacterium and E. coli spheroplasts with Nicotiana tabacum protoplasts — Direct gene transfer from microorganism to higher plant

Spheroplasts of Agrobacterium tumefaciens strains and E. coli were fused with protoplasts of Nicotiana tabacum. Fusion products were cultured in the presence of antibiotics to eliminate remaining bacterial spheroplasts. On hormone free medium, tobacco protoplasts treated with wild type Agrobacterium-strains formed colonies with an average frequency of 10^–4. Opine synthesis was detected in the tissues. Some calli derived from protoplasts treated with A. tumefaciens C58C1pRi15834 formed typical hairy roots. Kanamycin resistant calli were obtained after fusion with A. tumefaciens containing pLGVTi23 neo (frequency=10^–3). Fusion of E. coli spheroplasts containing a virulent pTiB6S3::RP4 co-integrate with tobacco protoplasts yielded two hormone independent growing calli producing octopine out of 10⁵ microcalli.Abbreviations PEG Polyethylene glycol - PVA Polyvinyl alcohol     

Application of protoplast fusion technique to genetic recombination of Micromonospora rosaria

The optimum conditions for efficient formation and regeneration of Micromonospora rosaria protoplasts have been determined. The state of inoculum culture and stage of growth in a medium containing partially growth-inhibiting concentrations of glycine had significant effects on protoplasting. A high frequency of regeneration was accomplished with a hypertonic regeneration agar medium. A slight difference was found in the optimum culture age for formation and regeneration of protoplasts. Protoplast fusion was carried out using these optimum conditions. The recombinant frequency varied from 0.7 to 5.9% in the intraspecific crosses employing single and multiple auxotrophic markers. Electron microscopy showed stable and intact protoplasts when they were prepared with a hypertonic buffer. However, many protoplasts were shown to be damaged and many membraneous vesicles were observed when prepared in buffer without sucrose. The fusion process of protoplasts of Micromonospora was observed with the aid of electron microscopy.     

Visualization of protoplast fusion and quantitation of recombination in fused protoplasts of auxotrophic strains of Escherichia coli

Protoplast fusion has been used to combine genes from different organisms to create strains with desired properties. A recently developed variant on this approach, genome shuffling, involves generation of a genetically heterogeneous population of a single organism, followed by recursive protoplast fusion to allow recombination of mutations within the fused protoplasts. These are powerful techniques for engineering of microbial strains for desirable industrial properties. However, there is a prevailing opinion that it will be difficult to use these methods for engineering of Gram-negative bacteria because the outer membrane makes protoplast fusion more difficult. Here we describe the successful use of protoplast fusion in Escherichia coli. Using two auxotrophic strains of E. coli, we obtained prototrophic strains by recombination in fused protoplasts at frequencies of 0.05-0.7% based on the number of protoplasts subjected to fusion. This frequency is three-four orders of magnitude better than those previously reported for recombination in fused protoplasts of Gram-negative bacteria such as E. coli and Providencia alcalifaciens.     

Electron microscopic study of Bacillus subtilis protoplast fusion.

When protoplasts derived from sporulating cells of Bacillus subtilis were fused by exposure to polyethylene glycol (PEG) and fixed immediately thereafter, protoplasts with two enclosed prespores could be seen by electron microscope. The number of fusion events was greatly increased, and multiply fused protoplasts appeared, when the PEG-treated suspension was diluted in hypertonic broth and reincubated before fixation. This post-PEG incubation effect is taken to indicate a fusion mechanism of two steps: a short, PEG-dependent step of membrane activation, followed by a slow, metabolism-requiring step completing fusion. When prespore-bearing protoplasts from two genetically different strains were mixed and fused, the extent of fusion could also be followed by counting clones of recombinant bacteria. Maximal from the start, their number (1% of each parent type protoplast present) was unaffected by post-PEG incubation. Fusion in this case is apparently completed after plating on the wall-regeneration medium. After optimal post-PEG incubation, the majority of the protoplasts were seen to participate in fusion, and the cytological fusion observed, corrected for wall-regeneration frequency, accounted quantitatively for the prototrophic bacteria eventually recovered. These results are in good agreement with those obtained independently by Sanchez-Rivas and Garro (J. Bacteriol. 137:1340--1345, 1979).     

Fluorescent vital stains for complementary labelling of protoplasts from Trichoderma spp

In this study several fluorescent vital stains were evaluated for their ability to provide complementary vital staining of protoplasts of Trichoderma spp. for selection of heterokaryons following protoplast fusion. Tetramethyl rhodamine isothiocyanate and fluorescein isothiocyanate were rejected because they stained only a small proportion of protoplasts. Fluorescein diacetate stained all protoplasts, but the chromophore leaked rapidly from stained cells. A mixture of FluoroBora T and acriflavine stained all cells, but intensity was low and fading upon illumination was rapid. Nile red stained lipid bodies in all cells, but the stain was lost upon protoplast fusion in polyethylene glycol. Rhodamine 6G, on the other hand, stained all cells, fluoresced green, and was stable through fusion and upon illumination. Hydroethidine also stained all protoplasts, and staining was relatively stable through fusion and upon illumination. Hydroethidine fluoresced red and stained nuclei more prominently than the cytoplasm. Rhodamine 6G and hydroethidine were tested on a number of strains to determine whether they were toxic to protoplasts. No toxicity to any strain was noted with rhodamine 6G. Hydroethidine, however, was toxic at the higher concentrations tested, especially when stained protoplasts were exposed to light. When protoplasts were stained with the minimum concentration giving ready visualization and were incubated in darkness, hydroethidine also was nontoxic. Hydroethidine and rhodamine 6G are useful complementary vital stains of Trichoderma protoplasts for visualization of frequency and type (dicell, multicell) of fusion.     

Fluorescent Vital Stains for Complementary Labelling of Protoplasts from Trichoderma Spp

In this study several fluorescent vital stains were evaluated for their ability to provide complementary vital staining of protoplasts of Trichoderma spp. for selection of heterokaryons following protoplast fusion. Tetramethyl rhodamine isothiocyanate and fluorescein isothiocyanate were rejected because they stained only a small proportion of protoplasts. Fluorescein diacetate stained all protoplasts, but the chromophore leaked rapidly from stained cells. A mixture of FluoroBora T and acriflavine stained all cells, but intensity was low and fading upon illumination was rapid. Nile red stained lipid bodies in all cells, but the stain was lost upon protoplast fusion in polyethylene glycol. Rhodamine 6G, on the other hand, stained all cells, fluoresced green, and was stable through fusion and upon illumination. Hydroethidine also stained all protoplasts, and staining was relatively stable through fusion and upon illumination. Hydroethidine fluoresced red and stained nuclei more prominently than the cytoplasm. Rhodamine 6G and hydroethidine were tested on a number of strains to determine whether they were toxic to protoplasts. No toxicity to any strain was noted with rhodamine 6G. Hydroethidine, however, was toxic at the higher concentrations tested, especially when stained protoplasts were exposed to light. When protoplasts were stained with the minimum concentration giving ready visualization and were incubated in darkness, hydroethidine also was nontoxic. Hydroethidine and rhodamine 6G are useful complementary vital stains of Trichoderma protoplasts for visualization of frequency and type (dicell, multicell) of fusion.     

Fusion of meiotic protoplasts in liliaceous plants

A method is reported for the induction of a high frequency of fusion in meiotic protoplasts from two species of liliaceous plants. The yields of fused protoplasts were 50 to 90% from the prophase and 30 to 60% from the metaphase I or later. Fusion was induced with rapid isolation of protoplasts followed by rapid production of the naked cell-to-cell contact.     

In vitro fertilization of single,isolated gametes of maize mediated by electrofusion

Summary Electrofusion-mediated in vitro fertilization of maize using single sperm and egg cells was performed. Sperm cells were released from pollen grains after rupture of the latter by osmotic shock in the fusion medium (0.55 M mannitol). Egg cells were isolated by enzyme treatment (pectinase, pectolyase, hemicellulase, and cellulase) followed by mechanical isolation. The conditions generally used for the electrical fusion of protoplasts of somatic cells were also applied to the protoplasts of gametic cells of maize. Electrofusion was performed with single pairs of gametes under microscopic observation. The mean fusion frequency was 79%. Isolated egg cells of maize showed protoplasmic streaming during 22 days of culture, but they did not divide. However, after fusion of the sperm with the egg cells, these fused cells did develop, with a mean division frequency of 83%, and grew to multicellular structures. Egg cells and fusion products were cultivated with a maize feeder-cell system.     

A method for production of interspecific hybrids within Brassiceae via somatic hybridization,using resynthesis of Brassica napus as a model

A general method for the production of somatic hybrids within Brassiceae has been developed using mesophyll protoplasts from one parent and hypocotyl protoplasts from the other. Fusion products were easily identified by their intermediate phenotype between the parental protoplasts. They could be isolated 24 h after fusion with micropipettes using a micromanipulator. At that time their frequency was about 15%. They were cultured in small volumes, 10 μl, and a plating efficiency of 14% was obtained. Hybrid calli were obtained from the fusion products, which was confirmed by isozyme analysis. Ploidy level of one hybrid shoot was determined by flow cytometric DNA analysis.     

New cell fusion method using polymer membrane

A porous polymer membrane of nitrocellulose or tetrafluoroethylene (TFE) was employed for fusion of Saccharomyces cerevisiae (AH22 and D13-1A) protoplasts. Protoplasts were adsorbed on the membrane with slight suction. Some part of the protoplasts was trapped in pores of the membrane as observed by electron microscopy. The membrane retaining protoplasts was placed on a selective medium. Several colonies appeared on the medium after 5-7 days incubation at 30 degrees C. The fusion of the two strains was ascertained by DNA content and genetic markers. Fusion frequency was 1.2 X 10(-6) in the case of the TFE membrane.     

Effects of Microgravitation on Electrofusion of Plant Cell Protoplasts

Electrofusion of evacuolated with vacuolated mesophyll protoplasts of Nicotiana tabacum was performed as part of the German Sounding Rocket Program (TEXUS 17, 1988). The results indicate a significant increase not only in the yield of 1:1 hybrids, but also in homo- and multifusion products. Hybrids obtained under microgravity have been shown to be viable to a higher degree with respect to their ability for light-dependent O₂-evolution (independent of other substrates than bicarbonate). This finding is of interest for fusion experiments were only limited numbers of fusion partners are available (e.g. protoplasts from embryogenic tissues) or where fusion yields are extemely low under 1 × gravity (e.g. protoplasts of different specific density).