A novel method for regenerating the protoplasts of thermophilic bacilli

A range of Bacillus thermophiles was tested for the ability to be converted to protoplasts with lysozyme and subsequently, to regenerate to bacillary form. Protoplast formation was straightforward but many of the strains failed to regenerate on commonly-used media. Two medium components were found to be causing the inhibition. Growth of protoplasts as L-forms only occurred if the medium lacked phosphate. However, reversion of L-forms to bacilli was asynchronous and infrequent. Regeneration of cell walls by protoplasts/L-forms to re-establish bacillary form was greatly improved when the medium was gelled with pluronic polyol F127 in place of agar or similar polysaccharides.     

Reversion of Bacillus megaterium protoplasts to the bacillary form.

Photomicrographic evidence of reversion of Bacillus megaterium protoplasts to the bacillary form on soft agar plates hypertonic medium is demonstrated.     

An improved method for the preparation of mycobacterial spheroplasts and the mechanism involved in the reversion to bacillary form: electron microscopic and physiological study

An efficient method is described for preparing spheroplasts and protoplasts by treating bacillary cells of Mycobacterium smegmatis with precise concentrations of L-glycine (followed by lysozyme). This improved procedure was widely applicable to many rapidly growing mycobacteria by selecting the concentrations of glycine suitable for the individual strains used. The process of reversion of spheroplasts to original bacillary form on solid and in liquid media, as revealed by electron microscopy, appeared to involve the formation of an internal elementary or initial body with subsequent budding from the spheroplast. The internal membrane systems appeared to function in the induction of initial bodies and in the maturation of elementary bodies to become dividing forms. Possible mechanisms involved in the development of bacilli from spheroplasts are discussed.     

Inhibitory protein controls the reversion of protoplasts and L forms of Bacillus subtilis to the walled state.

When the cell wall of Bacillus subtilis is removed by lysozyme and the resultant protoplasts are plated on hypertonic soft agar medium, each protoplast forms an L colony. L bodies from such L colonies again plate as L-colony-forming units (CFU). However, if protoplasts or L bodies are "conditioned" by 1 h of incubation in 0.4% casein hydrolysate medium and then incubated in 25% gelatin medium for 1 h, 60 to 100% of the formerly naked cells give rist to bacillary colonies. The present experiments largely explain the mechanism responsible for the "heritable" persistence of the wall-less state in B. subtilis. It is shown that protoplasts produce a reversion inhibitory factor (RIF) which blocks reversion when the cell concentration exceeds 5 x 105 CFU/ml. This inhibitor is nondialyzable and sensitive to trypsin, heat, and detergent. Efficient reversion at 2 x 107 CFU/ml is obtained if the protoplasts are treated with trypsin after conditioning and chloramphenicol is incorporated into the gelatin reversion medium. In the presence of 500 mug of trypsin per ml, the requirement for gelatin is sharply reduced, and reversion occurs rapidly in liquid medium containing only 10% gelatin. Trypsin also stimulates reversion in L colonies growing on soft agar. Latent RIF is activated by beta-mercaptoethanol. This reagent blocks reversion of protoplast suspensions at densities of 5 x 105 CFU/ml. Comparison of the autolytic behavior of B. subtilis and of the RIF revealed that several or the properties of the two activities coincide: both are inhibited by high concentrations of gelatin, both are activated by beta-mercaptoethanol, and both have high affinity for cell wall. Going on the assumption that RIF is autolysin, models for protoplast reversion is suggested by the finding that mutants with altered teichoic acid show altered reversion behavior.     

Gelatin-induced Reversion of Protoplasts of Bacillus subtilis to the Bacillary Form: Electron-microscopic and Physical Study

Protoplasts of Bacillus subtilis plated on SD medium form L colonies in quantitative yield and propagate in the L form indefinitely. L bodies or protoplasts placed in 25% gelatin medium form bacillary colonies. Details of the reversion of naked bodies to the walled form are reported. In 25% gelatin medium, reversion begins earlier (about 50% reversion in 4 hr) than the multiplication of bacilli. Thus, virtually all the observed bacillary forms are themselves revertants and not the offspring of a few growing clones. The optimal temperature for reversion is 26 C in 25% gelatin. When cells reverting at 26 C are warmed to 40 C for 3 min, reversion is delayed markedly, whereas viability is unaffected. For electron microscopy, a dense protoplast inoculum was placed on a gelatin surface, incubated, and then fixed in situ. There was no multiplication, but crowding delayed reversion markedly. Successive events of reversion are as follows. The loose nucleoid of the protoplasts condenses in response to the gelatin medium and condenses further and further as reversion proceeds. A thin coat of wall develops around the bodies of various sizes and shapes and then increases uniformly in thickness until a wall of normal aspect is formed. Rod-shaped cells grow out from these bodies-sometimes in several directions at once. A few mesosomes begin to appear only after a thin coat of wall has been formed. These are dense, atypical structures compartmented by membranes. They are located at the cell periphery and do not seem to be in contact with the nucleoids. Quantitative estimates showed that only 20 to 25% of revertant cells or cells grown on gelatin contain even a single mesosome. The others have no mesosome at all. Mesosomes thus do not appear to play a significant role in reversion, and normal mesosome functions must presumably be performed elsewhere in the cell in gelatin-grown bacilli. The role of cell wall, its synthesis, and its chemical nature in successive steps in reversion are discussed.     

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.     

Formation of cell wall polymers by reverting protoplasts of Bacillus licheniformis.

The biosynthesis of peptidoglycan and teichoic acid by reverting protoplasts of Bacillus licheniformis 6346 His-, in cubated at 35 C on medium containing 2.5% agar, is detectable after 40 min. The amount of N-acetyl-[1-14C]glucosamine incorporated into peptidoglycan and teichoic acid on continued incubation doubles at the same rate as the incorporation of [3H]tryptophan into protein. At the early stages of reversion the average glycan chain length, measured by the ratio of free reducing groups of muramic acid and glucosamine to total muramic acid present, is very short. As reversion proceeds, the average chain length increases to a value similar to the found in the wall of the parent bacillus. The extent of cross-linkage found in the peptide side chains of the peptidoglycan also increases as reversion proceeds. At the completion of reversion the wall material synthesized has similar characteristics to those of the walls of the parent bacilli, containing peptidoglycan and teichoic and teichuronic acids in about the same proportions. Soluble peptidoglycan can be isolated from the reversion medium, amounting to 30% of the total formed after 3 h of incubation and 8% after 12 h. This amount was reduced by the presence in the medium of the walls of an autolysin-deficient mutant; they were not formed at all by reverting protoplasts of the autolysin-deficient mutant itself. Analysis of the soluble material provided additional evidence for their being autolytic products rather than small unchanged molecules. When protoplasts were incubated on medium containing only 0.8% agar, 53 to 67% of the peptidoglycan formed after 3 h of incubation was soluble, and 21% after 12 h. Fibers that appeared to be sheared from the protoplasts at intermediate stages of reversion on medium containing 2.5% agar were similar in composition to the bacillary walls.     

Gelatin-induced Reversion of Protoplasts of Bacillus subtilis to the Bacillary Form: Biosynthesis of Macromolecules and Wall During Successive Steps

Protoplasts of Bacillus subtilis plated on SDG medium formed L colonies in quantative yield and propagated in the L-form indefinitely. Protoplasts or L bodies placed in 25% gelatin medium formed bacillary colonies. Details of the reversion of these naked bodies to the walled form are reported here. Protoplasts prepared in minimal medium reverted fairly synchronously 3 to 4 hr after inoculation into gelatin, but protoplasts preincubated in casein hydrolysate (CH)-enriched minimal medium were primed to revert within 1 hr in the gelatin. Preincubation for 1.5 hr in 0.44% CH was required for good priming. Cells must be subjected to this preincubation (step 1) in the naked state; it is effective for L bodies as well as protoplasts. Priming was blocked by chloramphenicol, puromycin, and actinomycin D but was not affected by penicillin, lysozyme, or inhibition of deoxyribonucleic acid (DNA) synthesis. It is concluded that protein and ribonucleic acid (RNA) synthesis are required during step 1, that DNA synthesis is not required, and that wall mucopeptide is not made. The reversion of well-primed protoplasts in the gelatin (step 2) proceeded undisturbed in thymine-starved cells with chromosomes arrested at the terminus. It was scarcely slowed by chloramphenicol in the gelatin but was delayed about 3 hr by both puromycin and actinomycin D. Escape from inhibition occurred while the inhibitors were still actively blocking growth. Penicillin and cycloserine inhibited and lysozyme reversed reversion. Momentary melting of the gelatin delayed reversion. It is concluded that mucopeptide synthesis occurs in step 2, that concomitant RNA, DNA, or protein synthesis is not essential, but that physical immobilization of excreted cell products at the protoplast surface is necessary early in step 2. Newly reverted cells were misshapen and osmotically sensitive. Processes which confer osmotic stability after reversion (step 3) did not occur in the presence of chloramphenicol or actinomycin D.     

Experimental inhibition of cell wall formation and of reversion inNadsonia elongata andSchizosaccharomyces pombe protoplasts

Summary The growth, cell wall regeneration, and the reversion of the protoplasts ofNadsonia elongata andSchizosaccbaromyces pombe cultivated in nutrient media containing snail enzyme was studied by light and electron microscopy. The protoplasts grew in the presence of snail enzyme and an incomplete cell wall composed of fibrils was formed on their surface. Thus, the presence of snail enzyme inhibited the completion of cell wall structure and, consequently, the reversion of the protoplasts to normal cells. The transfer of these protoplasts to medium free from snail enzyme led first to the completion of the cell wall and then to the reversion of the protoplasts to normal cells. The reported experiments confirmed that the regeneration of the complete cell wall preceded the protoplast reversion.     

Cytological study of early stages of regeneration of protoplasts of fungi and Streptomyces

Early stages of Penicillium chrysogenum 51 and Streptomyces lividans 66 protoplast regeneration on solid media were studied microscopically under conditions of microcompartments. It was shown that at the early regeneration stages there were both rapid reversion into the mycelial form and a retarded one. In P. chrysogenum retarded regeneration resulted in formation of hypha-like structures or protoplast breaking into fragments of various sizes. Some of the fragments restored the cell walls and mycelial organization whereas the others lysed. As a result of the breaking and compartmentalization of the viable areas one protoplasts formed several centers of P. chrysogenum colony reversion. Retarded regeneration of protoplasts in S. lividans 66 resulted in their growth and multiplication in the protoplast-like L-form. On media with penicillin, glycine and horse serum there were isolated colonies of S. lividans L-forms subject to passages or reversion depending on the medium composition.     

Reversion to bacillary forms of Serratia marcescens spheroplasts induced by carbenicillin. Scanning electron microscopic study

Bacterial cells of Serratia marcescens were easily induced to form spheroplasts in liquid medium by the addition of carbenicillin. The spheroplasts were unable to divide, but they were able to revert to the bacillary forms in liquid medium not containing carbenicillin. Four phases of the reversion sequence could be differentiated by scanning electron microscopy. (1) After 3 hr of incubation in carbenicillin-free medium, some projections arose out of the spheroplasts, and grew and elongated. (2) Their elongation resulted in a morphological change in the spheroplasts from spherical bodies to long irregular bacillary forms. (3) Further incubation caused several constricted areas in the bacillary form. (4) The long bacillary forms split along the constricted areas to become the parent bacillary forms of S. marcescens. When the long bacillary form that developed during the reversion was retreated with carbenicillin, it was immediately induced to become a spheroplast again.     

Stable L-forms of Clostridium perfringens and their growth on glass surfaces.

L-forms of Clostridium perfringens were induced in brain heart infusion broth containing 10% sucrose and 2 units of penicillin. After a few hours of growth, spheroplasts, granules, and elongated bacilli were apparent. At 24-h intervals, serial subcultures were made in the above medium which resulted in a culture composed entirely of spheroplasts (or protoplasts) and granules. Upon the withdrawal of penicillin these L-form cultures grew well and, after 100 passages, there was no reversion to the bacillary form. Sucrose could also be withdrawn from the medium. The effects of centrifugation, osmotic stabilizer, ultraviolet light, temperature, pH, and lyophilization upon stable L-forms were examined. L-forms were found to attach to the walls of culture tubes during trowth and sheets of L-form growth were obtained on cover slips in Leighton tubes and on the sides of medicine bottles.     

Regeneration of the cell wall of protoplasts of the fission yeastSchizosaccharomyces versatilis in liquid media and their reversion to cells

Regeneration of the cell wall and reversion of protoplasts with a completely regenerated cell wall to cells were studied by light and electron microscopy in protoplasts of the fission yeastsSchizosaccharomyces versatilis. On their surface the protoplasts regenerated a complete new wall even m liquid media The wall regeneration began with the formation of a thin irregular net of flat bundles of long microfibrils and the net was gradually filled with aggregates of short straight microfibrils and small piles of amorphous material. Osmotically resistant organisms with regenerated walls were detected after a 4–6 h cultivation Depending on the nutrient medium used 10–80 % of protoplasts with the regenerated wall were obtained that reverted subsequently to cells. The high percentage of the wall regeneration and reversion to cells was reached by combining cultivation in a poor medium with that in a rich medium Reversion to cells could only occur after the protoplasts had regenerated rigid cell walls These walled protoplasts underwent septation, and, by polar growth, produced cylindrical cells, further dividing by fission.     

Cell fusion between L-forms and protoplasts of Staphylococcus aureus

Mixtures of various combinations of Lysostaphin protoplasts and stable L-forms of Staphylococcus aureus, which have different markers for drug resistance, were treated with polyethylene glycol (PEG) to examine the development of doubly resistant fusion products (fusants). To recover doubly resistant colonies as L-forms, they were incubated in 4.5% NaCl-brain heart infusion (BHI) broth containing penicillin G (PCG) for enrichment culture and cultured in PCG-4.5% NaCl-BHI agar medium (method 1), while to recover doubly resistant fusants as L-forms and coccal forms, they were grown on reversion medium (R medium) which causes reversion of protoplasts or fusants to parent type cells, and then cultured on assay media, i.e., R medium, BHI agar medium or PCG-4.5% NaCl-BHI agar medium (method 2). Under both experimental conditions, doubly resistant fusants developed as L-form cells by PEG treatment of pairs of protoplasts carrying the chloramphenicol (CP)-resistance plasmid and L-forms having chromosomal resistance to streptomycin (SM). In the reverse combinations, i.e., protoplasts showing chromosomal SM-resistance and L-form cells carrying the CP-resistance plasmid, the first method gave no doubly resistant colonies. By the second method, without enrichment culture on R medium, the latter combination gave doubly resistant fusants as L-form, coccal-type and mixed-type colonial forms, while when the PEG-treated mixture was enriched on R medium, fusants were obtained exclusively as the coccal type on either R medium or BHI agar assay medium. Neither of the methods yielded colonies of doubly resistant fusants on PEG-treatment of pairs of protoplasts and L-forms both of which were chromosomal, but with different drug resistances. These results show that PEG-induced cell fusion between protoplasts and L-forms of S. aureus, unlike the fusion between protoplasts or between L-forms, resulted in transfer of the drug resistance controlled by the plasmid to the fusion products. The fusants obtained were L-forms in method 1, and coccal type in the method 2.     

Protoplast forming ability in the genusBrevibacterium

Formation of protoplasts and their reversion were followed in 7 strains of brevibacteria. The formation of protoplasts and their reversion differed both between various species of brevibacteria and between various mutant strains of the same species.     

Protoplast formation and regeneration of a thermophilic Clostridium sp.

Abstract Protoplasts of a thermophilic Clostridium sp. were prepared by lysozyme treatment using lactose as osmotic stabilizer. High frequency reversion (3–29.8%) to the bacillary form was obtained on hypertonic rich medium.     

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.     

Regeneration of protoplasts of Bacillus subtilis 168 and closely related strains

Regeneration of protoplasts to bacilli was attempted in several strains of Bacillus closely related to Bacillus subtilis 168. On DM3 and similar media using succinate as osmotic support, only B. subtilis 168 and Bacillus natto ATCC 15245 were able to regenerate. Media containing mannitol as osmotic support, and agar as gelling agent gave rise to L-form colonies with Bacillus licheniformis NCTC 6346. Many of the L-form colonies were able to regenerate to the bacillary form when plated on the mannitol medium solidified with gelatin. All of the Bacillus species tested were able to regenerate on the latter medium at rates sufficient to allow protoplast transformation and fusion experiments.     

Karyokinesis in growing and reverting protoplasts ofSchizosaccharomyces pombe

Division of nuclei without cytokinesis proceeds in growing protoplasts ofSchizosaccharomyces pombe. Prior to regeneration of the complete cell wall and reversion the protoplasts contain 1–7 nuclei, protoplasts with 1–2 nuclei are most frequent. When regeneration of the wall is postponed by adding snail enzymes to the growth medium, protoplasts with a higher number of nuclei (2–4) occur. Multinuclear protoplasts can revert to cells. During the first cytokinesis the protoplast with the regenerated cell wall is divided into two cells by a septum, distribution of nuclei between the two cells being probably incidental. More than only a single nucleus can pass to the revertants even during the second cytokinesis. Septation of protoplasts occurs also during a partial blockage of the wall formation by the snail enzyme preparation, however, reversion to cells can never be observed here (it occurs only after transfer of protoplasts to the medium without the enzyme preparation). The growing and reverting protoplasts represent a very good model system for studying relations among individual processes of the cell cycle, primarily growth of the cell, nuclear cycle and cytokinesis. Yeast protoplasts are often utilized as models for studying morphogenic processes, relations among regeneration of the cell wall, including division of the nucleus (karyokinesis) and cytokinesis.     

F-actin contractile rings in protoplasts of the yeast Schizosaccharomyces

By rhodamine-phalloidin fluorescence, distinct continuous F-actin rings were visualized in 18-20% of the protoplasts of Schizosaccharomyces pombe and S. japonicus var. versatilis, in addition to randomly distributed F-actin dots. Whereas the reversion of ring-lacking protoplasts coincided with the polarization of the dotted F-actin pattern, the ring-containing protoplasts became furrowed as the F-actin rings constricted. The furrowing was more conspicuous in S. japonicus var. versatilis than in S. pombe protoplasts and it was blocked when the reversion was inhibited by Novozyme 234 indicating that the cell wall formation is essential for the F-actin ring constriction.