Protoplast fusion: a tool for intergeneric gene transfer in bacteria

Protoplasts can be isolated from bacterial cells by digestion of the cell wall with the help of lysozyme in presence of osmotic stabilizers. Fusion of protoplasts can be induced by chemical fusogens like polyethylene glycol. The electrofusion technique has been reported in bacteria in which the fusion frequency is much higher than that obtained by PEG induced protoplast fusion. This technology allows recombination to take place not only between related species but also between unrelated genera and is of great potential in the breeding and improvement of industrial strains. This review includes the information and developments on the protoplast fusion in bacteria with special reference to genetic recombination by protoplast fusion between phylogenetically unrelated bacteria.     

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).     

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.     

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.     

Bacterial fusion assayed by a prophage complementation test.

In previous studies of bacterial protoplast fusion, only the frequencies of cell wall regeneration and of bacterial recombination were determined. In this work the frequency of the heterozygous fusion products is measured by prophage complementation. Two multiply marked nonsuppressing strains of Bacillus subtilis, each lysogenic for a different Sus mutant of the phage phi 105, were induced by mitomycin C, protoplasted, fused, and, after dilution in hypertonic broth, incubated until plating with phi 105-sensitive indicator bacteria. When cell lysis was avoided, the frequency of the heterozygous fused cells could be determined from the number of infectious centers produced. The very high frequencies observed are in good agreement with those determined directly, with nonlysogenic strains, by electron microscopic examination of the fused protoplasts (C. Frehel, A. M. Lheritier, C. Sanchez-Rivas, and P. Schaeffer, J. Bacteriol. 137:1354--1361, 1979). Evidence is presented that fusion occurs in two steps, one polyethylene glycol dependent, the other energy requiring. The bacterial growth medium affects the ability of the protoplasts to fuse and to regenerate a cell wall. When experiments using different growth media were compared, an inverse relationship between these abilities was observed, and a direct relationship appeared between the heterozygotes (corrected for wall regeneration) and the recombinant bacteria that were found.     

Transfer of functional adenovirus E1A transcription activator proteins into mammalian cells by protoplast fusion

Human adenovirus 2/5 E1A proteins were used to evaluate protoplast fusion as a method of transferring functional proteins into mammalian cells. Both the E1A 13 and 12 S mRNA products expressed in Escherichia coli are shown to activate in trans adenovirus gene expression following transfer into monkey kidney cells by protoplast fusion. Approximately 20% of the recipient mammalian cells exhibited positive nuclear E1A-specific immunofluorescence following fusion with protoplasts containing E1A protein. E. coli-expressed E1A protein was modified post-translationally in Vero cells following protoplast fusion, as evidenced by its shift in sodium dodecyl sulfate-polyacrylamide gel electrophoresis mobility. These results establish protoplast fusion as a simple rapid method for examining the functional activity, intracellular distribution, and post-translational modification of E. coli-expressed proteins in intact mammalian cells.     

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.     

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.     

PEG-induced fusion of phosphatidylcholine-liposomes with protoplasts and post-fusion evaluation of plating efficiency and enrichment in plasmamembrane phosphatidylcholine of protoplasts in Datura innoxia Mill

Liposomes entrapping fluorescein diacetate were fused with protoplasts of Datura innoxia Mill by employing polyethylene glycol (PEG) as the fusogen. Factors that influence liposome-protoplast fusion were optimized as a function of PEG-concentration and incubation duration, liposome composition and surface charge and liposome:protoplast ratio. Phosphatidylcholine-liposomes were found ideal for the objectives of the study. Fusion index based on per cent fluorescing protoplasts varied among the protoplast types. PEG-incubation duration in the fusion assay and growth ability of protoplasts to form microcalli subsequent to liposome-protoplast fusion was determined based on protoplast plating-efficiency. Plating efficiency of post-fusion protoplasts increased due to incorporation of liposome-phosphatidylcholine in the plasmamembrane of protoplasts. Results are discussed in relation to the application of liposome-protoplast fusion system in selective modification of plasmamembrane phospholipids of protoplasts.     

Studies of protoplast fusion in Streptomyces chrysomallus

Conditions for the regeneration of cells from protoplasts of Streptomyces chrysomallus, a producer of the peptide antibiotic actinomycin, are described. Regeneration of fusion products was most efficient at 27-30 degrees C on regeneration R2 medium (Okanishi et al., 1974) containing 0.25 M-sucrose. The addition of phosphate (150-300 mg 1(-1) to the medium and incubation at 23 degrees C proved to be optimal for the regeneration of individual strains. Highest recombination frequencies after protoplast fusion were obtained by fusing protoplasts in the presence of 45% (w/v) polyethylene glycol 6000. With strains that produce no, or little antibiotic, protoplasts must be present in excess in fusion mixtures in order to overcome inhibition of regeneration by the antibiotic-producing partner.     

Protoplast fusion — a tool for genetic manipulation and breeding in industrial microorganisms

Protoplasts can be isolated from microbial cells by enzymatic digestion of the cell wall, in the presence of an osmotic stabilizer. Such protoplasts can be induced to fuse in the presence of agents such as the poly (ethylene glycols). When suitably selected auxotrophic strains are used, the fusion products can be recovered by selection on the basis of nutritional complementation. Cultivation of the protoplasts on a hypertonic growth medium induces regeneration of new cell wall material and their subsequent reversion to the normal cell form of the organism. The protoplast fusion technique has been applied sucessfully to both bacterial and fungal systems leading to the recovery of recombinant progeny. In the fungi, the recovery of non-parental segregants from inter-species crosses has also been demonstrated. In assessing the value of the fusion technique, caution may be necessary at this stage in its application to genetic mapping in bacteria. The behaviour of protoplasts, especially with respect to reversion, could be an additional factor that operates during selection, distorting recombination frequencies. However, the fusion technique, in providing a mechanism by which genetic recombination can be readily achieved, should be of great potential in empirical breeding and strain improvement. These aspects are reviewed.     

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.     

Protoplast fusion in Saccharomyces cerevisiae

The ability of different Saccharomyces cerevisiae yeast strains to form protoplasts and protoplast fusion were studied. The protoplast formation depended mainly on strains used and the time of snail gut enzyme action. The percentages of the regenerating protoplasts varied, depending on strain, from 3 to 33 per cent. From the fusion experiments one can establish that kariogamy is prerequisite for stable for stable diploid formation. The yields of protoplast fusion were higher when both strains were rho+ as compared with rho+ and rho 0 combinations.     

Expression of the recombinant antibacterial peptide sarcotoxin IA in Escherichia coli cells

Sarcotoxin IA is an antibacterial peptide that is secreted by a meat-fly Sarcophaga peregrina larva in response to a hypodermic injury or bacterial infection. This peptide is highly toxic against a broad spectrum of both Gram-positive and Gram-negative bacteria and lethal to microbes even at nanomolar concentrations. However, research needs as well as its potential use in medicine require substantial amounts of highly purified sarcotoxin. Because heterologous expression systems proved to be inefficient due to sarcotoxin sensitivity to intracellular proteases, here we propose the biosynthesis of sarcotoxin precursors in Escherichia coli cells that are highly sensitive to the mature peptide. To optimize its biosynthesis, sarcotoxin was translationally fused with proteins highly expressed in E. coli. A fusion partner and the position of sarcotoxin in the chimeric polypeptide were crucial for protecting the sarcotoxin portion of the fusion protein from proteolysis. Released after chemical cleavage of the fusion protein and purified to homogeneity, sarcotoxin displayed antibacterial activity comparable to that previously reported for the natural peptide.     

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     

Export of Thermus thermophilus cytoplasmic beta-glycosidase via the E. coli Tat pathway

The Tat pathway is distinct from the Sec machinery given its unusual capacity to export folded proteins, which contain a twin-arginine (RR) signal peptide, across the plasma membrane. The functionality of the Tat pathway has been demonstrated for several Gram-negative and Gram-positive mesophilic bacteria. To assess the specificity of the Tat system, and to analyze the capacity of a mesophilic bacterial Tat system to translocate cytoplasmic proteins from hyperthermophilic bacteria, we fused the Thermus thermophilus beta-glycosidase (Glc) to the twin-arginine signal peptide of the E. coli TorA protein. When expressed in E. coli, the thermophilic RR-Glc chimera was successfully synthesized and efficiently translocated into the periplasm of the wild type strain. In contrast, the beta-glycosidase accumulated within the cytoplasm of all the tat mutants analyzed. The beta-glycosidase synthesized in these strains exhibited thermophilic properties. These results demonstrated, for the first time, the capacity of the E. coli Tat system to export cytoplasmic hyperthermophilic protein, implying an important potential of the Tat system for the production of thermostable enzymes used in bioprocessing applications.     

Use of the protoplast fusion method in the selection of Streptomyces griseus--the producer of the streptothricin antibiotic grisin

An effective method for protoplast fusion in S. griseus producing grisin was developed. The method requires the use of polyethylene glycol with a molecular weight of 1000. It was demonstrated that protoplasts formed most effectively in this organism, when the mycelium of the streptomycete previously treated with ultrasound in the process of its growth was used for the treatment with lysozyme. The efficacy of protoplast regeneration in the strains with the use of the modified hypertonic medium R2MD was 25-75 per cent. The possibility of using the protoplast fusion method for constructing phage resistant strains producing kormogrisin was shown.     

Induction and Characterization of Artificial Diploids from the Haploid Yeast Torulaspora delbrueckii

The yeast Torulaspora delbrueckii, which propagates as a haploid, was made into a diploid by treatment with dimethyl sulfoxide (DMSO) on the regeneration of protoplasts. The diploid state was stably inherited; the cell volume was three times that of the parent strain and the cellular DNA content was two times that of the parental strain. No essential difference was found between diploids induced by DMSO and those formed through intraspecific protoplast fusion. The diploid strains sporulated fairly well, with their cells converting directly into asci. Random spore analysis revealed that diploids induced through protoplast fusion gave rise to auxotrophic segregants (haploids) with the parental genetic marker or to segregants formed by recombination, while diploids induced by DMSO from a doubly auxotrophic parent gave rise to no recombinant, indicating that it was chromosomally homoallelic in nature. The magnesium level in the protoplast regeneration medium was found to be an important factor for inducing diploid formation. At 0.2 mM magnesium diploids appeared even in the absence of DMSO, while at 2 mM magnesium diploids never appeared unless DMSO was added to the regeneration medium. Evidence is provided that the diploids induced by DMSO or a low magnesium level are due to direct diploidization but not protoplast fusion. UV light irradiation of intact cells (without protoplasts), 10% of which survived, also produced diploids among this surviving population. From these results we conclude that the perturbation of protoplast regeneration or of cell division by the treatments mentioned above somehow induced direct diploidization of T. delbrueckii.     

Fungal protoplast fusion – a revisit

Protoplast fusion is a non-specific recombination technique used for transfer of cytosolic organelles including genetic material. The process involves cell wall breakdown, regeneration of protoplasts, chemofusion and electrofusion. This review article discusses all the stages involved in fusion of protoplasts and some of the applications of protoplast fusion technique in fungal systems.     

The use of mitochondrial mutants in the isolation of hybrids involving industrial yeast strains

Summary Methods for isolation of hybrids of industrial yeast strains, obtained by PEG-mediated protoplast fusion, using mitochondrial mutations to antibiotic resistance and to the petite condition as markers, are described. One of the industrial prototrophic strains, carrying a rescuable mutation to antibiotic resistance, was converted to the petite form, and protoplasts obtained from it were fused with protoplasts from antibiotic-sensitive prototrophic strains of brewing and distiller's yeasts or with an auxotrophic laboratory strain carrying several chromosomal mutations. The parent of the petite strain was also able to metabolize starch, which was used as an additional character for confirming the hybrid nature of the strains isolated on the basis of their antibiotic resistance.Presented in part at the 5th International Protoplast Symposium held at the Attila Josef University, Szeged, Hungary, July 9–14, 1979