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.     

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.     

Effect of the composition of reversion medium on change of Staphylococcus aureus lysostaphin protoplasts to coccal forms and L-forms

The experimental conditions under which protoplasts of Staphylococcus aureus strain MS353 (pCp) are converted to the coccal or L-form were investigated. Protoplasts prepared by treating coccal MS353 (pCp) strain with Lysostaphin formed various types of colonies (coccal form, L-form and mixed types) in about 50% yield when they were plated on reversion (R) medium consisting of 2% brain heart infusion, 0.5M sodium succinate, 0.01% bovine serum albumin, 20 mM MgCl2 and 0.6% agar. The L-form type colonies with a typical fried-egg appearance that developed on the R medium at an early stage gradually reverted to the coccal form through a mixed type stage in which a high density area first appeared in the periphery of the colony and then spread throughout the colony. The use of modified R medium without MgCl2 or R medium in which 0.5M sodium succinate as an osmotic stabilizer was replaced by 7.5% NaCl resulted in marked delay in the appearance of reverted cells. R medium without bovine serum albumin yielded atypical L-form type colonies, which contained masses of coccal cells with very irregular margins. On the other hand, R medium without MgCl2 but with penicillin G supported development of L-form type colonies at high rate (13-15%) from the inoculated protoplasts.     

Effect of aculeacin A on reverting protoplasts of Candida albicans

Protoplasts of Candida albicans were prepared by digestion with Zymolyase and the effect of aculeacin A, a wall-active antibiotic, on the synthesis of microfibrillar structures by the protoplasts incubated for 5 hr in an osmotically stabilized medium was studied using several electron microscopical techniques. Chemical analyses of the protoplasts before and after reversion with or without the antibiotic were also performed. Aculeacin A not only inhibited synthesis of microfibrils mainly composed of alkali-insoluble beta-glucan, but also their assembly to form thicker bundles. The antibiotic appeared to have no effect on other wall components constituting the surface structure of reverting protoplasts. These data confirmed our previous postulation that aculeacin A is a specific and potent inhibitor of beta-glucan synthesis as well as biogenesis of cell walls including beta-glucans in susceptible yeasts.     

Transformation in Quasi Spheroplasts of Bacillus subtilis

RECENTLY DEVELOPED DIFFERENTIAL PLATING MEDIA PERMIT THE DISTINCTION OF FOUR CELL TYPES IN INCOMPLETELY PROTOPLASTED POPULATIONS: intact, osmotically insensitive bacilli; osmotically sensitive rods; spheres with adherent wall residues, called quasi spheroplasts; and protoplasts. Such population mixtures were washed free of lysozyme, and then transforming deoxyribonucleic acid (DNA) was added. Transformation was nil in the protoplasts, very low in the residual osmotically insensitive bacilli, and markedly enhanced in both osmotically sensitive rods and quasi spheroplasts. Transformation in the latter two population fractions was reduced, respectively, by about 60% and about 80% by deoxyribonuclease treatment. DNA adhering to the quasi spheroplasts transforms these cells only if they are permitted to resume wall synthesis; when the same cells are plated on a medium where they shed the residual wall and form L colonies, no transformant L colonies are recovered. It is inferred that far-reaching or complete protoplasting blocks all entry of transforming DNA into the cell interior. This may be owing to eversion of mesosomes. Evidence that intact mesosomes may be required for DNA entry is provided by the finding that the recovery of transformants in the intact cell system is sharply reduced on plating media containing 25% gelatin. On such media, cells expel their mesosomes and 75% of them do not re-form any. Our own data and a survey of published results suggest the generalization that partial depolymerization of the cell wall by lysozyme may enhance competence, whereas its complete removal abolishes it.     

Morphological study of the reversion to bacillary form, of Bacillus megaterium protoplasts.

Protoplasts of Bacillus megaterium readily reverted to bacillary form in liquid media and when plated in a soft-agar layer onto the surface of appropriate agar media. Three phases of the reversion sequence could be differentiated by phase contrast microscopy: (i) increase in size of the individual protoplasts, (ii) non oriented division of the protoplasts and (iii) outgrowth of the bacillary forms. With time-lapse photomicrography, reversion sequences of single protoplasts were demonstrated.     

Phytochrome destruction: an apparent requirement for protein synthesis in the induction of the destruction mechanism

Examination of the phytochrome destruction reaction as a function of age in etiolated oat (Avena sativa L. cv. Garry) seedlings demonstrates that following illumination of 3-day-old shoots there is a lag, not observed in 4- or 5-day-old oats, prior to the onset of destruction. This light-mediated induction of the phytochrome destruction mechanism in 3-day-old shoots is inhibited by chloramphenicol, actinomycin D, and puromycin suggesting that protein synthesis is required. In 4-day-old shoots, actinomycin D and puromycin do not alter the kinetics of destruction while chloramphenicol partially inhibits the process. Thus, the inhibitors have a specific effect on the induction of the destruction mechanism but not its subsequent operation.     

Optimum conditions for efficient transformation ofStreptomyces venezuelae protoplasts

Summary Optimum conditions for protoplast regeneration and transformation ofStreptomyces venezuelae ETH 14630 have been established. Protoplasts from mycelium grown to the stationary phase and treated with lysozyme in P medium under mild conditions gave the best regeneration frequency. Transformation of protoplasts with naked DNA was very efficient using either polyethylene glycol of mol. wt. 4000 or 6000, at concentrations of 28.5% or 36% (w/v) respectively. About 10⁵ transformants/g DNA could be isolated using protoplasts derived from cells cultivated to the early exponential growth phase in LB medium containing 0.2%-0.6% glycine and subsequently treated at 30°–32°C with 20 mg lysozyme/ml in P medium for 30 min. Selection of the transformants occurred on MRYE plates containing less than 10⁵ regenerating protoplasts per plate. Higher protoplast densities considerably decreased the regeneration frequency of the transformants.     

Characterization of the Repair of Injury Induced by Freezing Salmonella anatum

Fast freezing and slow thawing of Salmonella anatum cells suspended in water resulted in injury of more than 90% of the cells that survived the treatment. The injured cells failed to form colonies on the selective medium (xyloselysine-peptone-agar with 0.2% sodium deoxycholate) but did form colonies on a nonselective (xylose-lysine-peptone-agar) plating medium. In Tryptic soy plus 0.3% yeast extract broth or minimal broth, most of the injured cells repaired within 1 to 2 hr at 25 C. Tryptic soy plus yeast extract broth supported repair to a greater extent than minimal broth. Phosphate or citrate at concentrations found in minimal broth supported repair of some cells. MgSO(4), when present with inorganic phosphate or citrate or both, increased the extent of repair. The repair process in the presence of phosphate was not prevented by actinomycin D, chloramphenicol, and D-cycloserine, but was prevented by cyanide and 2,4-dinitrophenol (only at pH 6). This suggested that the repair process might involve energy metabolism in the form of adenosine triphosphate. The freeze-injured cells were highly sensitive to lysozyme, whereas unfrozen fresh cells were not. In the presence of phosphate or minimal broth this sensitivity was greatly reduced. This suggested that, at least in some of the cells, the injury involved the lipopolysaccharide of the cell wall and adenosine triphosphate synthesis was required for repair.     

Protoplasts from the cyanobacterium,Spirulina platensis

Protoplasts were obtained from the filamentous blue-green algaSpirulina platensis by treating the filaments with 0.05% (w/v) lysozyme in 0.03m phosphate buffer. The protoplasts regenerated cell walls and formed colonies when plated on a regeneration medium. The highest percentage of regeneration, 40% was obtained after 21 days.     

Transformation of Bacillus thuringiensis protoplasts by plasmid deoxyribonucleic acid.

A method has been developed to transform plasmid deoxyribonucleic acid into protoplasts of the insect pathogen Bacillus thuringiensis. Protoplasts were formed by treatment of cells with lysozyme. The efficiency of formation of protoplasts was affected by the strain, the media, and the cell density. Deoxyribonucleic acid uptake was induced by polyethylene glycol. Deoxyribonucleic acid from the Staphylococcus aureus plasmid pC194 was used for transformation. Although this plasmid could not be isolated as a stable extrachromosomal element, its chloramphenicol resistance was transferred to the recipient protoplasts. This was confirmed by assay for the enzyme chloramphenicol acetyltransferase, which confers resistance to chloramphenicol. This suggested that pC194 acts as an insertion element in B. thuringiensis.     

Isolation of protoplasts from somatic embryos of carrot

Protoplasts were isolated enzymatically from synchronously induced globular somatic embryos from a carrot suspension culture. Among the macerating enzymes tested, Driselase was the most effective for release of protoplasts from embryos. A higher medium osmolarity was required for the isolation of protoplasts from embryos than from undifferentiated cells. Protoplasts from embryos were smaller than protoplasts from undifferentiated cells. On step gradients of Ficoll, protoplasts from embryos gave one major band. Protoplasts from undifferentiated cells gave two major bands, one lighter and the other heavier than the protoplasts from embryos.     

Reversion to the Streptococcal State of Enterococcal Protoplasts, Spheroplasts, and L-Forms

A method is described for predetermining whether lysozyme-damaged enterococci grow as either the parent strain or as L-forms. Organisms treated with lysozyme grew as L-forms on media solidified with low concentrations of agar, or the damaged cells grew as streptococci on media solidified with high concentrations of gelatin. After induction, some of the L-forms reverted to the parent strain, but most did not during three routine subcultures. Continued spontaneous reversion occurred through approximately 30 subcultures after induction. However, subsequent progeny did not revert, even when subjected to conditions such as the gelatin medium which strongly favors growth in the streptococcal phase.     

Protoplast-transfection of Streptomyces chartreusis SF1623 with Actinophage Φr5 DNA

To establish a procedure for high frequency transfection in streptomycetes, the conditions and factors affecting the polyethyleneglycol (PEG) mediated transfection of S. chartreusis SF1623 by actinophage Φr5 DNA were studied. Protoplasts of S. chartreusis SF1623 prepared by treatment with lysozyme and achromopeptidase were very stable. Protoplasts from 20 to 22hr culture cells were more competent for transfection. The optimal pH of the medium for transfection was pH 7.6. The presence of NaCl, thymidine, ATP, ADP or adenosine in the transfection medium enhanced the frequency of transfection. The optimal conditions determined for protoplast transfection were 12.5% PEG 4,000, 300 mm NaCl, 1 mm thymidine, final concentration, Φr5 DNA and protoplasts in P3 medium (pH 7.6). The frequency of transfection under the optimal conditions was 5 × 10⁵ per μg Φr5 DNA and was about 3 × 10^?3 per regenerated protoplasts.

Progenitively mature phages appeared 4hr after incubation in the regeneration solution and their number continued to increase for about 11 hr. The burst size was estimated to be about 400.     

Protoplast fusion permits high-frequency transfer of a Streptomyces determinant which mediates actinomycin synthesis.

Prototrophic recombinants and heterocaryotic colonies developed at high frequency when protoplasts of nutritionally complementary actinomycin-producing and nonproducing strains of Streptomyces antibioticus were fused in the presence of polyethylene glycol and plated on minimal regeneration medium. Of the spores obtained from aerial hyphae of a single heterocaryotic colony, 99% carried the act+ character regardless of whether the nutritional markers of the spore were derived from the act+ or the act parent. Similarly, a high-frequency transfer (68% in S. antibioticus, 48% in Streptomyces parvulus) of act+ determinant(s) to act was achieved by protoplast fusion. Protoplasts of a doubly auxotrophic act strain of S. parvulus were efficiently transformed in the presence of polyethylene glycol with respect to the auxotrophic markers by DNA of an act+ auxotrophic strain with complementary nutritional requirements. The transformation frequency of the nutritional (chromosomal) markers was 17%. In contrast, the transformation frequency for actinomycin synthesis was less than 1%.     

CELL ARREST IN Gl AND G2 OF THE MITOTIC CYCLE OF VICIA FABA ROOT MERISTEMS

Experiments were performed with cultured excised primary root tips of Vicia faba ‘Longpod’ to determine: (1) the proportion of meristematic cells arrested in Gl and in G2 during carbohydrate starvation, and to determine if the proportion is fixed or can be varied experimentally; (2) the effect of increased starvation on the ability of arrested cells in Gl and G2 to initiate DNA synthesis and mitosis, respectively, when exogenous sucrose was supplied; and (3) whether puromycin, cycloheximide, or actinomycin D prevented the initiation of DNA synthesis and the onset of mitosis. Microspectrophotometry of nuclear DNA and autoradiographic measurements of incorporated ³H-thymidine showed that 72 hr of starvation immediately after excision produced tissue with more than 70 % of the cells arrested in G2 and less than 30 % in Gl. If cultured for three days and then starved for 72 hr, the tissue had nearly equal numbers of cells arrested in Gl and G2. As the duration of starvation increased, the time required to initiate DNA synthesis and to divide when carbohydrate was replenished also increased. Inhibition of protein synthesis by puromycin and cycloheximide prevented the initiation of DNA synthesis and mitosis, but actinomycin D, an inhibitor of RNA synthesis, did not prevent division of cells from G2 nor DNA synthesis by cells from Gl. The experiments demonstrated that the mitotic cycle of Vicia has two major controls, one in Gl and another in G2, and that other factors determine how many cells are affected by either of these cycle controls.     

Metabolic Process During the Repair of Freeze-Injury in Escherichia coli

After Escherichia coli was injured by freezing, the repair process was studied during incubation of the cells for 2 hr at 25 C in 0.5% K(2)HPO(4) at pH 7.0 in the presence of specific metabolic inhibitors. The repair in K(2)HPO(4) was not affected by inhibitors of the synthesis of protein, nucleic acids, and mucopeptide. These inhibitors prevented growth of the repaired cells in a minimal broth at 35 C for 24 hr (except actinomycin D and hydroxyurea). Several uncouplers of adenosine triphosphate (ATP) synthesis reduced the repair process in K(2)HPO(4), but only cyanide and azide prevented growth in minimal medium. Data indicated that the cells synthesized energy in the form of ATP and probably utilized it for the repair process. Addition of ATP also facilitated the repair of injury. The freeze-injured cells showed extreme susceptibility to surface-active agents and lysozyme. The repaired cells, like the uninjured cells, became relatively resistant to these compounds.     

Replacement of Lysine by Hydroxylysine and Its Effects on Cell Lysis in Streptococcus faecalis.

Shockman, Gerald D. (Temple University, Philadelphia, Pa.), J. Stuart Thompson, and Margaret J. Conover. Replacement of lysine by hydroxylysine and its effects on cell lysis in Streptococcus faecalis. J. Bacteriol. 90:575-588. 1965.-Hydroxylysine was not significantly incorporated by Streptococcus faecalis ATCC 9790 or 8043 until exponential growth ceased as a result of lysine exhaustion. Uptake was then rapid and virtually complete within 1 hr. Lysine absence, rather than physiological age, seemed to be the governing factor. Hydroxylysine uptake rapidly reached a peak in the acid-soluble fraction, suggesting a precursor role for substances in this fraction. Substitution of hydroxylysine for lysine was much more efficient in mucopeptide synthesis than in protein synthesis. In wall medium, less than 1% of the incorporated hydroxylysine was found in the protein fraction. Addition of lysine to both growth and wall media inhibited both further hydroxylysine uptake and transfer of hydroxylysine from acid-soluble to mucopeptide or protein fractions. Hydroxylysine resulted in decreased penicillin susceptibility only after it was postexponentially incorporated. This effect was physiologically similar to that seen after threonine deprivation or chloramphenicol treatment. Hydroxylysine incorporation increased resistance to autolysis, but failed to decrease lysozyme susceptibility when measured after heat inactivation of autolysis. Electron microscopy of negatively stained cells showed increased thickness of cell walls containing hydroxylysine. Thus, most of the effects of replacement of lysine by hydroxylysine resemble those seen after deprivation of a nonwall amino acid (e.g., threonine or valine) or after chloramphenicol treatment. Each of these conditions results in inhibition of protein synthesis while permitting cell-wall synthesis to continue, resulting in autolysis-resistant, thick-walled cells.     

Chemical analysis of cell wall regeneration and reversion of protoplasts from Schizophyllum commune.

In the presence of MgSo4 as osmotic stabilizer, nucleated protoplasts of Schizophyllum commune developed a large vacuole and could be isolated on the basis of their low buoyant density. All these protoplasts were capable of wall regeneration and about 50 percent reverted to the hyphal mode of growth in liquid medium. The kinetics of the formation of three main cell-wall components, S-glucan (alpha-1,3-glucan), R-glucan (beta-1,3, beta-1,6-glucan) and chitin were studied from the onset of regeneration. S-glucan and chitin accumulation as well as RNA and protein synthesis started simultaneously after a short lag, but R-glucan formation was delayed. The reversion of hyphal tubes only began after several hours of rapid R-glucan synthesis. Cycloheximide (0.5 mug/ml), inhibiting protein synthesis by 98% inhibited the formation of R-glucan and the reversion to hyphal growth but the formation of chitin and S-glucan did start and continued seemingly unimpaired for several hours. This indicates that the enzymes responsible for the synthesis of S-glucan and chitin remained intact during protoplast preparation. Polyoxin D inhibited both the synthesis of chitin and R-glucan and also the reversion to hyphal growth. However, the synthesis of S-glucan was not suppressed. These inhibitor studies as well as the kinetics of R-glucan formation during normal regeneration suggest that the synthesis of R-glucan is required for the initiation of hyphal morphogenesis.     

Effects of metabolic inhibitors on spontaneous and interferon-boosted human natural killer cell activity

Human natural killer (NK) cell activity can be augmented by pretreatment with partially purified preparations of human interferon (IF). Studies have now been performed to determine the metabolic processes required for and involved in spontaneous NK activity and augmentation of cytotoxicity. A 4-hr 51Cr release cellular cytotoxicity assay was used to measure the NK activity, and peripheral blood leukocyte cells (PBL) were treated with: a) x-ray or mitomycin C; b) actinomycin D; or c) emetine, cycloheximide, pactamyhcin, or puromycin to assess the roles of DNA, RNA, and protein synthesis, respectively, in spontaneous NK activity and in boosting by IF. Prolonged incubation (18 hr) of PBL after blockage of synthesis of DNA almost completely abrogated NK activity; however, NK activity could be partially or totally restored to these populations by incubation of the effector cells for 1 hr at 37 degrees C with IF. Blockage of DNA synthesis for 1 hr had no effect on spontaneous NK activity or on boosting by IF. Inhibition of RNA synthesis also had no effect on spontaneous NK activity. Treatment of PBL with actinomycin before exposure to IF prevented boosting, but treatment with the RNA synthesis inhibitor after boosting with IF for 5 to 6 hr no longer had an appreciable effect on cytotoxicity. The effect of protein synthesis inhibitors on spontaneous NK activity was dependent on the inhibitor selected. Emetine and puromycin totally abrogated spontaneous NK activity at concentrations of inhibitor that blocked 3H-leucine incorporation 90% or more. In contrast, cycloheximide and pactamycin had only minimal effects on spontaneous NK activity but totally abrogated the boosting of IF.