Somatic hybridization in higher plants

Summary Somatic hybridization in higher plants has come into focus since methods have been established for protoplast fusion and uptake of foreign DNA and organelles by protoplasts. Polyethylene glycol (PEG) was an effective agent for inducing fusion. Treatment of protoplasts with PEG resulted in 5 to 30% heterospecific fusion products. Protoplasts of different species, genera and even families were compatible when fused. A number of protoplast combinations (soybean + corn, soybean + pea, soybean + tobacco, carrot + barley, etc.) provided fusion products which underwent cell division and callus formation. Fusion products initially were heterokaryocytes. In dividing heterokaryocytes, random distribution of mitotic nuclei was observed to be accompanied by multiple wall formation and to result in chimeral callus. Juxtaposition of mitotic nuclei suggested nuclear fusion and hybrid formation. Fusion of heterospecific interphase nuclei was demonstrated in soybean + pea and carrot + barley heterokaryons. Provided parental protoplasts carry suitable markers, the fusion products can be recognized. For the isolation and cloning of hybrid cells, fusion experiments must be supplemented with a selective system. Complementation of two nonallelic genes that prevent or inhibit growth under special culture conditions appears as the principle on which to base the selection of somatic hybrids. As protoplasts of some species have been induced to regenerate entire plants, the development of hybrid plants from protoplast fusion products is feasible and has already been demonstrated for tobacco. Presented in the formal symposium on Somatic Cell Genetics at the 27th Annual Meeting of the Tissue Culture Association, Philadelphia, Pennsylvania, June 7–10, 1976.     

Somatic hybridization in higher plants.

Somatic hybridization in higher plants has come into focus since methods have been established for protoplast fusion and uptake of foreign DNA and organelles by protoplasts. Polyethylene glycol (PEG) was an effective agent for inducing fusion. Treatment of protoplasts with PEG resulted in 5 to 30% heterospecific fusion products. Protoplasts of different species, genera and even families were compatible when fused. A number of protoplast combinations (soybean + corn, soybean + pea, soybean + tobacco, carrot + barley, etc.) provided fusion products which underwent cell division and callus formation. Fusion products initially were heterokaryocytes. In dividing heterokaryocytes, random distribution of mitotic nuclei was observed to be accompanied by multiple wall formation and to result in chimeral callus. Juxtaposition of mitotic nuclei suggested nuclear fusion and hybrid formation. Fusion of heterospecific interphase nuclei was demonstrated in soybean + pea and carrot + barley heterokaryons. Provided parental protoplasts carry suitable markers, the fusion products can be recognized. For the isolation and cloning of hybrid cells, fusion experiments must be supplemented with a selective system. Complementation of two non-allelic genes that prevent or inhibit growth under special culture conditions appears as the principle on which to base the selection of somatic hybrids. As protoplasts of some species have been induced to regenerate entire plants, the development of hybrid plants from protoplast fusion products is feasible and has already been demonstrated for tobacco.     

Genetic recombination by protoplast fusion inNocardia asteroides

Summary Fusion and regeneration of protoplasts ofNocardia asteroides strains ATCC 3318, IMRU W3599 and HIK B971 have been used to study genetic recombination in this species. Protoplasts were produced by treatment with lysozyme, following incubation with glycine. Mutants of ATCC 3318 were grown in peptone yeast extract medium at 32°C prior to protoplast production to maximize protoplast frequency, whereas mutants of IMRU W3599 and HIK B971 were grown in trypticase-soy broth. Glycine concentrations favoring protoplast formation varied from 1.5% to 5% depending on strain. For all strains, protoplast formation was complete 1 h after addition of 5 mg/ml lysozyme. Protoplasts were fused by addition of 50% polyethylene glycol-1000. In general, 25% of the protoplasts could be regenerated. The incidence of recombinant recovery was increased up to 750-fold. The distribution of recombinant phenotypes in matings was similar for protoplast fusion and conventional crosses.     

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.     

Genetic recombination in Micromonospora rosaria by protoplast fusion

Auxotrophic strains of Micromonospora rosaria were isolated by N-methyl-N'-nitro-N'-nitrosoguanidine mutagenesis and used in intraspecific recombination by protoplast fusion. High-frequency fusion of protoplasts of M. rosaria strains was induced by polyethylene glycol (molecular weight, 1,000) (PEG 1,000). The optimum concentration of PEG 1,000 for fusion of M. rosaria was 50% (wt/vol). PEG 4,000 was slightly better than PEG 1,000 at concentrations lower than 50% (wt/vol). The recombinant frequency did not increase after treatment with PEG 1,000 (50% [wt/vol]) for longer than 20 min. Under these conditions, fusion with many auxotrophic strains of M. rosaria resulted in a high frequency of formation of true recombinants (sometimes more than 10%). Additionally, when ros (rosamicin nonproducing) strains were crossed by protoplast fusion; about 5% of the resultant prototrophic recombinants were shown to have the ros+ (rosamicin producing) characteristic restored. Rosamicin production by M. rosaria colonies was clearly distinguished by the broth overlay method. The results of fusion experiments between ros and ros+ strains indicated that either the chromosomal mutation or pleiotrophic effect of some auxotrophic markers is involved.     

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.     

Genetic recombination in Micromonospora rosaria by protoplast fusion.

Auxotrophic strains of Micromonospora rosaria were isolated by N-methyl-N'-nitro-N'-nitrosoguanidine mutagenesis and used in intraspecific recombination by protoplast fusion. High-frequency fusion of protoplasts of M. rosaria strains was induced by polyethylene glycol (molecular weight, 1,000) (PEG 1,000). The optimum concentration of PEG 1,000 for fusion of M. rosaria was 50% (wt/vol). PEG 4,000 was slightly better than PEG 1,000 at concentrations lower than 50% (wt/vol). The recombinant frequency did not increase after treatment with PEG 1,000 (50% [wt/vol]) for longer than 20 min. Under these conditions, fusion with many auxotrophic strains of M. rosaria resulted in a high frequency of formation of true recombinants (sometimes more than 10%). Additionally, when ros (rosamicin nonproducing) strains were crossed by protoplast fusion; about 5% of the resultant prototrophic recombinants were shown to have the ros+ (rosamicin producing) characteristic restored. Rosamicin production by M. rosaria colonies was clearly distinguished by the broth overlay method. The results of fusion experiments between ros and ros+ strains indicated that either the chromosomal mutation or pleiotrophic effect of some auxotrophic markers is involved.     

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.     

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.     

Antibiotic production by variants of Penicillium chrysogenum isolated after protoplast formation and exposure to mutagens at the protoplast stage

A procedure for protoplast formation in the penicillin-producing organism Penicillium chrysogenum was developed. The yield of the protoplasts was high, the protoplasts were stable and capable of regeneration. Two types of the protoplast regeneration were revealed. The spores and protoplasts were treated with UV light and N-nitroso-N'-methyl biuret and their effect on production of the antibiotic by the isolated variants was studied. It was shown that the protoplasts of P. chrysogenum were more liable to the mutagenic effect of UV light and nitroso methyl biuret than the fungus conidia. It is possible to use this specific feature in intensification of selection aimed at isolation of highly productive strains of P. chrysogenum.     

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.     

Intracellular calcium and calmodulin involvement in protoplast fusion

(45)Ca(2+) uptake was compared between fusogenic and nonfusogenic Daucus carota L. protoplasts. Fusogenic protoplasts took 10 minutes to reach calcium equilibrium compared to 5 minutes in the nonfusogenic protoplasts. Intracellular stores of calcium were manipulated by isolating protoplasts in different calcium regimes. Lowering of intracellular calcium lowered fusion potential, while raising intracellular stores of calcium enhanced fusion potential. Regardless of the amount of calcium sequestered in a store, mobilization with A23187 increased fusion levels within 10 minutes. Calmodulin antagonists were potent inhibitors of protoplast fusion. This inhibition was obtained by treating cells with the calmodulin antagonists during protoplast isolation. A23187, however, only allowed a partial recovery from this inhibition, indicating that calcium flux alone was not sufficient for maximum fusion potential. On the basis of the evidence presented, we propose that calcium fluxes during protoplast isolation activate a calmodulin-mediated biochemical process that is necessary for the formation or maintenance of a fusion permissive state.     

Formation, Fusion, and Regeneration of Protoplasts from Wild-Type and Auxotrophic Strains of the White Rot Basidiomycete Phanerochaete chrysosporium

A preparation of two commercial enzymes was used to liberate protoplasts from 16-h-old mycelium of Phanerochaete chrysosporium. Regeneration frequencies of up to 5% were attained when the protoplasts were plated in a medium containing 10% sorbose and 3% agar. Fusion of protoplasts from different auxotrophic strains in polyethylene glycol-Ca²⁺ produced heterokaryons. Separation of the heterokaryons into their constituent homokaryotic strains could be effected through protoplast release and formation of colonies on regeneration agar.     

Protoplast fusion in Streptomyces fradiae strains producing neomycin and tylosin]

Interspecies fusion of protoplasts of the Streptomyces fradiae strains producing neomycin (an aminoglycoside antibiotic) and tylosin (a macrolide antibiotic) was performed with a view to isolate strains producing novel antibiotics. Fusion of the protoplasts of the neomycin- and tylosin-producing strains labelled by the resistance to monomycin and lincomycin, respectively, caused no formation of stable strains producing antibiotics differing in chromatographic mobility from the antibiotics produced by the initial strains. In fusion of the protoplasts of the unlabelled strains, heat-inactivated protoplasts of the active line of one strain (donor) and native protoplasts of the inactive line of the other strain (recipient) were used. When the neomycin-producing culture was used as a recipient the fusion led to formation of strain 195-34 producing antibiotics of the benzo(a)anthraquinone group. One of these antibiotics, i.e. antibiotic 34-I, proved to be a novel biologically active substance. After regeneration of the protoplasts of the initial strains, no stable strains producing antibiotics differing from neomycin and tylosin were isolated.     

Plasmid transfer and genetic recombination by protoplast fusion in staphylococci.

The experimental conditions for plasmid transfer and genetic recombination in Staphylococcus aureus and some coagulase-negative staphylococci by protoplast fusion are described. Protoplasts were prepared by treatment with lysostaphin and lysozyme in a buffered medium with 0.7 to 0.8 M sucrose. Regeneration of cell walls was accomplished on a hypertonic agar medium containing succinate and bovine serum albumin. Transfer of plasmids occurred after treatment of the protoplast mixtures with polyethylene glycol (molecular weight, 6,000) not only between strains of the same species but also between parents of different species, although at approximately 100 times lower frequency in the latter case. Recombination of the chromosomal genes in fused protoplasts required simultaneous treatment of the mixed protoplasts with polyethylene glycol and CaCl2. A method was developed for isolation of recombinants after fusion between mutants of S. areus carrying unselectable markers. Antibiotic resistance plasmids were introduced into the parental strains and used as primary markers to detect protoplast fusion. Chromosomal recombinants were found among the clones with both parental plasmids at a high frequency. The method appears to have simple applications in the construction of strains with multiple mutant characters.     

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.     

Protoplast Fusion of Lactobacillus casei

Lactobacillus casei ATCC 7469 was successfully converted to protoplasts by treatment with endo-7V-acetyl muramidase in sucrose phosphate buffer. For full hydrolysis of cell walls, a high concentration of sucrose and a cold shock were necessary. Mg²⁺ ions enhanced the stability of protoplasting cells. The cell wall regeneration of protoplasts was more effective on gelatin-induced regeneration medium than with the soft overlay method. The optimal concentration of gelatin was 2.5%. The frequency of regeneration was found to be about 6% for the protoplast prepared by enzyme treatment for 20 min. The mutants having streptomycin resistance and rifampicin resistance, as selection markers for the detection of fusion, were isolated by UV irradiation and NTG treatment. These mutants were stable for at least several transfers. Protoplast fusion was carried out using PEG (50% solution of polyethyleneglycol, M.W. 6,000). The frequency of protoplast fusion was found to be about 10^-5.     

Identification of somatic hybrids in plant protoplast fusions with monoclonal antibodies to plasma-membrane antigens

Monoclonal antibodies generated by immunization with a plasma-membrane preparation from suspension-cultured cells of Nicotiana glutinosa L. were used in combination with fluoresceinor rhodamine-labeled goat anti-mouse immunoglobulins to identify heterokaryons in protoplast fusion procedures. Antibody labeling did not inhibit callus formation nor plantlet regeneration. The antibodies are non-invasive and surface labeling provides clear optical discrimination of true heterokaryons from unfused aggregates as well as from parental protoplasts and homokaryons. Labeling is stable throughout fusion and hence by pre-labeling parental protoplast populations the strategy is both versatile and of general applicability.     

Genetic interactions in Streptomyces rimosus mediated by conjugation and by protoplast fusion

The development of a protoplast fusion technique for oxytetracycline-producing Streptomyces rimosus strains, and its evaluation for the application for a breeding programme, has been described. Treatment of S. rimosus protoplasts with 40% (w/v) PEG 1550 for 30 min gave optimal numbers of recombinants ranging from 1 to 10% of the total progeny. Therefore, by comparison with conjugation, protoplast fusion increased the frequency of recombination by two to three orders of magnitude. The proportion of multiple crossover classes amongst recombinants was higher, by a factor of ten, after protoplast fusion (13.3%) than after conjugation (1.5%). Participation of less frequent complementary genotype doubled from 9.0% in conjugation to 17.9% in protoplast fusion. Overall, this suggested that the opportunities for crossing over in a fusion of S. rimosus protoplasts were spatially and/or temporally extended leading to a loosening of linkage with a near-random assortment of genotypes in a cross. However, by minimizing the multiple crossover classes and calculating allele frequency gradients, it was shown that the protoplast fusion technique allows arrangement of genetic markers on the S. rimosus chromosome. These are ideal characteristics for the recombination of divergent lines in a strain improvement programme.     

用灭活原生质体融合进行高温香菇育种——Ⅰ.融合产物的选出及其鉴定

用灭活的近裸香菇(Lentinus subnudus Berk.)双核菌株原生质体与香菇[L. edodes(Berk.)Sing.]双核菌株原生质体融合,在35℃的条件下选得融合子。融合频率为0—4.3×10~(-5)。融合子与双亲有明显的拮抗性。融合子的菌丝形态、氨基酸含量,子实体的形态,以及酸性磷酸酶同功酶的测定都与双亲不同。