Parameters governing bacterial regeneration and genetic recombination after fusion of Bacillus subtilis protoplasts.

Bacterial protoplast fusion, induced by polyethylene glycol, has been made more regular and convenient by further specification and improvement of various steps in the previously used procedure. These have made it possible to obtain regularly 100% regeneration of Bacillus subtilis cells from protoplasts before treatment with polyethylene glycol and yields of 10 to 75% from polyethylene glycol-treated protoplasts. Genetic recombination frequencies do not increase correspondingly. Also, when regeneration is reduced by various experimental conditions, recombination does not decrease in proportion. It is concluded that regeneration of recombinant-forming cells is independently determined and not closely related to the average regeneration for the population. Kinetic studies with varying individual parental or total protoplast concentrations strongly indicate that protoplast collision and contact is not the limiting factor determining the number of genetic recombinants obtained. Recombination approximates a linear, rather than quadratic, function of the total or of the majority protoplast population present, from which it is concluded that fusion events are always adequate to produce substantially more potential recombinants than are registered. The strong effect of the majority/minority ratio upon the number of minority cells that become recombinant is independent of which parent is in excess. This shows in a direct and physiological way that both parents are equivalent partners in their genetic contributions.     

Interspecific recombinants of Bacillus thuringiensis x Bacillus cereus

The possibility of interspecies recombination was shown by using protoplast fusion method. The Bacillus thuringiensis var. galleriae strain 48S Thi Nic Gua Rifr Strr and 56R Gua Rifr, and also Bac. cereus carrying the plasmid pBC16 responsible for resistance to tetracycline (150 mcg/ml) were used. Recombinants were selected on the medium containing rifampicin and tetracycline. They were shown to combine the properties of both parents. The majority of recombinants were resistant to phages Tg4 and Td15 and represented the mean level of sensitivity to phages Tg12, Tg13 and Td14. Examination of the plasmid profiles of recombinants revealed that their resistance to tetracycline was due to the plasmid with mobility analogous to pBC16. It was concluded that the protoplast fusion method can be used to obtain recombinants between relatively remote species of microorganisms.     

Fusion of protoplasts in Streptomyces antibioticus

The analysis of Streptomyces antibioticus recombinants isolated under non-selective conditions for stability of inheritance of parental properties demonstrated the existence of non-stable diploids and stable haploid recombinants. Also, genetic analysis of heteroclones isolated on selective medium after plating spores of regenerants was conducted. The results of analysis of haploid recombinant and heteroclones pointed to linkage of genetic loci and the possibility to use the technique of protoplast fusion for establishment of genetic map of S. antibioticus.     

Polyethylene glycol-induced fusion of heat-inactivated and living protoplasts of Bacillus megaterium.

Protoplasts of Bacillus megaterium, incubated at 50 degrees C for 120 min, lost the ability to revert to bacillary form. Such heat-inactivated protoplasts, however, produced recombinants when fused by polyethylene glycol treatment with normal protoplasts. Although this differential inactivation effect is not yet fully reproducible, reciprocal inactivations of the parental protoplasts in genetic crosses have clearly shown that for protoplast fusion (i) either of the parents may serve as the viable recipient for markers coming from the heated parental protoplasts, and (ii) either of the parents may be rendered nonviable and yet, when fused with a viable partner, contribute to formation of a recombinant. Heat inactivation seems to provide a way to counterselect when few markers are available and one of the parents is prototrophic.     

Genetic analysis of fusion recombinants and presence of noncomplementing diploids in Bacillus megaterium

We have attempted to undertake genetic analysis in Bacillus megaterium using the technique of protoplast fusion that has been successfully applied in Staphylococcus and Streptomyces. Efficient production of protoplasts, fusion and regeneration techniques have been established. However, variability in numbers and types of recombinants using two-, three-, and four-factor crosses was observed throughout these studies. No linkages were detected, even between loci known to be linked by cotransduction with bacteriophage MP13. These results were similar to those reported by Alf?ldi and coworkers using B. megaterium strain 216, even though the experimental design was significantly changed. During initial subculturing, segregants were observed in a 1:2:2 ratio of noncomplementing diploids:parental-1:parental-2. The ratio changed dramatically after seven subcultures. Double recombinants appeared after nine subcultures. These results corroborate those reported in B. subtilis and suggest that there is a locus-inactivation phenomenon present in Bacillus which is not evident in Streptomyces or Staphylococcus. Until the mechanism is elucidated, protoplast fusion should not be used for chromosomal mapping in B. megaterium. However, it can be used to transfer plasmids among the bacilli at a frequency of 10(-5)-10(-6) per regenerated protoplast.     

Genetic Analysis of Fusion Recombinants in Bacillus Subtilis: Function of the Rece Gene

Bacillus subtilis protoplast fusion allows the study of the genetic recombination of an entire procaryotic genome. Protoplasts from bacterial strains marked genetically by chromosomal mutations were fused using polyethylene glycol and the regenerated cells analyzed. Recombinants represent 19.3% of heterozygotic cells; they are haploids. Individual characterization of clones show a unique particular phenotype in each colony suggesting that recombination takes place immediately after fusion, probably before the first cellular division. Recombination occurs in the whole chromosome; in one-third of the cases both reciprocal recombinants could be shown in the colony. The genetic interval that includes the chromosome replication origin shows the highest recombination level. Our results suggest that the RecE protein accounts for most of the fused protoplast recombination; however, some "replication origin-specific" recombination events were independent of the recE gene product.     

Bacterial protoplast fusion: recombination in fused protoplasts of Streptomyces coelicolor

Summary Numerous recombinants arose when protoplasts of S. coelicolor were treated with polyethylene glycol and regenerated on non-selective solid medium. In six-factor crosses, recombination frequencies of more than 10% (up to 17%) were routinely observed. This recombination did not require either of the known sex factors, SCP1 and SCP2.The proportion of multiple crossover classes was much higher than amongst recombinants produced by conjugation between mycelia. Analysis of the spatial distribution of crossovers in double and quadruple crossover recombinants showed only a slight tendency for crossovers to occur closer together than randomly on the complete linkage group. This suggests that genomes brought together by protoplast fusion are complete, or nearly so (in conjugation, in contrast, one genome is represented by a comparatively short fragment). Individual colonies arising from fused protoplasts did not contain different parental genomes without recombinants, but recombinants often occurred without parentals. Several recombinant genotypes often occurred in the same colony, showing a segregation of some, only, of the parental alleles. Complementary genotypes, parental or recombinant, did not occur in the same colony. It is postulated that complete genomes of fused protoplasts usually become fragmented and that crossing-over, often repeated, occurs between the fragments, to generate haploid recombinants.Analysis of fusions between protoplasts of four different genotypes indicated that the average number of protoplasts fusing together was low, but nevertheless appreciable numbers of fusions involved three or four genomes. Crossing-over between them produced recombinants inheriting markers from three or four parents.The generation of nearly random populations of recombinants between two or more parent strains by protoplast fusion under the conditions described appears to have simple applications in industrial and academic strain construction.     

Fusing plant protoplasts

As a result of improvements in regeneration of whole plants from isolated protoplasts and improvements in protoplast fusion technology, more new somatic hybrids plants are being produced. Both bulk electrofusions and microfusion of selected protoplast pairs are being applied to produce new combinations of genetic material. Practical application of this technology is leading to field testing of somatic hybrid plants.     

The interaction of Bacillus protoplasts with sonicated phosphatidylcholine liposomes

When protoplasts from Bacillus subtilis are incubated with sonicated liposomes made from egg-yolk phosphatidylcholine, this phospholipid is incorporated into the protoplast membranes. Biochemical, fluorescence and ultrastructural data suggest that incorporation occurs through membrane fusion.     

Direct selection of complementing diploids from PEG-induced fusion of Bacillus subtilis protoplasts

Summary A minimal medium containing horse serum is described on which Bacillus subtilis protoplasts revert to bacillary forms at high frequency (ca. 30%). Used as a plating medium for a mixture of polyethyleneglycol-treated protoplasts from two complementary polyauxotrophic parental strains, it selects the prototrophic fusion products efficently, and also allows isolation of various auxotrophic recombinants. These prototrophs and recombinants amount respectively to 1% and 10% of the regenerated bacteria.We confirm that two types of prototrophs can be isolated after fusion: stable recombinants and complementing diploids, the latter segregating into various types of recombinants. Based on easily recognized colonial aspects, an approximate estimation of the proportion of the two types becomes possible when a spoOA mutation has been introduced in one of the parents. At least 50% of the prototrophic fusion products are complementing diploids. Incidently, the data also settle a controversy by showing the dominance of spoOA mutations in heterozygotic bacteria.This work was supported by the Centre National de la Recherche Scientifique (Contrat L.A. 136).     

Factors affecting recombinant frequency in protoplast fusions of Streptomyces coelicolor.

The optimum concentration of polyethylene glycol 1000 (PEG) for the production of recombinants through protoplast fusion in Streptomyces coelicolor was about 50% (w/v). The addition of 14% (v/v) dimethyl sulphoxide to the fusion mixture enhanced recombination frequencies, but only at sub-optimal PEG concentrations. After treatment of protoplasts with 50% PEG for 1 min, the frequency of recombinants in a multi-factor 'cross' sometimes exceeded 20% of the total progeny. The frequency of recombinants in the progeny could be significantly enhanced by ultraviolet irradiation of the parental protoplast suspensions immediately before fusion.     

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.     

The localization of SPO1 phage resistance in the genome of Bacillus subtilis as revealed by fusion of protoplasts

We localized the gene for resistance to phage SPO1 relatively to the markers pur B 34 and ura by means of the polyethylene-glycol induced fusion of bacterial protoplasts of three-fold auxotrophic Bacillus subtilis strains S3 and S13. By this same method, the site of some auxotrophic markers was tentatively determined. The application of the protoplast fusion technique to exact genetic analysis will not be possible until the exo- and endogenous factors influencing cell wall regeneration are standardized. Fluctuations of this kind are very significant for the determination of genetic segregation.     

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.     

Polyethylene-glycol induced fusion of bacterial protoplasts

Summary Direct selection for recombinants by supplemented minimal media from polyethylene-glycol (PEG)-induced fusion of protoplasts of polyauxotrophic strains of B. megaterium revealed striking physiological influences on the yield of recombinants. Cytoplasmic state of the protoplasts to be fused, rather than genetic events, determined the number of colonies obtained on the selection media. It is suggested that the physiological effects primarily influenced the ability of the fused protoplasts to revert to bacillary form.     

Further studies on recombination in diploid clones from Bacillus subtilis protoplast fusion

Summary Diploid prototrophs were obtained from protoplast fusion of Bacillus subtilis strains. They are unstable but upon further cultivation they stabilize retaining diploidy but are genetically inactive. It has been suggested that recombination between the parental chomosomes is involved in the production of stable prototrophs and recombinants. In this work the occurrence of this recombination was searched for by determining genetic linkages in transformation experiments. In prototrophs two alleles: hisH2 and trpE8 carried originally on each parental chromosome, were shown to be 48% co-transformable in a stable clone whereas they were only cotransformed in 10% of the unstable colonies. For Trp^- recombinants (the most frequent type of a Leu^- Met^- Thr^- x Ade^- Ura^- Trp^- fusion pair) lysed protoplasts were used as donor DNA for the transformations. High values of co-transfer for Ura⁺ Met⁺ were obtained. These results confirm the occurrence of recombination in stable diploid clones, prototrophs or recombinants.     

Stereochemical Behavior of an NADH Model Compound Carrying l-Prolinamide at 3,5-Positions

Interspecific recombinants have been produced between Streptococcus cremoris H-61 and S. lactis J-1 by polyethylene glycol-induced protoplast fusion. All of the fusants obtained showed mixed physiological properties of the two parents, and possessed plasmids derived from both parents at random. Physiological properties of primary colonies were stably maintained among the progenies after the single-colony isolation procedure. Similarly, in most of the fusants the plasmid profiles of the primary colonies were stably maintained, but one lost 2 out of the 7 plasmid bands. However, there was no indication that plasmids from either one of the parents were preferentially lost. These results showed that interspecific genetic transfer occurred on chromosomal and plasmid DNA on the protoplast fusion and that the fusants obtained were not heterokaryons, but true recombinants.     

Transfection of Bacillus subtilis protoplasts by bacteriophage phi do7 DNA.

DNA from the Bacillus subtilis temperate bacteriophage phi do7 was found to efficiently transfect B. subtilis protoplasts; protoplast transfection was more efficient than competent cell transfection by a magnitude of 10(3). Unlike competent cell transfection, protoplast transfection did not require primary recombination, suggesting that phi do7 DNA enters the protoplast as double-stranded molecules.     

High-frequency fusion of Streptomyces parvulus or Streptomyces antibioticus protoplasts induced by polyethylene glycol.

Conditions were established for the regeneration of protoplasts of Streptomyces parvulus and Streptomyces antibioticus to the mycelial form. Regeneration was accomplished with a hypertonic medium that contained sucrose, CaCl2, MgCl2, and low levels of phosphate. High-frequency fusion of protoplasts derived from auxotrophic strains of S. parvulus or S. antibioticus was induced by polyethylene glycol 4,000 (42%, wt/vol). The frequency of genetic transfer by the fusogenic procedure varied with the auxotrophic strains examined. Fusion with auxotrophic strains of S. parvulus resulted in the formation of true prototrophic recombinants. Similar studies with S. antibioticus revealed that both stable prototrophic recombinants and heterokaryons were formed.     

Intergeneric protoplast fusion between agrobacterium tumefaciens and Bacillus thuringiensis subsp. kurstaki

Summary Intergeneric protoplast fusion betweenA.tumefaciens andB.thuringiensis was performed. The fusants exhibited some properties of both the parental strains. One of the Gram positive fusants with most of theBacillus properties showed tumor inducing capacity in pigeonpea (Cajanas cajan).