Structure and Chemical Composition of Prospheroplast Envelopes of Saccharomyces cerevisiae and Hansenula anomala

Cells of Saccharomyces cerevisiae and Hansenula anomala were digested with snail enzyme under conditions yielding prospheroplasts. Surrounding envelopes were isolated after lysis of prospheroplasts in distilled water. The envelope material was embedded and sectioned for electron microscopy, and thin, hollow structures still retaining the elongated form of the original cells were seen. The envelopes were of low electron density in sections stained with uranyl magnesium acetate and lead citrate, but were more electron-dense when stained with phosphotungstic acid. Shadowed preparations of prospheroplast envelopes revealed structures resembling ghosts. These "ghosts" were similar to the original cells in form and size but seemed to be very thin. Varying numbers of anular structures (bud scars) were found on them. Chemical analyses of the envelope indicated that an alkali-soluble glucan was a major constituent. The results show that the prospheroplast envelope is part of the original cell wall of the yeast and is located in close apposition to the cytoplasmic membrane.     

Controlled production of spheroplasts in the yeast Nadsonia elongata

Summary Yeast cells of Nadsonia elongata were cultivated in such a way that simultaneously with enzymatic lysis of the cell wall a partial synthesis of cell wall components was taking place. After the initial period of cultivation, which lasted about 10 h and during which the morphology of cells remained unchanged when compared to controls, the cells were transformed into prospheroplasts. The prospheroplasts were larger than the control cells and, though they enlarged in volume in distilled water, they still retained the shape of the original cells. However, some changes were found in the ultrastructure of the cell walls of prospheroplasts in comparison with that of the cell walls of intact cells: while in yeast cells the surface was smooth, in prospheroplasts the fibrillar network was revealed as a result of the removal of the amorphous component; the gradual disappearance of the outer cell wall layer and a swelling of the remaining cell wall fragment were seen in ultrathin sections. After about 20-h cultivation the prospheroplasts were transformed into spheroplasts. The spheroplasts were osmotically fragile, and did not retain the shape of the yeast cell, even in isoosmotic environment. On the surface of spheroplasts only the fibrillar network composed of separate fibrils was seen. The spheroplasts were the final stage of yeast cell transformation under the conditions employed in the present study. Under the mentioned conditions true protoplasts are never formed. However, if the synthesis of cell wall components could not take place simultaneously with the lysis of the cell wall, the cells were transformed to protoplasts.     

Natural penicillin resistance of Francisella tularensis

Altered viable forms of F. tularensis with spheroplast specific damages of the surface structures were isolated after the culture exposure to lithium chloride (0.5 and 1%). Study of natural penicillin resistance in the spheroplasts and bacterial forms of F. tularensis revealed their difference: the spheroplasts of the strains tested had a lower resistance to beta-lactam antibiotics than the bacterial forms while the activity of spheroplast beta-lactamase did not differ from that of the enzyme of the bacterial form and equalled 224 to 252 U/ml of the cell suspension. Therefore, on the model of the lithium-induced spheroplasts it appeared possible to show that the damages of the surface structures of the cell walls of F. tularensis changed the penicillin resistance level which was indicative of involvement of the F. tularensis cell walls in the phenomenon of the natural resistance to beta-lactams.     

Scanning electron microscope study of Saccharomyces cerevisiae spheroplast formation.

A suspension of Saccharomyces cerevisiae NCY366 in buffered 1.2 M sorbitol containing Zymolyase-5000 (a beta-glucanase-containing preparation/showed maximum osmotic sensitivity after 30 min of incubation at 30 degrees C. A scanning electron microscope study of spheroplast formation, using a very high resolution (4-nm) machine, revealed several new morphological features. The surface of the plug in bud scars on intact cells appeared warty. The wall, which assumed a beady appearance as digestion proceded, ultimately sloughed off to reveal the furrowed surface of the plasma membrane. Bud scars were resistant to digestion and. as incubation proceeded, they became surrounded by an outer annulus, which may be the seconary septum. Wall material was completely removed from the majority of cells only after 60 min of digestion. The surface of spheroplasts was studded with particles, about 25 to 30 nm in diameter. Many spheroplasts had a single large indentation, which may be in that part of the plasma membrane originally underlying the birth scar.     

Modification of the Composition and Structure of the Yeast Cell Wall by Culture in the Presence of Sulfur Amino Acids

Growth of Candida utilis and Saccharomyces cerevisiae in a medium supplemented with sulfur amino acids led to synthesis and accumulation of S-adenosylmethionine, accompanied by a reduction in the cell yield, an increased sensitivity of the cell wall to snail gut enzymes (Helix pomatia), as judged by spheroplast formation, and by a modification of the chemical composition of both the intact cells and their isolated walls. Walls of supplemented cultures of C. utilis were three times as sensitive to enzymatic digestion as walls from nonsupplemented cultures. In contrast to C. utilis, walls isolated from supplemented cultures of S. cerevisiae were digested slightly more rapidly by the purified snail extract than those from nonsupplemented cultures. Chemical modifications of the cell wall are interpreted to explain the ease with which cells from sulfur amino acid-supplemented cultures are converted to spheroplasts.     

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.     

Characteristics of chromosomal DNA isolated from Escherichia coli spheroplasts

The chromosomal DNA of Escherichia coli spheroplasts induced by penicillin G was studied biochemically and electron microscopically. Although the spheroplasts were unable to divide, they continued to synthesize chromosomal DNA for several hours even in the presence of penicillin G. Some differences were observed between the chromosomal DNA of the parent cells and that of the spheroplasts in sucrose gradient centrifugation and electron microscopy; two types of chromosomal DNA, a slower sedimenting form and a faster sedimenting form, were released from the gently lysed parent cells. The former was membrane-free folded chromosome and the latter was membrane-associated chromosome. In contrast, the chromosome from the spheroplast showed a single intermediate value of sedimentation coefficient between those of the chromosomal DNA from the parent cell. Cytochrome spreading for electron microscopy showed that the spheroplast chromosomal DNA formed an aggregated mass consisting of several chromosome-molecules of the parent cell.     

Effect of penicillin on the morphology and reproduction ofAzotobacter chroococcum

The effect of penicillin on the morphology and reproduction of some strains ofA. chroococcum was studied on a number of solid media. When the growth was not entirely suppressed by the penicillin, filamentous cells and spheroplasts were formed. The formation of spheroplasts was stimulated by peptone. Gonidia were sometimes formed inside the spheroplasts and also inside giant cells. They were released from the cell after disruption or after lysis of the cell wall. In some cases they produced dwarf cells. Under certain conditions groups of gonidia present in a cell fused and formed one or more normal-looking cells inside the mother cell. Sometimes one or moreAzotobacter cells developed inside a spheroplast or at the site of a spheroplast with a lysed cell wall. Microcolonies consisting of small cocci representing gonidia and dwarf cells were also observed occasionally at the sites of spheroplasts with lysed cell walls. Occasionally tiny groups of small elements with a less marked structure were found at such sites, probably representing debris of lysed cells. The production of normal-looking cells inside filamentous cells was greatly stimulated on a medium containing 10 percent horse serum, with a drop of sterile water containing 200 or 250 I.U. penicillin added in the centre of the plate. The growth ofA. chroococcum was greatly retarded when the medium contained 10 U/ml penicillin and seemed to be checked entirely at concentrations of 20 U/ml penicillin or higher. Occasionally, however, even at concentrations of 100 and 300 U/ml penicillin, a few filamentous cells were found and also a few microcolonies, visible only through the microscope, consisting of gonidia or regenerative rods. By repeated exposure ofAzotobacter to penicillin populations could be obtained that were adapted to high concentrations of this antibiotic.     

Interaction of the isolated DNA of lambda phage with spheroplasts of E. coli treated with sturine]

The method of centrifugation in sucrose density gradient (30-55%) of the spheroplast membrane preparations treated and untreated with sturine and infected with phage lambda DNA demonstrated that sturine, treatment increased the phage lambda DNA absorption three-fold. About 50% of the lambda DNA molecules adsorbed by spheroplasts are bound with the cytoplasmic membrane of spheroplasts treated with sturine; 50% of the lambda DNA molecules are bound with the cell wall membrane on the sturine-untreated spheroplasts. The data obtained allow to conclude that the stimulating effect of sturine in E. coli spheroplasts transfection by lambda DNA is connected with redistribution of phage DNA absorbed on spheroplasts from the cell wall to the cytoplasmic membrane facilitating the penetration of DNA and its fastening on the membrane.     

Isolation and characterization of two outer membrane preparations from Escherichia coli

A method was developed for releasing specifically a part of outer membrane during spheroplast formation. A highly purified outer membrane (outer membrane I) was obtained from the spheroplast medium by isopycnic sucrose gradient centrifugation. The remaining outer membrane (outer membrane II) and cytoplasmic membrane was also isolated from the spheroplasts by the isopycnic centrifugation.Two outer membrane preparations were different from the cytoplasmic membrane in protein composition, enzyme localization, phospholipid composition, lipopolysaccharide content and electron micrographs. Although outer membranes I and II were almost the same in various respects, they seemed to be different from each other under electron microscope and in cardiolipin content. It is suggested that the outer membrane I and the outer membrane II, at least a part of the outer membrane II, are integrated in a different fashion in the outer-most layer of Escherichia coli cell surface.     

Plasmid DNA-induced Transformability of Yeast Cells during Spheroplast Conversion

Changes in transformability, regenerability, cell fusibilityand endocytotic activity of Saccharomyces cerevisiae yeast duringspheroplast conversion were investigated using the cell walldigesting enzyme Zymolylase. The transformability with plasmidDNA, cell fusibility and endocytotic activity all reached maximumat the critical spheroplast conversion period when about halfof the cells had been converted into spheroplasts. Lysosomotropicdrugs, chloroquine and dansylcadaverine enhanced transformationand endocytosis two- to threefold. This study showed that aclose relationship exists among transformability, cell fusingactivity and endocytotic activity of spheroplasts. ¹ A preliminary report appeared in ref. Yoshida and Takagi (1981). (Received March 15, 1982; Accepted May 12, 1982)     

SPHEROPLAST FORMATION AND ASSOCIATED ULTRASTRUCTURAL CHANGES IN A SYNCHRONOUS CULTURE OF ANACYSTIS NIDULANS TREATED WITH LYSOZYME1,2

Cells of Anacystis nidnlans were grown in synchronous culture using a light-dark alternation to obtain synchronization. Two synchronous cycles were obtained with, decay of synchrony beginning with the third cycle. Cells of various ages in the growth cycle were treated with lysozyme to form spheroplasts. The percentage of spheroplast formation varied with age of the cells. After extended periods of lysozyme treatment, up to 90% of the cells of all ages showed spheroplast formation. Some cells were resistant to the action of lysozyme regardless of age or length of treatment. An ultrastructure study of the spheroplast was made. The electron-dense inner layer of the cell wall was removed by the action of lysozyme on the glucosamine residues of the cell wall, indicating true spheroplast formation. The photosynthetic apparatus became more pronounced with extended treatment with lysozyme.     

Surface Structure of Intact Cells and Spheroplasts of Pseudomonas aeruginosa

This report describes the ultrastructural features of Pseudomonas aeruginosa after freeze-etching of intact cells and enzymatically prepared spheroplasts. Freeze-etching of intact cells revealed two convex layers of the cell wall and particles within the hydrophobic interior of the cell membrane. Areas of the membrane free of particles were sometimes elevated in the form of rather large dome-shaped structures. Spheroplasts were formed from intact cells by the addition of trypsin to a reaction mixture of lysozyme and ethylenediaminetetraacetic acid. Spheroplasts contained the outer lipoid layer of the cell wall. It was possible to observe this cell wall layer in freeze-etch preparations of spheroplasts. The spheroplast membrane like that of intact cells was cleaved along a central plane to expose particles and particle-free areas.     

Effects of Lysozyme and Inorganic Anions on the Morphology of Streptococcus mutans BHT: Electron Microscopic Examination

The effects of hen egg white lysozyme and the inorganic salt sodium thiocyanate on the integrity of Streptococcus mutans BHT were studied by transmission electron microscopy. Both control cells and cells exposed to NaSCN possessed thick outer cell walls and densely staining inner cell walls juxtaposed to the plasma membranes. In the presence of NaSCN, however, the S. mutans BHT nucleoid was coagulated into thick electron-dense filaments. Exposure of S. mutans BHT to 150 μg of hen egg white lysozyme per ml resulted in the progressive destruction of both the cell walls and the plasma membranes. The enzyme appeared to affect the region of the cell wall septum, and exposure to 150 μg of hen egg white lysozyme per ml for as short a time as 10 min resulted in visible morphological cell wall alterations. At 30 min, ultrastructural observations revealed that the majority of the cells were in the process of expelling a portion of their cytoplasmic contents from the septal and other regions of the cells at the time of fixation. After 3 h of incubation in the presence of this high lysozyme concentration, gelled protoplasmic masses, which were free from the cells, were evident. In addition, extensive damage to the outer and inner cell walls and to the plasma membranes was apparent, although the cells maintained their shape. On some areas of the cell surface, the outer cell wall and plasma membrane were completely absent, whereas at other locations the outer cell wall was either split away from the inner cell wall and plasma membrane or distended from an area free of inner cell wall and plasma membrane. Upon addition of NaSCN to the hen egg white lysozyme-treated cells, both the gelled protoplasmic masses and the damaged cells exhibited an exploded appearance and existed as membrane ghosts, cell wall fragments, or dense aggregates of cytoplasmic components. The effects of a low lysozyme concentration (22.5 μg/ml) on S. mutans morphology were less pronounced at short incubation times (i.e., 10 and 30 min) than those that were observed with a high enzyme concentration; however, breaks in the cell walls and dissolution of the plasma membranes with resulting cell lysis were visible after a prolonged (3-h) incubation and after subsequent addition of NaSCN.     

Ultrastructure of protoplasts from mycelium and microconidia of Trichophyton mentagrophytes

Protoplast formation from mycelium and microconidia of Trichophyton mentagrophytes was achieved with Novozym 234. Pretreatment procedures with dithiothreitol or urea mercaptoethanol sodium lauryl sulphate before digestion with Novozym 234 greatly reduced protoplast yield from mycelium. Snail gut enzyme did not protoplasts in good yield. Scanning electron microscopy of mycelium protoplasts showed the acquired spherical shape. The plasma membrane appeared finely granular although remnants of cell wall could sometimes be observed. Transmission electron microscopy showed the cell interior of these protoplasts was plasmolysed. Microconidia treated with Novozym 234 displayed a range of cell wall digestion, with intact protoplasts showing distinct cytoplasmic organelles.     

Chemical Composition of the Cell Walls of Clostridium botulinum Type A

Cell walls were isolated by sonic disruption of log-phase cells of Clostridium botulinum type A strain 190L and purified by treatment with sodium dodecyl sulfate (SDS) followed by digestion with proteases. Electron microscopy revealed that the cell walls thus obtained were free of both cytoplasmic membrane and cytoplasmic fragments. The purified cell wall contained 8.7% total nitrogen, 15.0% total hexosamines, 22.4% reducing groups, 8.3% carbohydrate, and 3.1% glucose. The content of total phosphorus was very low (0.02%), and therefore it was expected that teichoic acid might be absent in the cell wall. The wall peptidoglycan contained glutamic acid, alanine, diaminopimelic acid, glucosamine and muramic acid in the molar ratios of 1.00:1.85:0:85:1.06:0.67. A low amount of galactosamine was also present, but no other amino acids were found in significant quantities. The SDS-treated cell walls were not attacked by lysozyme, but after extraction with hot formamide they were completely dissolved by the enzyme and released reducing groups. The lysozyme digest was separated into two constituents, the saccharide moiety and the peptide moiety on Sephadex G-50.     

Characterization of the fusion of enveloped viruses with the plasma membrane of Saccharomyces cerevisiae spheroplasts

Vesicular stomatitis virus (VSV) was associated at low pH with Saccharomyces cerevisiae spheroplasts. In the cold, the association was characterized as reversible binding to the spheroplast surface. At 37 degrees C, the association became irreversible due to fusion of the viral envelope with the yeast plasma membrane according to the following data. Proteinase K digestion degraded the viral envelope glycoprotein G but left the internal N and M proteins of VSV intact and associated with the spheroplasts. The plasma membrane could be stained by indirect immunofluorescent labeling using antiserum against VSV. By immunoelectron microscopy, no VSV particles could be detected at the spheroplast surface. Instead, the G protein could be visualized at the external aspect of the plasma membrane using specific antiserum and protein A-gold. Fusion of VSV with spheroplasts occurred below pH 4.75 at temperatures of 30-42 degrees C. It was strictly dependent on the prior removal of the yeast cell wall. The fusion process was fast, calcium-independent, and nonleaky, leaving the spheroplasts viable for at least 4 h. On the average, less than 100 VSV particles could be fused per one spheroplast. Similar data were obtained with Semliki Forest virus.     

Kinetics of synthesis, processing, and membrane transport of heat-labile enterotoxin, a periplasmic protein in Escherichia coli

We report the detection in vivo of precursors to the A and the B subunits of the heat-labile enterotoxin (LT) in Escherichia coli. Both pre-LT A (Mr = 29,500) and pre-LT B (Mr = 13,500) are present in the spheroplast fraction of the bacteria after separation of the cells in spheroplasts and periplasm. Two smaller LT A related polypeptides (17 and 23 kDa) were also detected in the spheroplast fraction. Both were degraded with a half-time of about 40 s. Mature subunits (Mr = 27,500 for LT A, and 11,500 for LT B) are released from the spheroplasts soon after processing and occur freely in the periplasm not associated with the cytoplasmic or the outer membranes. Processing occurs mainly post-translationally for both the A and the B subunits. However, they show different kinetics of processing and subsequent segregation into the periplasm. Whereas pre-LT B is processed and released within seconds after chain termination, pre-LT A is processed and released more slowly, and a subfraction of mature LT A may reside in the cytoplasmic membrane for several minutes.     

Stability of Escherichia coli to the membranotropic antibiotic gramicidin S]

The work was aimed at studying the effect of gramicidin S on the intact cells, spheroplasts and membrane specimens of Escherichia coli K12S with the natural resistance to this antibiotic. The resistance was shown to be caused by the barrier properties of the cell wall: the spheroplasts were highly sensitive to the lytic action of gramicidin S. The differences in the sensitivity to gramicidin S of substrate oxidation carried by the membranes of E. coli and Micrococcus luteus, a sensitive organism, were not of crucial significance for the manifestation of the resistance. The resistance was not associated with the decrease of gramicidin S adsorption: the cells were capable of binding large quantities of the antibiotic and remaining viable. Gramicidin S appeared to be attached to the cell walls (most likely, the outer membranes) rather than the cytoplasmic membranes.     

Genetic recombination in fused spheroplasts of Providence alcalifaciens.

Spheroplasts of Providence alcalifaciens strain P29 auxotrophs were prepared by combined treatment with glycine and lysozyme-EDTA. About 15% of spheroplasts had areas of cytoplasmic membrane exposed where cell wall was absent. The spheroplasts of different auxotrophs were mixed pairwise and fusion was attempted with polyethylene glycol or nascent calcium phosphate. After spheroplasts had regenerated to bacterial forms selection was made for recombinants. Recombinants arose at frequencies of 3.8 X 10(-6) to 1.7 X 10(-7) per spheroplast initially present, by both methods of fusion. The frequency was strongly dependent on the number of chromosomal loci used in selection. The possible order of five loci was determined and this corresponded to that on the closely related Proteus mirabilis chromosome. Control experiments excluded possibilities of auxotrophic reversion, conjugation, transformation, transfection or transduction as explanations of the results. Analysis of prototrophic clones yielded stable prototrophs or mixtures of stable prototrophs and stable recombinants. Parental types were not encountered. Unselected markers segregated among recombinants. It was concluded that the formation of recombinant bacteria was due to spheroplast fusion and that only stable products of the very temporary heteroploid state were haploid recombinants. The low frequency of recombination was ascribed to the limited number of spheroplasts with areas of exposed cytoplasmic membrane.