Atypical Cell Forms Overproducing Extracellular Substances in Populations of Cycad Cyanobionts

The ultrastructure of the cyanobionts of the greenhouse-grown cycads Cycas circinalis, Ceratozamia mexicana, and Encephalartos villosus was studied. The cyanobiont microcolonies grown in the intercellular space of the cyanobacterial zone of cortical parenchyma in the cycad coralloid roots contained two specific forms of vegetative cells with a reduced cell wall, namely, protoplasts and spheroplasts. The protoplasts and spheroplasts exhibited ultrastructural properties indicating the overproduction of two extracellular substances, one of which resembled the mucilage polysaccharides and the other was protein-like. The substances were likely to be synthesized intracellularly and then be excreted with the aid of surface vesicles or by ruptures in the cytoplasmic membrane to form, respectively, a mucilagious extracellular matrix and an additional electron-opaque envelope around the cell. At the late developmental stages, the excretion of these substances was accompanied by degradative changes in the cells, leading eventually to cell death. The physiological role of these specific cell forms and the factors that induce their development and death in the cell populations of cyanobionts are discussed.     

Isolation,structural and functional characterization of Staphylococcus aureus protoplasts obtained using lysoamidase

The action of the lysoamidase bacteriolytic complex on Staphylococcus aureus VKM B-209P cells has been studied to obtain protoplasts. The cells in the midlogarithmic phase were the most sensitive to lysoamidase action. It led to local destruction of cell wall due to hydrolysis of the peptidoglycan. Protoplast formation occurred in two steps in the presence of 1 M sucrose. First, osmotically fragile spheroplasts were formed. Then, the protoplasts were released from the destructed cell wall. The protoplast yield was about 80%. The protoplasts preserved the intact ultrastructure and were able to synthesize peptidoglycan fibrillae. Mainly the spheroplasts that maintained the cell-wall residues reversed into bacterial forms. The protoplasts had respiratory activity similar to cells. Respiration of cells and protoplasts was stimulated by various substrates. High rates of oxygen consumption were observed with -glycerophosphate and ethanol as substrates.     

Reversion of protoplasts and spheroplasts in the yeast Nadsonia elongata

Summary The time rate of regeneration of the cell wall and reversion of protoplasts of the yeast Nadsonia elongata to cells of normal shape and size has been compared with the capability for regeneration of spheroplasts of this yeast. Nearly all protoplasts in a given culture were able to regenerate new walls and had usually reverted to cells of normal appearance by the 30th h of cultivation. Spheroplasts required only half this time to do this. These results can be interpreted as evidence that regeneration of a wall by protoplasts does not depend upon the presence of a cell wall primer, because the proportion of reverting protoplasts (which lack wall remnants) was the same as that of reverting spheroplasts (which possess them). The presence of wall remnants in spheroplasts appears to have merely an accelerating effect on the formation of a new wall and on subsequent reversion of the spheroplasts to complete cells of normal shape and size.     

Transformation of Vinca protoplasts mediated by Agrobacterium spheroplasts

Summary Vinca rosea protoplasts and Agrobacterium tumefaciens spheroplasts harboring octopine-type Ti plasmid were mixed and treated with polyethylene glycol or polyvinyl alcohol, which facilitated the introduction of spheroplasts into plant protoplasts. After the protoplasts had been kept at 40° C for 4 days, bacteria were found to be completely eliminated from the medium. Among treated protoplasts 1–2 per 1,000 formed colonies on the Murashige and Skoog medium (1962) lacking hormones. When the colonies were isolated and subcultured, they could be maintained as clones. Octopine, an amino acid specific to crown gall, was detected in half of these clones. The phenotypic features of these putative transformants were compared but did not show any coincidental tendencies in relation to color, hardness, form, growth rate, or octopine production. The significance of this system in transformation of higher plant cells is discussed.     

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.     

Electron Microscopy and Viability of Lysostaphin-induced Staphylococcal Spheroplasts, Protoplast-like Bodies, and Protoplasts

The cell walls of a selected isolate of Staphylococcus aureus FDA 209P were observed undergoing progressive disintegration when exposed to lysostaphin (1 unit/ml) in 24% NaCl solution. Electron micrographs of ultrathin sections of test cells after exposure to lysostaphin for 2 min showed only superficial evidence of lytic damage. However, an average of 89% of these cells were osmotically fragile, and 21% were damaged beyond their capacity to regenerate cell walls and to grow as normal staphylococci. The 68% (average) of the osmotically fragile cells which retained the capacity to revert to normal staphylococci were designated spheroplasts. Neither perforations of the cell walls nor separation of the cell walls from the plasma membranes were observed in the micrographs of these 2-min spheroplasts. Thus, it appears that the osmotic fragility of these and possibly all lysostaphin-induced staphylococcal spheroplasts results from the hydrolysis of a critical number of the pentapeptide cross-linkages of the murein of the cell wall. Electron micrographs of cells exposed to lysostaphin for 5 to 10 min showed perforations and more extensive damage, including the separation of walls from the plasma membranes and the disintegration of large sections of the walls. Smaller numbers of spheroplasts (21 and 8%) were recovered from these 5- and 10-min preparations; those recovered probably represent cells which were attacked more slowly than the majority by the lytic enzyme. The nonrevertible, osmotically fragile cells that retained segments of cell wall were designated protoplast-like bodies. After 20-min exposure to lysostaphin, all of the cell wall was digested away from most of the cells, and true staphylococcal protoplasts were produced. These lysostaphin-induced, osmotically fragile forms appear to have different osmotic properties from the staphylococcal "protoplasts" reported by other investigators and should serve as the basis for a variety of fundamental investigations.     

The interaction betweenE. coli spheroplasts and plant protoplasts: A proposed procedure to deliver foreign genes into plant cells

Summary E. coli spheroplasts can be used to deliver DNA vectors into plant protoplasts. The use of fluorescent dyes showed that 25–100% of the protoplast population was associated with 1–9 spheroplasts following incubation with several fusogens. Electron microscopy demonstrated spheroplasts attached to protoplasts via a plasma membrane protrusion after high pH/Ca²⁺ treatment, but PEG-high pH/Ca²⁺ promoted endocytosis of spheroplasts into a plasma membrane bounded vesicle. Ultrastructural profiles showed that fusion between spheroplasts and protoplasts did not occur. Immunofluorescence studies detectedE. coli antigens associated with tobacco protoplasts, and after fusogen treatment the antigens were dispersed within the peripheral cytoplasm. The elimination of residual contaminatingE. coli cells from protoplasts was achieved by lysozyme and antibiotic treatment, thus allowing DNA vector assessment in axenic culture.     

Certain data on the protoplast ultrastructure]

A study was made of the structure of Bac. subtilis and Listeria monocytogenes protoplasts by the method of scanning electron microscopy. The mechanism of protoplast formation in Gram-positive bacteria and in spheroplasts of Gram-negative bacteria proved to differ. A loss of the rigid form of the cell, round protrusions on cell surface, and an escape of the cytoplasm through the ruptured cell wall in some one place was noted in case of protoplasts. Individual cells can coalesce with one another with the formation of shapeless masses. The formation of small spheroid bodies by budding, and also a division of protoplasts by constriction was described.     

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.     

Cell volume changes during rapid temperature shifts

The effect of a rapid temperature increase on the volume of different types of cells was investigated. Experiments were carried out using continuous microscopic image analysis. Volume variation of yeast cells, yeast spheroplasts and human leukaemia cells was measured during the transient phase after a thermal shift. The thermal shift was found to induce rapid increase in cell volume for cells lacking a cell wall (yeast spheroplasts and human leukaemia cells). This increase in cell volume is assumed to be a main cause of the heat shock-induced cell death. A theoretical mechanistic model that explains the behaviour of these cells is finally proposed.     

Action of streptolysin S, the group D hemolysin, and phospholipase C on whole cells and spheroplasts

Davie, Joseph M. (Indiana University, Bloomington), and Thomas D. Brock. Action of streptolysin S, the group D hemolysin, and phospholipase C on whole cells and spheroplasts. J. Bacteriol. 91:595-600. 1966.-The effect of streptolysin S, the group D hemolysin, and phospholipase C (the alpha toxin of Clostridium perfringens) on whole cells and spheroplasts or protoplasts of three strains of streptococci and Micrococcus lysodeikticus was tested. Viability, C(14)-glycine uptake, and lysis were measured. The group D hemolysin and phospholipase C were active against whole bacteria; streptolysin S was not. All three substances were active on spheroplasts. A partially resistant mutant derived from a strain sensitive to the group D hemolysin was also partially resistant to streptolysin S and phospholipase C. Antimycin A protected spheroplasts from streptolysin S but not from the group D hemolysin.     

Formation and regeneration of protoplasts and spheroplasts of gastrointestinal strains of lactobacilli.

Methods were developed for the formation of protoplasts and spheroplasts of gastrointestinal strains of Lactobacillus reuteri, Lactobacillus gasseri, and Lactobacillus salivarius. Attempts to regenerate vegetative cells from protoplasts were not successful, but spheroplasts could be regenerated consistently for five of six strains.     

Introduction of Escherichia coli cells and spheroplasts into Vinca protoplasts

In the presence of 10% polyvinyl alcohol (PVA), Escherichia coli cells or spheroplasts can be easily introduced into Vinca protoplasts by endocytosis. Uptake proceeded quite rapidly; bacterial cells or spheroplasts were found within the cytoplasm of Vinca protoplasts after 10 min of incubation with PVA.     

Formation and regeneration of protoplasts and spheroplasts of gastrointestinal strains of lactobacilli

Methods were developed for the formation of protoplasts and spheroplasts of gastrointestinal strains of Lactobacillus reuteri, Lactobacillus gasseri, and Lactobacillus salivarius. Attempts to regenerate vegetative cells from protoplasts were not successful, but spheroplasts could be regenerated consistently for five of six strains.     

Susceptibility to Polymyxin B of Penicillin G-induced Proteus mirabilis L Forms and Spheroplasts

A polymyxin B-resistant strain of Proteus mirabilis was converted into L forms and spheroplasts in the presence of penicillin G. This treatment caused a 400-fold increase in polymyxin B susceptibility. The acquired susceptibility was in the range of the natural susceptibility reported for susceptible gram-negative bacteria ( approximately 1 mug/ml). The high susceptibility to polymyxin B was lost as soon as the spheroplasts and L forms were allowed to reconvert into the bacillary form in penicillin-free media. This behavior is strong evidence that the natural resistance of Proteus strains to polymyxins is due to the impermeability of the outer cell wall structures to these antibiotic substances.     

Isolation and Characterization of Protoplasts from Saccharomyces rouxii

Cells of the osmotolerant yeast Saccharomyces rouxii were transformed to protoplasts in good yield (85%) by digesting cell walls with snail-gut enzyme in the presence of 10 mM dithioerythritol, 0.1 M sodium phosphate buffer (pH 6.8), and 2.0 M KCl. The requirement for 2.0 M KCl compares with that for S. bisporus var. mellis (another osmotolerant species) and contrasts with the 0.3 to 0.8 M KCl concentrations used in the preparation of most yeast protoplasts. Short digestions (60 min or less) produced mostly spheroplasts; longer incubations (90 min or more) yielded mostly protoplasts as judged by electron micrographs. These protoplasts could be transferred to 1.0 M KCl or 2.0 M sorbitol without lysing, but lysis was pronounced in 0.5 M KCl or 1.0 M mannitol and complete in 0.02 M KCl. Protoplasts were separated from isolated cell wall remnants and debris by centrifugation on a linear gradient of Ficoll 400 (35 to 17.5%, wt/vol) containing 2.0 M KCl. Both crude and fractionated protoplast preparations contained vesicles which were identified with the periplasmic bodies of whole cells. Some of the periplasmic bodies were connected to protoplasts by fine pedicels; others appeared free. Independent degeneracy of periplasmic bodies was occasionally observed. beta-Fructofuranosidase (EC 3.2.1.26) activity is cryptic (physically) in cells of S. rouxii in contrast to the expressed enzyme (periplasmic space) of other Saccharomyces species. This enzyme remains cryptic in protoplast preparations of S. rouxii but is expressed upon lysis. The same specific activities were found per unit cell or protoplast. The possible association of the cryptic enzyme with periplasmic bodies is discussed.     

Endocytic uptake of Escherichia coli spheroplasts by Neurospora crassa slime cells

Summary Interaction of Escherichia coli spheroplasts with Neurospora crassa slime cells was examined by transmission electron microscopy after treatment with polyvinyl alcohol followed by dilution with the high pH-high Ca buffer. Bacterial spheroplasts were found either adhering to the flat surface, associating with the invaginating surface, or residing within the intracellular vesicle of fungal protoplasts. In addition, bacterial spheroplasts free of the surrounding vesicles and those in the course of breakdown were observed in the fungal cytoplasm. It was concluded that Escherichia coli spheroplasts are taken up by Neurospora crassa protoplasts almost exclusively via endocytosis. This is the first cytological evidence for the endocytic activity of fungal cells.     

Isolation problems and structural organization of membrane units in Mycobacterium sp. smegmatis

Summary Membrane units from lysed spheroplasts induced by lysozyme or glycine from Mycobacterium spec. smegmatis were isolated in a biological active state by differential centrifugation and by density gradient technique. They were compared morphologically with membraneous fractions obtained from mycobacterial cells disintegrated under a high hydrostatic pressure.Higher homogeneity of membraneous structures isolated from spheroplasts was confirmed. Three types of membraneous structures could be distinguished. They include empty ghosts of spheroplasts, tubular structures containing cytoplasmic material and fragments of typical membraneous structures relatively free of contaminants. By studying protoplasts in the process of lysis it was determined that these structures correspond with cytoplasmic membranes and mesosomes.Differences between lysozome and glycine induced spheroplasts as a starting material for isolation of membraneous structures include the proportion of contamination by other cellular components, reasons of which are discussed.     

Isolation of Staphylococcus aureus protoplasts using lysoamidase

The effect of the bacteriolytic enzyme preparation, lysoamidase, on Staphylococcus aureus 209P cells was studied. The protoplast formation was examined by spectrophotometric, biochemical and electron microscopic methods. Optimal conditions for isolation of S. aureus protoplasts were chosen. The susceptibility of S. aureus cells to lysoamidase depended on the culture age: the maximum effect was observed in the logarithmic growth phase. The protoplast yield was 80% when 1 M sucrose was used as an osmotic stabilizer. Lysoamidase caused local disruptures of the staphylococcus cell walls, which resulted in the formation of osmotically fragile spheroplasts and the release of protoplasts into the medium. The protoplasts obtained could retain 85-90% of the respiration activity and were able of cell wall regeneration.     

Preparation and regeneration of protoplasts and spheroplasts for fusion and transformation ofSchizosaccharomyces pombe

Preparation and regeneration of protoplasts is essential for somatic hybridization and transformation of yeasts. We present conditions that were found to be optimal for preparing and regeneratingSchizosaccharomyces pombe protoplasts for cell fusion. In contrast to these conditions, genetic transformation ofS. pombe requires spheroplasts that are osmotically sensitive, but still have some wall material attached to the cell. The main finding were as follows: (a) For protoplast formation with Novozym SP234, 0.9M sorbitol was found to be the optimal osmotic milieu and -mercaptoethanol is not necessary. (b) Embedding in soft agar yields considerably better regeneration frequencies than direct plating. (c) Cell fusion is optimal when both fusion partners are fully protoplasted, although considerable fusion occurs between spheroplasted cells as well. (d)Schizosaccharomyces pombe transformation frequencies are much higher with spheroplasts than with protoplasts. Inclusion of -mercaptoethanol did not enhance transformation frequency.